apiVersion: sriovnetwork.openshift.io/v1
kind: SriovOperatorConfig
metadata:
name: default (1)
namespace: openshift-sriov-network-operator
spec:
enableInjector: true
enableOperatorWebhook: true
configurationMode: "systemd" (2)
logLevel: 2- Documentation
- OpenShift Container Platform
- Networking
- Hardware networks
- Configuring hardware offloading history bug_report picture_as_pdf
- About
- Release notes
- Getting started
- Architecture
- Architecture overview
- Product architecture
- Installation and update
- Red Hat OpenShift Cluster Manager
- About the multicluster engine for Kubernetes Operator
- Control plane architecture
- NVIDIA GPU architecture overview
- Understanding OpenShift development
- Red Hat Enterprise Linux CoreOS
- Admission plugins
- Installing
- Installation overview
- Disconnected installation mirroring
- Installing on Alibaba
- Preparing to install on Alibaba Cloud
- Creating the required Alibaba Cloud resources
- Installing a cluster quickly on Alibaba Cloud
- Installing a cluster on Alibaba Cloud with customizations
- Installing a cluster on Alibaba Cloud with network customizations
- Installing a cluster on Alibaba Cloud into an existing VPC
- Installation configuration parameters for Alibaba Cloud
- Uninstalling a cluster on Alibaba Cloud
- Installing on AWS
- Preparing to install on AWS
- Configuring an AWS account
- Installing a cluster quickly on AWS
- Installing a cluster on AWS with customizations
- Installing a cluster on AWS with network customizations
- Installing a cluster on AWS in a restricted network
- Installing a cluster on AWS into an existing VPC
- Installing a private cluster on AWS
- Installing a cluster on AWS into a government region
- Installing a cluster on AWS into a Secret or Top Secret Region
- Installing a cluster on AWS into a China region
- Installing a cluster on AWS using CloudFormation templates
- Installing a cluster on AWS in a restricted network with user-provisioned infrastructure
- Installing a cluster on AWS with compute nodes on AWS Local Zones
- Installing a cluster on AWS with compute nodes on AWS Wavelength Zones
- Installing a cluster on AWS with compute nodes on AWS Outposts
- Installing a three-node cluster on AWS
- Uninstalling a cluster on AWS
- Installation configuration parameters for AWS
- Installing on Azure
- Preparing to install on Azure
- Configuring an Azure account
- Enabling user-managed encryption on Azure
- Installing a cluster quickly on Azure
- Installing a cluster on Azure with customizations
- Installing a cluster on Azure with network customizations
- Installing a cluster on Azure into an existing VNet
- Installing a private cluster on Azure
- Installing a cluster on Azure into a government region
- Installing a cluster on Azure in a restricted network with user-provisioned infrastructure
- Installing a cluster on Azure using ARM templates
- Installing a cluster on Azure in a restricted network
- Installing a three-node cluster on Azure
- Uninstalling a cluster on Azure
- Installation configuration parameters for Azure
- Installing on Azure Stack Hub
- Preparing to install on Azure Stack Hub
- Configuring an Azure Stack Hub account
- Installing a cluster on Azure Stack Hub with an installer-provisioned infrastructure
- Installing a cluster on Azure Stack Hub with network customizations
- Installing a cluster on Azure Stack Hub using ARM templates
- Installation configuration parameters for Azure Stack Hub
- Uninstalling a cluster on Azure Stack Hub
- Installing on GCP
- Preparing to install on GCP
- Configuring a GCP project
- Installing a cluster quickly on GCP
- Installing a cluster on GCP with customizations
- Installing a cluster on GCP with network customizations
- Installing a cluster on GCP in a restricted network
- Installing a cluster on GCP into an existing VPC
- Installing a cluster on GCP into a shared VPC
- Installing a private cluster on GCP
- Installing a cluster on GCP using Deployment Manager templates
- Installing a cluster into a shared VPC on GCP using Deployment Manager templates
- Installing a cluster on GCP in a restricted network with user-provisioned infrastructure
- Installing a three-node cluster on GCP
- Installation configuration parameters for GCP
- Uninstalling a cluster on GCP
- Installing on IBM Cloud
- Preparing to install on IBM Cloud
- Configuring an IBM Cloud account
- Configuring IAM for IBM Cloud
- User-managed encryption
- Installing a cluster on IBM Cloud with customizations
- Installing a cluster on IBM Cloud with network customizations
- Installing a cluster on IBM Cloud into an existing VPC
- Installing a private cluster on IBM Cloud
- Installing a cluster on IBM Cloud in a restricted network
- Installation configuration parameters for IBM Cloud
- Uninstalling a cluster on IBM Cloud
- Installing on Nutanix
- Installing on bare metal
- Preparing to install on bare metal
- Installing a user-provisioned cluster on bare metal
- Installing a user-provisioned bare metal cluster with network customizations
- Installing a user-provisioned bare metal cluster on a restricted network
- Scaling a user-provisioned installation with the bare metal operator
- Installation configuration parameters for bare metal
- Installing on-premise with Assisted Installer
- Installing an on-premise cluster with the Agent-based Installer
- Preparing to install with Agent-based Installer
- Understanding disconnected installation mirroring
- Installing a cluster with Agent-based Installer
- Preparing PXE assets for OCP
- Preparing an Agent-based installed cluster for the multicluster engine for Kubernetes
- Installation configuration parameters for the Agent-based Installer
- Installing on a single node
- Deploying installer-provisioned clusters on bare metal
- Installing IBM Cloud Bare Metal (Classic)
- Installing on IBM Z and IBM LinuxONE
- Preparing to install on IBM Z and IBM LinuxONE
- Installing a cluster with z/VM on IBM Z and IBM LinuxONE
- Restricted network IBM Z installation with z/VM
- Installing a cluster with RHEL KVM on IBM Z and IBM LinuxONE
- Restricted network IBM Z installation with RHEL KVM
- Installing a cluster in an LPAR on IBM Z and IBM LinuxONE
- Restricted network IBM Z installation in an LPAR
- Installation configuration parameters for IBM Z and IBM LinuxONE
- Installing on IBM Power
- Installing on IBM Power Virtual Server
- Preparing to install on IBM Power Virtual Server
- Configuring an IBM Cloud account
- Creating an IBM Power Virtual Server workspace
- Installing a cluster on IBM Power Virtual Server with customizations
- Installing a cluster on IBM Power Virtual Server into an existing VPC
- Installing a private cluster on IBM Power Virtual Server
- Installing a cluster on IBM Power Virtual Server in a restricted network
- Uninstalling a cluster on IBM Power Virtual Server
- Installation configuration parameters for IBM Power Virtual Server
- Installing on OpenStack
- Preparing to install on OpenStack
- Preparing to install a cluster that uses SR-IOV or OVS-DPDK on OpenStack
- Installing a cluster on OpenStack with customizations
- Installing a cluster on OpenStack on your own infrastructure
- Installing a cluster on OpenStack in a restricted network
- Configuring network settings after installing OpenStack
- OpenStack Cloud Controller Manager reference guide
- Deploying on OpenStack with rootVolume and etcd on local disk
- Uninstalling a cluster on OpenStack
- Uninstalling a cluster on OpenStack from your own infrastructure
- Installation configuration parameters for OpenStack
- Installing on OCI
- Installing on vSphere
- Installation methods
- Installer-provisioned infrastructure
- User-provisioned infrastructure
- Assisted Installer
- Agent-based Installer
- Installing a three-node cluster
- Uninstalling a cluster
- Using the vSphere Problem Detector Operator
- Installation configuration parameters
- Regions and zones for a VMware vCenter
- Enabling encryption on a vSphere cluster
- Configuring the vSphere connection settings after an installation
- Installing on any platform
- Installation configuration
- Validation and troubleshooting
- Postinstallation configuration
- Postinstallation configuration overview
- Configuring a private cluster
- Bare metal configuration
- Configuring multi-architecture compute machines on an OpenShift cluster
- About clusters with multi-architecture compute machines
- Creating a cluster with multi-architecture compute machines on Azure
- Creating a cluster with multi-architecture compute machines on AWS
- Creating a cluster with multi-architecture compute machines on GCP
- Creating a cluster with multi-architecture compute machines on bare metal, IBM Power, or IBM Z
- Creating a cluster with multi-architecture compute machines on IBM Z and IBM LinuxONE with z/VM
- Creating a cluster with multi-architecture compute machines on IBM Z and IBM LinuxONE with RHEL KVM
- Creating a cluster with multi-architecture compute machines on IBM Power
- Managing your cluster with multi-architecture compute machines
- Machine configuration tasks
- Cluster tasks
- Node tasks
- Postinstallation network configuration
- Configuring image streams and image registries
- Storage configuration
- Preparing for users
- Changing the cloud provider credentials configuration
- Configuring alert notifications
- Converting a connected cluster to a disconnected cluster
- Configuring additional devices in an IBM Z or IBM LinuxONE environment
- Red Hat Enterprise Linux CoreOS image layering
- AWS Local Zone or Wavelength Zone tasks
- Updating clusters
- Understanding OpenShift updates
- Preparing to update a cluster
- Performing a cluster update
- Updating a cluster using the CLI
- Updating a cluster using the web console
- Performing a Control Plane Only update
- Performing a canary rollout update
- Updating a cluster that includes RHEL compute machines
- Updating a cluster in a disconnected environment
- Updating hardware on nodes running on vSphere
- Migrating to a cluster with multi-architecture compute machines
- Updating hosted control planes
- Updating the boot loader on Red Hat Enterprise Linux CoreOS nodes using bootupd
- Troubleshooting a cluster update
- Support
- Support overview
- Managing your cluster resources
- Getting support
- Remote health monitoring with connected clusters
- About remote health monitoring
- Showing data collected by remote health monitoring
- Opting out of remote health reporting
- Enabling remote health reporting
- Using Insights to identify issues with your cluster
- Using the Insights Operator
- Using remote health reporting in a restricted network
- Importing simple content access entitlements with Insights Operator
- Gathering data about your cluster
- Summarizing cluster specifications
- Troubleshooting
- Troubleshooting installations
- Verifying node health
- Troubleshooting CRI-O container runtime issues
- Troubleshooting operating system issues
- Troubleshooting network issues
- Troubleshooting Operator issues
- Investigating pod issues
- Troubleshooting the Source-to-Image process
- Troubleshooting storage issues
- Troubleshooting Windows container workload issues
- Investigating monitoring issues
- Diagnosing OpenShift CLI (oc) issues
- Web console
- Web console overview
- Accessing the web console
- Using the OpenShift Container Platform dashboard to get cluster information
- Adding user preferences
- Configuring the web console
- Customizing the web console
- Dynamic plugins
- Web terminal
- Disabling the web console
- Creating quick start tutorials
- Optional capabilities and products
- CLI tools
- Security and compliance
- Security and compliance overview
- Container security
- Understanding container security
- Understanding host and VM security
- Hardening Red Hat Enterprise Linux CoreOS
- Container image signatures
- Understanding compliance
- Securing container content
- Using container registries securely
- Securing the build process
- Deploying containers
- Securing the container platform
- Securing networks
- Securing attached storage
- Monitoring cluster events and logs
- Configuring certificates
- Certificate types and descriptions
- User-provided certificates for the API server
- Proxy certificates
- Service CA certificates
- Node certificates
- Bootstrap certificates
- etcd certificates
- OLM certificates
- Aggregated API client certificates
- Machine Config Operator certificates
- User-provided certificates for default ingress
- Ingress certificates
- Monitoring and cluster logging Operator component certificates
- Control plane certificates
- Compliance Operator
- File Integrity Operator
- File Integrity Operator Overview
- File Integrity Operator release notes
- File Integrity Operator support
- Installing the File Integrity Operator
- Updating the File Integrity Operator
- Understanding the File Integrity Operator
- Configuring the File Integrity Operator
- Performing advanced File Integrity Operator tasks
- Troubleshooting the File Integrity Operator
- Security Profiles Operator
- Security Profiles Operator overview
- Security Profiles Operator release notes
- Security Profiles Operator support
- Understanding the Security Profiles Operator
- Enabling the Security Profiles Operator
- Managing seccomp profiles
- Managing SELinux profiles
- Advanced Security Profiles Operator tasks
- Troubleshooting the Security Profiles Operator
- Uninstalling the Security Profiles Operator
- NBDE Tang Server Operator
- NBDE Tang Server Operator overview
- NBDE Tang Server Operator release notes
- Understanding the NBDE Tang Server Operator
- Installing the NBDE Tang Server Operator
- Configuring and managing Tang servers using the NBDE Tang Server Operator
- Identifying URL of a Tang server deployed with the NBDE Tang Server Operator
- cert-manager Operator for Red Hat OpenShift
- cert-manager Operator for Red Hat OpenShift overview
- cert-manager Operator for Red Hat OpenShift release notes
- Installing the cert-manager Operator for Red Hat OpenShift
- Configuring the egress proxy
- Customizing cert-manager by using the cert-manager Operator API fields
- Authenticating the cert-manager Operator for Red Hat OpenShift
- Configuring an ACME issuer
- Configuring certificates with an issuer
- Monitoring the cert-manager Operator for Red Hat OpenShift
- Configuring log levels for cert-manager and the cert-manager Operator for Red Hat OpenShift
- Uninstalling the cert-manager Operator for Red Hat OpenShift
- Viewing audit logs
- Configuring the audit log policy
- Configuring TLS security profiles
- Configuring seccomp profiles
- Allowing JavaScript-based access to the API server from additional hosts
- Encrypting etcd data
- Scanning pods for vulnerabilities
- Network-Bound Disk Encryption (NBDE)
- Authentication and authorization
- Authentication and authorization overview
- Understanding authentication
- Configuring the internal OAuth server
- Configuring OAuth clients
- Managing user-owned OAuth access tokens
- Understanding identity provider configuration
- Configuring identity providers
- Configuring an htpasswd identity provider
- Configuring a Keystone identity provider
- Configuring an LDAP identity provider
- Configuring a basic authentication identity provider
- Configuring a request header identity provider
- Configuring a GitHub or GitHub Enterprise identity provider
- Configuring a GitLab identity provider
- Configuring a Google identity provider
- Configuring an OpenID Connect identity provider
- Using RBAC to define and apply permissions
- Removing the kubeadmin user
- Understanding and creating service accounts
- Using service accounts in applications
- Using a service account as an OAuth client
- Scoping tokens
- Using bound service account tokens
- Managing security context constraints
- Understanding and managing pod security admission
- Impersonating the system:admin user
- Syncing LDAP groups
- Managing cloud provider credentials
- Networking
- About networking
- Understanding networking
- Zero trust networking
- Accessing hosts
- Networking Operators overview
- Networking dashboards
- Understanding the Cluster Network Operator
- Understanding the DNS Operator
- Understanding the Ingress Operator
- Understanding the Ingress Node Firewall Operator
- Configuring the Ingress Controller for manual DNS management
- Verifying connectivity to an endpoint
- Changing the cluster network MTU
- Configuring the node port service range
- Configuring the cluster network IP address range
- Configuring IP failover
- Configuring system controls and interface attributes using the tuning plugin
- Using SCTP
- Using PTP hardware
- External DNS Operator
- External DNS Operator release notes
- Understanding the External DNS Operator
- Installing the External DNS Operator
- External DNS Operator configuration parameters
- Creating DNS records on a public hosted zone for AWS
- Creating DNS records on a public zone for Azure
- Creating DNS records on a public managed zone for GCP
- Creating DNS records on a public DNS zone for Infoblox
- Configuring the cluster-wide proxy on the External DNS Operator
- Network policy
- CIDR range definitions
- AWS Load Balancer Operator
- AWS Load Balancer Operator release notes
- Understanding the AWS Load Balancer Operator
- Installing the AWS Load Balancer Operator
- Preparing for the AWS Load Balancer Operator on a cluster using the AWS Security Token Service (STS)
- Creating an instance of the AWS Load Balancer Controller
- Serving multiple ingress resources through a single AWS Load Balancer
- Adding TLS termination on the AWS Load Balancer
- Configuring cluster-wide proxy on the AWS Load Balancer Operator
- Multiple networks
- Understanding multiple networks
- Configuring an additional network
- About virtual routing and forwarding
- Configuring multi-network policy
- Attaching a pod to an additional network
- Removing a pod from an additional network
- Editing an additional network
- Removing an additional network
- Assigning a secondary network to a VRF
- Hardware networks
- About Single Root I/O Virtualization (SR-IOV) hardware networks
- Installing the SR-IOV Operator
- Configuring the SR-IOV Operator
- Configuring an SR-IOV network device
- Configuring an SR-IOV Ethernet network attachment
- Configuring an SR-IOV InfiniBand network attachment
- Adding a pod to an SR-IOV network
- Configuring interface-level network sysctl settings and all-multicast mode for SR-IOV networks
- Using high performance multicast
- Using DPDK and RDMA
- Using pod-level bonding for secondary networks
- Configuring hardware offloading
- Switching Bluefield-2 from NIC to DPU mode
- Uninstalling the SR-IOV Operator
- OVN-Kubernetes network plugin
- About the OVN-Kubernetes network plugin
- OVN-Kubernetes architecture
- OVN-Kubernetes troubleshooting
- OVN-Kubernetes network policy
- OVN-Kubernetes traffic tracing
- Migrating from the OpenShift SDN network plugin
- Rolling back to the OpenShift SDN network plugin
- Converting to IPv4/IPv6 dual stack networking
- Logging for egress firewall and network policy rules
- Configuring IPsec encryption
- Configure an external gateway on the default network
- Configuring an egress firewall for a project
- Viewing an egress firewall for a project
- Editing an egress firewall for a project
- Removing an egress firewall from a project
- Configuring an egress IP address
- Assigning an egress IP address
- Configuring an egress service
- Considerations for the use of an egress router pod
- Deploying an egress router pod in redirect mode
- Enabling multicast for a project
- Disabling multicast for a project
- Tracking network flows
- Configuring hybrid networking
- OpenShift SDN network plugin
- About the OpenShift SDN network plugin
- Configuring egress IPs for a project
- Configuring an egress firewall for a project
- Viewing an egress firewall for a project
- Editing an egress firewall for a project
- Removing an egress firewall from a project
- Considerations for the use of an egress router pod
- Deploying an egress router pod in redirect mode
- Deploying an egress router pod in HTTP proxy mode
- Deploying an egress router pod in DNS proxy mode
- Configuring an egress router pod destination list from a config map
- Enabling multicast for a project
- Disabling multicast for a project
- Configuring multitenant isolation
- Configuring kube-proxy
- Configuring Routes
- Configuring ingress cluster traffic
- Overview
- Configuring ExternalIPs for services
- Configuring ingress cluster traffic using an Ingress Controller
- Configuring the Ingress Controller endpoint publishing strategy
- Configuring ingress cluster traffic using a load balancer
- Configuring ingress cluster traffic on AWS
- Configuring ingress cluster traffic using a service external IP
- Configuring ingress cluster traffic using a NodePort
- Configuring ingress cluster traffic using load balancer allowed source ranges
- Kubernetes NMState
- Configuring the cluster-wide proxy
- Configuring a custom PKI
- Load balancing on OpenStack
- Load balancing with MetalLB
- About MetalLB and the MetalLB Operator
- Installing the MetalLB Operator
- Upgrading the MetalLB Operator
- Configuring MetalLB address pools
- Advertising the IP address pools
- Configuring MetalLB BGP peers
- Advertising an IP address pool using the community alias
- Configuring MetalLB BFD profiles
- Configuring services to use MetalLB
- Managing symmetric routing with MetalLB
- MetalLB logging, troubleshooting, and support
- Associating secondary interfaces metrics to network attachments
- Storage
- Storage overview
- Understanding ephemeral storage
- Understanding persistent storage
- Configuring persistent storage
- Persistent storage using AWS Elastic Block Store
- Persistent storage using Azure Disk
- Persistent storage using Azure File
- Persistent storage using Cinder
- Persistent storage using Fibre Channel
- Persistent storage using FlexVolume
- Persistent storage using GCE Persistent Disk
- Persistent Storage using iSCSI
- Persistent storage using NFS
- Persistent storage using Red Hat OpenShift Data Foundation
- Persistent storage using VMware vSphere
- Persistent storage using local storage
- Using Container Storage Interface (CSI)
- Configuring CSI volumes
- CSI inline ephemeral volumes
- Shared Resource CSI Driver Operator
- CSI volume snapshots
- CSI volume cloning
- Managing the default storage class
- CSI automatic migration
- Detach CSI volumes after non-graceful node shutdown
- AliCloud Disk CSI Driver Operator
- AWS Elastic Block Store CSI Driver Operator
- AWS Elastic File Service CSI Driver Operator
- Azure Disk CSI Driver Operator
- Azure File CSI Driver Operator
- Azure Stack Hub CSI Driver Operator
- GCP PD CSI Driver Operator
- GCP Filestore CSI Driver Operator
- IBM VPC Block CSI Driver Operator
- IBM Power Virtual Server Block CSI Driver Operator
- OpenStack Cinder CSI Driver Operator
- OpenStack Manila CSI Driver Operator
- Secrets Store CSI Driver Operator
- VMware vSphere CSI Driver Operator
- Generic ephemeral volumes
- Expanding persistent volumes
- Dynamic provisioning
- Registry
- Registry overview
- Image Registry Operator in OpenShift Container Platform
- Setting up and configuring the registry
- Configuring the registry for AWS user-provisioned infrastructure
- Configuring the registry for GCP user-provisioned infrastructure
- Configuring the registry for OpenStack user-provisioned infrastructure
- Configuring the registry for Azure user-provisioned infrastructure
- Configuring the registry for OpenStack
- Configuring the registry for bare metal
- Configuring the registry for vSphere
- Configuring the registry for OpenShift Data Foundation
- Configuring the registry for Nutanix
- Accessing the registry
- Exposing the registry
- Operators
- Operators overview
- Understanding Operators
- User tasks
- Administrator tasks
- Adding Operators to a cluster
- Updating installed Operators
- Deleting Operators from a cluster
- Configuring OLM features
- Configuring proxy support
- Viewing Operator status
- Managing Operator conditions
- Allowing non-cluster administrators to install Operators
- Managing custom catalogs
- Using OLM on restricted networks
- Catalog source pod scheduling
- Managing platform Operators
- Troubleshooting Operator issues
- Developing Operators
- About the Operator SDK
- Installing the Operator SDK CLI
- Go-based Operators
- Ansible-based Operators
- Helm-based Operators
- Java-based Operators
- Defining cluster service versions (CSVs)
- Working with bundle images
- Complying with pod security admission
- Token authentication
- Validating Operators using the scorecard
- Validating Operator bundles
- High-availability or single-node cluster detection and support
- Configuring built-in monitoring with Prometheus
- Configuring leader election
- Configuring support for multiple platforms
- Object pruning utility
- Migrating package manifest projects to bundle format
- Operator SDK CLI reference
- Cluster Operators reference
- OLM 1.0 (Technology Preview)
- CI/CD
- CI/CD overview
- Builds using Shipwright
- Builds using BuildConfig
- Understanding image builds
- Understanding build configurations
- Creating build inputs
- Managing build output
- Using build strategies
- Custom image builds with Buildah
- Performing and configuring basic builds
- Triggering and modifying builds
- Performing advanced builds
- Using Red Hat subscriptions in builds
- Securing builds by strategy
- Build configuration resources
- Troubleshooting builds
- Setting up additional trusted certificate authorities for builds
- Pipelines
- GitOps
- Jenkins
- Images
- Overview of images
- Configuring the Cluster Samples Operator
- Using the Cluster Samples Operator with an alternate registry
- Creating images
- Managing images
- Managing image streams
- Using image streams with Kubernetes resources
- Triggering updates on image stream changes
- Image configuration resources
- Using templates
- Using Ruby on Rails
- Using images
- Building applications
- Building applications overview
- Projects
- Creating applications
- Viewing application composition by using the Topology view
- Exporting applications
- Connecting applications to services
- Service Binding Operator release notes
- Understanding Service Binding Operator
- Installing Service Binding Operator
- Getting started with service binding
- Getting started with service binding on IBM Power, IBM Z, and IBM LinuxONE
- Exposing binding data from a service
- Projecting binding data
- Binding workloads using Service Binding Operator
- Connecting an application to a service using the Developer perspective
- Working with Helm charts
- Deployments
- Quotas
- Using config maps with applications
- Monitoring project and application metrics using the Developer perspective
- Monitoring application health
- Editing applications
- Pruning objects to reclaim resources
- Idling applications
- Deleting applications
- Using the Red Hat Marketplace
- Serverless
- Machine management
- Overview of machine management
- Managing compute machines with the Machine API
- Creating a compute machine set on Alibaba Cloud
- Creating a compute machine set on AWS
- Creating a compute machine set on Azure
- Creating a compute machine set on Azure Stack Hub
- Creating a compute machine set on GCP
- Creating a compute machine set on IBM Cloud
- Creating a compute machine set on IBM Power Virtual Server
- Creating a compute machine set on Nutanix
- Creating a compute machine set on OpenStack
- Creating a compute machine set on vSphere
- Creating a compute machine set on bare metal
- Manually scaling a compute machine set
- Modifying a compute machine set
- Machine phases and lifecycle
- Deleting a machine
- Applying autoscaling to a cluster
- Creating infrastructure machine sets
- Adding a RHEL compute machine
- Adding more RHEL compute machines
- Managing user-provisioned infrastructure manually
- Managing control plane machines
- About control plane machine sets
- Getting started with control plane machine sets
- Managing control plane machines with control plane machine sets
- Control plane machine set configuration
- Configuration options for control plane machines
- Control plane configuration options for Amazon Web Services
- Control plane configuration options for Microsoft Azure
- Control plane configuration options for Google Cloud Platform
- Control plane configuration options for Nutanix
- Control plane configuration options for Red Hat OpenStack Platform
- Control plane configuration options for VMware vSphere
- Control plane resiliency and recovery
- Troubleshooting the control plane machine set
- Disabling the control plane machine set
- Managing machines with the Cluster API
- Deploying machine health checks
- Hosted control planes
- Hosted control planes overview
- Getting started with hosted control planes
- Authentication and authorization for hosted control planes
- Handling a machine configuration for hosted control planes
- Using feature gates in a hosted cluster
- Updating hosted control planes
- Hosted control planes Observability
- High availability for hosted control planes
- Troubleshooting hosted control planes
- Nodes
- Overview of nodes
- Working with pods
- About pods
- Viewing pods
- Configuring a cluster for pods
- Automatically scaling pods with the horizontal pod autoscaler
- Automatically adjust pod resource levels with the vertical pod autoscaler
- Providing sensitive data to pods by using secrets
- Providing sensitive data to pods by using an external secrets store
- Creating and using config maps
- Using Device Manager to make devices available to nodes
- Including pod priority in pod scheduling decisions
- Placing pods on specific nodes using node selectors
- Run Once Duration Override Operator
- Automatically scaling pods with the Custom Metrics Autoscaler Operator
- Release notes
- Custom Metrics Autoscaler Operator overview
- Installing the custom metrics autoscaler
- Understanding the custom metrics autoscaler triggers
- Understanding custom metrics autoscaler trigger authentications
- Pausing the custom metrics autoscaler
- Gathering audit logs
- Gathering debugging data
- Viewing Operator metrics
- Understanding how to add custom metrics autoscalers
- Removing the Custom Metrics Autoscaler Operator
- Controlling pod placement onto nodes (scheduling)
- About pod placement using the scheduler
- Scheduling pods using a scheduler profile
- Placing pods relative to other pods using pod affinity and anti-affinity rules
- Controlling pod placement on nodes using node affinity rules
- Placing pods onto overcommited nodes
- Controlling pod placement using node taints
- Placing pods on specific nodes using node selectors
- Controlling pod placement using pod topology spread constraints
- Descheduler
- Secondary scheduler
- Using Jobs and DaemonSets
- Working with nodes
- Viewing and listing the nodes in your cluster
- Working with nodes
- Managing nodes
- Managing the maximum number of pods per node
- Using the Node Tuning Operator
- Remediating, fencing, and maintaining nodes
- Understanding node rebooting
- Freeing node resources using garbage collection
- Allocating resources for nodes
- Allocating specific CPUs for nodes in a cluster
- Enabling TLS security profiles for the kubelet
- Machine Config Daemon metrics
- Creating infrastructure nodes
- Working with containers
- Understanding containers
- Using Init Containers to perform tasks before a pod is deployed
- Using volumes to persist container data
- Mapping volumes using projected volumes
- Allowing containers to consume API objects
- Copying files to or from a container
- Executing remote commands in a container
- Using port forwarding to access applications in a container
- Using sysctls in containers
- Accessing faster builds with /dev/fuse
- Working with clusters
- Viewing system event information in a cluster
- Analyzing cluster resource levels
- Setting limit ranges
- Configuring cluster memory to meet container memory and risk requirements
- Configuring your cluster to place pods on overcommited nodes
- Configuring the Linux cgroup version on your nodes
- Enabling features using FeatureGates
- Improving cluster stability in high latency environments using worker latency profiles
- Remote worker nodes on the network edge
- Worker nodes for single-node OpenShift clusters
- Node metrics dashboard
- Windows Container Support for OpenShift
- Red Hat OpenShift support for Windows Containers overview
- Release notes
- Getting support
- Understanding Windows container workloads
- Enabling Windows container workloads
- Creating Windows machine sets
- Scheduling Windows container workloads
- Windows node upgrades
- Using Bring-Your-Own-Host Windows instances as nodes
- Removing Windows nodes
- Disabling Windows container workloads
- OpenShift sandboxed containers
- Observability
- Observability overview
- Monitoring
- Monitoring overview
- Common monitoring configuration scenarios
- Configuring the monitoring stack
- Enabling monitoring for user-defined projects
- Enabling alert routing for user-defined projects
- Managing metrics
- Managing alerts
- Reviewing monitoring dashboards
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- SubjectAccessReview [authorization.openshift.io/v1]
- SubjectRulesReview [authorization.openshift.io/v1]
- SelfSubjectReview [authentication.k8s.io/v1]
- TokenRequest [authentication.k8s.io/v1]
- TokenReview [authentication.k8s.io/v1]
- LocalSubjectAccessReview [authorization.k8s.io/v1]
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- SelfSubjectRulesReview [authorization.k8s.io/v1]
- SubjectAccessReview [authorization.k8s.io/v1]
- Autoscale APIs
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- APIServer [config.openshift.io/v1]
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- ClusterVersion [config.openshift.io/v1]
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- HelmChartRepository [helm.openshift.io/v1beta1]
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- ImageTagMirrorSet [config.openshift.io/v1]
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- Network [config.openshift.io/v1]
- Node [config.openshift.io/v1]
- OAuth [config.openshift.io/v1]
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- Project [config.openshift.io/v1]
- ProjectHelmChartRepository [helm.openshift.io/v1beta1]
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- Console APIs
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- Machine APIs
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- ContainerRuntimeConfig [machineconfiguration.openshift.io/v1]
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- MachineConfig [machineconfiguration.openshift.io/v1]
- MachineConfigNode [machineconfiguration.openshift.io/v1alpha1]
- MachineConfigPool [machineconfiguration.openshift.io/v1]
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- Metadata APIs
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- Alertmanager [monitoring.coreos.com/v1]
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- PodMonitor [monitoring.coreos.com/v1]
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- Prometheus [monitoring.coreos.com/v1]
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- Network APIs
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- AdminPolicyBasedExternalRoute [k8s.ovn.org/v1]
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- EgressIP [k8s.ovn.org/v1]
- EgressQoS [k8s.ovn.org/v1]
- EgressService [k8s.ovn.org/v1]
- Endpoints [undefined/v1]
- EndpointSlice [discovery.k8s.io/v1]
- EgressRouter [network.operator.openshift.io/v1]
- Ingress [networking.k8s.io/v1]
- IngressClass [networking.k8s.io/v1]
- IPPool [whereabouts.cni.cncf.io/v1alpha1]
- NetworkAttachmentDefinition [k8s.cni.cncf.io/v1]
- NetworkPolicy [networking.k8s.io/v1]
- OverlappingRangeIPReservation [whereabouts.cni.cncf.io/v1alpha1]
- PodNetworkConnectivityCheck [controlplane.operator.openshift.io/v1alpha1]
- Route [route.openshift.io/v1]
- Service [undefined/v1]
- Node APIs
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- Authentication [operator.openshift.io/v1]
- CloudCredential [operator.openshift.io/v1]
- ClusterCSIDriver [operator.openshift.io/v1]
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- Config [operator.openshift.io/v1]
- Config [imageregistry.operator.openshift.io/v1]
- Config [samples.operator.openshift.io/v1]
- CSISnapshotController [operator.openshift.io/v1]
- DNS [operator.openshift.io/v1]
- DNSRecord [ingress.operator.openshift.io/v1]
- Etcd [operator.openshift.io/v1]
- ImageContentSourcePolicy [operator.openshift.io/v1alpha1]
- ImagePruner [imageregistry.operator.openshift.io/v1]
- IngressController [operator.openshift.io/v1]
- InsightsOperator [operator.openshift.io/v1]
- KubeAPIServer [operator.openshift.io/v1]
- KubeControllerManager [operator.openshift.io/v1]
- KubeScheduler [operator.openshift.io/v1]
- KubeStorageVersionMigrator [operator.openshift.io/v1]
- MachineConfiguration [operator.openshift.io/v1]
- Network [operator.openshift.io/v1]
- OpenShiftAPIServer [operator.openshift.io/v1]
- OpenShiftControllerManager [operator.openshift.io/v1]
- OperatorPKI [network.operator.openshift.io/v1]
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- OperatorHub APIs
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- CatalogSource [operators.coreos.com/v1alpha1]
- ClusterServiceVersion [operators.coreos.com/v1alpha1]
- InstallPlan [operators.coreos.com/v1alpha1]
- OLMConfig [operators.coreos.com/v1]
- Operator [operators.coreos.com/v1]
- OperatorCondition [operators.coreos.com/v2]
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- PackageManifest [packages.operators.coreos.com/v1]
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- BMCEventSubscription [metal3.io/v1alpha1]
- BareMetalHost [metal3.io/v1alpha1]
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- HostFirmwareSettings [metal3.io/v1alpha1]
- Metal3Remediation [infrastructure.cluster.x-k8s.io/v1beta1]
- Metal3RemediationTemplate [infrastructure.cluster.x-k8s.io/v1beta1]
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- RBAC APIs
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- ClusterResourceQuota [quota.openshift.io/v1]
- FlowSchema [flowcontrol.apiserver.k8s.io/v1beta3]
- LimitRange [undefined/v1]
- PriorityClass [scheduling.k8s.io/v1]
- PriorityLevelConfiguration [flowcontrol.apiserver.k8s.io/v1beta3]
- ResourceQuota [undefined/v1]
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- PodSecurityPolicySubjectReview [security.openshift.io/v1]
- RangeAllocation [security.openshift.io/v1]
- Secret [undefined/v1]
- SecurityContextConstraints [security.openshift.io/v1]
- ServiceAccount [undefined/v1]
- Storage APIs
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- CSIDriver [storage.k8s.io/v1]
- CSINode [storage.k8s.io/v1]
- CSIStorageCapacity [storage.k8s.io/v1]
- PersistentVolume [undefined/v1]
- PersistentVolumeClaim [undefined/v1]
- StorageClass [storage.k8s.io/v1]
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- BuildConfig [build.openshift.io/v1]
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- Virtualization
- About
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×
Configuring hardware offloading
- About hardware offloading
- Supported devices
- Prerequisites
- Setting the SR-IOV Network Operator into systemd mode
- Configuring a machine config pool for hardware offloading
- Configuring the SR-IOV network node policy
- Improving network traffic performance using a virtual function
- Creating a network attachment definition
- Adding the network attachment definition to your pods
As a cluster administrator, you can configure hardware offloading on compatible nodes to increase data processing performance and reduce load on host CPUs.
About hardware offloading
Open vSwitch hardware offloading is a method of processing network tasks by diverting them away from the CPU and offloading them to a dedicated processor on a network interface controller. As a result, clusters can benefit from faster data transfer speeds, reduced CPU workloads, and lower computing costs.
The key element for this feature is a modern class of network interface controllers known as SmartNICs. A SmartNIC is a network interface controller that is able to handle computationally-heavy network processing tasks. In the same way that a dedicated graphics card can improve graphics performance, a SmartNIC can improve network performance. In each case, a dedicated processor improves performance for a specific type of processing task.
In OpenShift Container Platform, you can configure hardware offloading for bare metal nodes that have a compatible SmartNIC. Hardware offloading is configured and enabled by the SR-IOV Network Operator.
Hardware offloading is not compatible with all workloads or application types. Only the following two communication types are supported:
-
pod-to-pod
-
pod-to-service, where the service is a ClusterIP service backed by a regular pod
In all cases, hardware offloading takes place only when those pods and services are assigned to nodes that have a compatible SmartNIC. Suppose, for example, that a pod on a node with hardware offloading tries to communicate with a service on a regular node. On the regular node, all the processing takes place in the kernel, so the overall performance of the pod-to-service communication is limited to the maximum performance of that regular node. Hardware offloading is not compatible with DPDK applications.
Enabling hardware offloading on a node, but not configuring pods to use, it can result in decreased throughput performance for pod traffic. You cannot configure hardware offloading for pods that are managed by OpenShift Container Platform.
Supported devices
Hardware offloading is supported on the following network interface controllers:
| Manufacturer | Model | Vendor ID | Device ID |
|---|---|---|---|
Mellanox |
MT27800 Family [ConnectX‑5] |
15b3 |
1017 |
Mellanox |
MT28880 Family [ConnectX‑5 Ex] |
15b3 |
1019 |
Mellanox |
MT2892 Family [ConnectX‑6 Dx] |
15b3 |
101d |
Mellanox |
MT2894 Family [ConnectX-6 Lx] |
15b3 |
101f |
Mellanox |
MT42822 BlueField-2 in ConnectX-6 NIC mode |
15b3 |
a2d6 |
Prerequisites
-
Your cluster has at least one bare metal machine with a network interface controller that is supported for hardware offloading.
-
Your cluster uses the OVN-Kubernetes network plugin.
-
In your OVN-Kubernetes network plugin configuration, the
gatewayConfig.routingViaHostfield is set tofalse.
Setting the SR-IOV Network Operator into systemd mode
To support hardware offloading, you must first set the SR-IOV Network Operator into systemd mode.
Prerequisites
-
You installed the OpenShift CLI (
oc). -
You have access to the cluster as a user that has the
cluster-adminrole.
Procedure
-
Create a
SriovOperatorConfigcustom resource (CR) to deploy all the SR-IOV Operator components:-
Create a file named
sriovOperatorConfig.yamlthat contains the following YAML:1 The only valid name for the SriovOperatorConfigresource isdefaultand it must be in the namespace where the Operator is deployed.2 Setting the SR-IOV Network Operator into systemdmode is only relevant for Open vSwitch hardware offloading. -
Create the resource by running the following command:
$ oc apply -f sriovOperatorConfig.yaml
-
Configuring a machine config pool for hardware offloading
To enable hardware offloading, you now create a dedicated machine config pool and configure it to work with the SR-IOV Network Operator.
Prerequisites
-
SR-IOV Network Operator installed and set into
systemdmode.
Procedure
-
Create a machine config pool for machines you want to use hardware offloading on.
-
Create a file, such as
mcp-offloading.yaml, with content like the following example:apiVersion: machineconfiguration.openshift.io/v1 kind: MachineConfigPool metadata: name: mcp-offloading (1) spec: machineConfigSelector: matchExpressions: - {key: machineconfiguration.openshift.io/role, operator: In, values: [worker,mcp-offloading]} (1) nodeSelector: matchLabels: node-role.kubernetes.io/mcp-offloading: "" (2)1 The name of your machine config pool for hardware offloading. 2 This node role label is used to add nodes to the machine config pool. -
Apply the configuration for the machine config pool:
$ oc create -f mcp-offloading.yaml
-
-
Add nodes to the machine config pool. Label each node with the node role label of your pool:
$ oc label node worker-2 node-role.kubernetes.io/mcp-offloading="" -
Optional: To verify that the new pool is created, run the following command:
$ oc get nodesExample outputNAME STATUS ROLES AGE VERSION master-0 Ready master 2d v1.28.5 master-1 Ready master 2d v1.28.5 master-2 Ready master 2d v1.28.5 worker-0 Ready worker 2d v1.28.5 worker-1 Ready worker 2d v1.28.5 worker-2 Ready mcp-offloading,worker 47h v1.28.5 worker-3 Ready mcp-offloading,worker 47h v1.28.5 -
Add this machine config pool to the
SriovNetworkPoolConfigcustom resource:-
Create a file, such as
sriov-pool-config.yaml, with content like the following example:apiVersion: sriovnetwork.openshift.io/v1 kind: SriovNetworkPoolConfig metadata: name: sriovnetworkpoolconfig-offload namespace: openshift-sriov-network-operator spec: ovsHardwareOffloadConfig: name: mcp-offloading (1)1 The name of your machine config pool for hardware offloading. -
Apply the configuration:
$ oc create -f <SriovNetworkPoolConfig_name>.yamlWhen you apply the configuration specified in a
SriovNetworkPoolConfigobject, the SR-IOV Operator drains and restarts the nodes in the machine config pool.It might take several minutes for a configuration changes to apply.
-
Configuring the SR-IOV network node policy
You can create an SR-IOV network device configuration for a node by creating an SR-IOV network node policy.
To enable hardware offloading, you must define the .spec.eSwitchMode field with the value "switchdev".
The following procedure creates an SR-IOV interface for a network interface controller with hardware offloading.
Prerequisites
-
You installed the OpenShift CLI (
oc). -
You have access to the cluster as a user with the
cluster-adminrole.
Procedure
-
Create a file, such as
sriov-node-policy.yaml, with content like the following example:apiVersion: sriovnetwork.openshift.io/v1 kind: SriovNetworkNodePolicy metadata: name: sriov-node-policy (1) namespace: openshift-sriov-network-operator spec: deviceType: netdevice (2) eSwitchMode: "switchdev" (3) nicSelector: deviceID: "1019" rootDevices: - 0000:d8:00.0 vendor: "15b3" pfNames: - ens8f0 nodeSelector: feature.node.kubernetes.io/network-sriov.capable: "true" numVfs: 6 priority: 5 resourceName: mlxnics1 The name for the custom resource object. 2 Required. Hardware offloading is not supported with vfio-pci.3 Required. -
Apply the configuration for the policy:
$ oc create -f sriov-node-policy.yamlWhen you apply the configuration specified in a
SriovNetworkPoolConfigobject, the SR-IOV Operator drains and restarts the nodes in the machine config pool.It might take several minutes for a configuration change to apply.
An example SR-IOV network node policy for OpenStack
The following example describes an SR-IOV interface for a network interface controller (NIC) with hardware offloading on Red Hat OpenStack Platform (RHOSP).
An SR-IOV interface for a NIC with hardware offloading on RHOSP
apiVersion: sriovnetwork.openshift.io/v1
kind: SriovNetworkNodePolicy
metadata:
name: ${name}
namespace: openshift-sriov-network-operator
spec:
deviceType: switchdev
isRdma: true
nicSelector:
netFilter: openstack/NetworkID:${net_id}
nodeSelector:
feature.node.kubernetes.io/network-sriov.capable: 'true'
numVfs: 1
priority: 99
resourceName: ${name}Improving network traffic performance using a virtual function
Follow this procedure to assign a virtual function to the OVN-Kubernetes management port and increase its network traffic performance.
This procedure results in the creation of two pools: the first has a virtual function used by OVN-Kubernetes, and the second comprises the remaining virtual functions.
Prerequisites
-
You installed the OpenShift CLI (
oc). -
You have access to the cluster as a user with the
cluster-adminrole.
Procedure
-
Add the
network.operator.openshift.io/smart-niclabel to each worker node with a SmartNIC present by running the following command:$ oc label node <node-name> network.operator.openshift.io/smart-nic=Use the
oc get nodescommand to get a list of the available nodes. -
Create a policy named
sriov-node-mgmt-vf-policy.yamlfor the management port with content such as the following example:apiVersion: sriovnetwork.openshift.io/v1 kind: SriovNetworkNodePolicy metadata: name: sriov-node-mgmt-vf-policy namespace: openshift-sriov-network-operator spec: deviceType: netdevice eSwitchMode: "switchdev" nicSelector: deviceID: "1019" rootDevices: - 0000:d8:00.0 vendor: "15b3" pfNames: - ens8f0#0-0 (1) nodeSelector: network.operator.openshift.io/smart-nic: "" numVfs: 6 (2) priority: 5 resourceName: mgmtvf1 Replace this device with the appropriate network device for your use case. The #0-0part of thepfNamesvalue reserves a single virtual function used by OVN-Kubernetes.2 The value provided here is an example. Replace this value with one that meets your requirements. For more information, see SR-IOV network node configuration object in the Additional resources section. -
Create a policy named
sriov-node-policy.yamlwith content such as the following example:apiVersion: sriovnetwork.openshift.io/v1 kind: SriovNetworkNodePolicy metadata: name: sriov-node-policy namespace: openshift-sriov-network-operator spec: deviceType: netdevice eSwitchMode: "switchdev" nicSelector: deviceID: "1019" rootDevices: - 0000:d8:00.0 vendor: "15b3" pfNames: - ens8f0#1-5 (1) nodeSelector: network.operator.openshift.io/smart-nic: "" numVfs: 6 (2) priority: 5 resourceName: mlxnics1 Replace this device with the appropriate network device for your use case. 2 The value provided here is an example. Replace this value with the value specified in the sriov-node-mgmt-vf-policy.yamlfile. For more information, see SR-IOV network node configuration object in the Additional resources section.The
sriov-node-mgmt-vf-policy.yamlfile has different values for thepfNamesandresourceNamekeys than thesriov-node-policy.yamlfile. -
Apply the configuration for both policies:
$ oc create -f sriov-node-policy.yaml$ oc create -f sriov-node-mgmt-vf-policy.yaml -
Create a Cluster Network Operator (CNO) ConfigMap in the cluster for the management configuration:
-
Create a ConfigMap named
hardware-offload-config.yamlwith the following contents:apiVersion: v1 kind: ConfigMap metadata: name: hardware-offload-config namespace: openshift-network-operator data: mgmt-port-resource-name: openshift.io/mgmtvf -
Apply the configuration for the ConfigMap:
$ oc create -f hardware-offload-config.yaml
-
Additional resources
Creating a network attachment definition
After you define the machine config pool and the SR-IOV network node policy, you can create a network attachment definition for the network interface card you specified.
Prerequisites
-
You installed the OpenShift CLI (
oc). -
You have access to the cluster as a user with the
cluster-adminrole.
Procedure
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Create a file, such as
net-attach-def.yaml, with content like the following example:apiVersion: "k8s.cni.cncf.io/v1" kind: NetworkAttachmentDefinition metadata: name: net-attach-def (1) namespace: net-attach-def (2) annotations: k8s.v1.cni.cncf.io/resourceName: openshift.io/mlxnics (3) spec: config: '{"cniVersion":"0.3.1","name":"ovn-kubernetes","type":"ovn-k8s-cni-overlay","ipam":{},"dns":{}}'1 The name for your network attachment definition. 2 The namespace for your network attachment definition. 3 This is the value of the spec.resourceNamefield you specified in theSriovNetworkNodePolicyobject. -
Apply the configuration for the network attachment definition:
$ oc create -f net-attach-def.yaml
Verification
-
Run the following command to see whether the new definition is present:
$ oc get net-attach-def -AExample outputNAMESPACE NAME AGE net-attach-def net-attach-def 43h
Adding the network attachment definition to your pods
After you create the machine config pool, the SriovNetworkPoolConfig and SriovNetworkNodePolicy custom resources, and the network attachment definition, you can apply these configurations to your pods by adding the network attachment definition to your pod specifications.
Procedure
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In the pod specification, add the
.metadata.annotations.k8s.v1.cni.cncf.io/networksfield and specify the network attachment definition you created for hardware offloading:.... metadata: annotations: v1.multus-cni.io/default-network: net-attach-def/net-attach-def (1)1 The value must be the name and namespace of the network attachment definition you created for hardware offloading.