Customization guide

Table of contents

  1. Overview
  2. NodeFeatureRule custom resource
    1. A NodeFeatureRule example
    2. NodeFeatureRule controller
  3. Local feature source
    1. A hook example
    2. Hooks
    3. Feature files
    4. Input format
    5. Mounts
  4. Custom feature source
    1. An example custom feature source configuration
    2. Additional configuration directory
  5. Node labels
  6. Label rule format
    1. Fields
    2. Available features
    3. Templating
    4. Backreferences
    5. Examples
  7. Legacy custom rule syntax
    1. General nomenclature and definitions
    2. Custom features format (using the nomenclature defined above)
    3. Matching process
    4. Rules
    5. Legacy custom rule example

Overview

NFD provides multiple extension points for vendor and application specific labeling:

  • NodeFeatureRule objects provide a way to deploy custom labeling rules via the Kubernetes API
  • local feature source of nfd-worker creates labels by executing hooks and reading files
  • custom feature source of nfd-worker creates labels based on user-specified rules

NodeFeatureRule custom resource

NodeFeatureRule objects provide an easy way to create vendor or application specific labels. It uses a flexible rule-based mechanism for creating labels based on node feature.

A NodeFeatureRule example

Consider the following referential example:

apiVersion: nfd.k8s-sigs.io/v1alpha1
kind: NodeFeatureRule
metadata:
  name: my-sample-rule-object
spec:
  rules:
    - name: "my sample rule"
      labels:
        "my-sample-feature": "true"
      matchFeatures:
        - feature: kernel.loadedmodule
          matchExpressions:
            dummy: {op: Exists}
        - feature: kernel.config
          matchExpressions:
            X86: {op: In, value: ["y"]}

It specifies one rule which creates node label feature.node.kubenernetes.io/my-sample-feature=true if both of the following conditions are true (matchFeatures implements a logical AND over the matchers):

  • The dummy network driver module has been loaded
  • X86 option in kernel config is set to =y

Create a NodeFeatureRule with a yaml file:

kubectl apply -f https://raw.githubusercontent.com/kubernetes-sigs/node-feature-discovery/v0.10.1/examples/nodefeaturerule.yaml

Now, on X86 platforms the feature label appears after doing modprobe dummy on a system and correspondingly the label is removed after rmmod dummy. Note a re-labeling delay up to the sleep-interval of nfd-worker (1 minute by default).

NodeFeatureRule controller

NFD-Master acts as the controller for NodeFeatureRule objects. It applies these rules on raw feature data received from nfd-worker instances and creates node labels, accordingly.

NOTE nfd-master is stateless and (re-)labelling only happens when a request is received from nfd-worker. That is, in practice rules are evaluated and labels for each node are created on intervals specified by the core.sleepInterval configuration option (or -sleep-interval command line flag) of nfd-worker instances. This means that modification or creation of NodeFeatureRule objects does not instantly cause the node labels to be updated. Instead, the changes only come visible in node labels as nfd-worker instances send their labelling requests.

Local feature source

NFD-Worker has a special feature source named local which is an integration point for external feature detectors. It provides a mechanism for pluggable extensions, allowing the creation of new user-specific features and even overriding built-in labels.

The local feature source has two methods for detecting features, hooks and feature files. The features discovered by the local source can further be used in label rules specified in NodeFeatureRule objects and the custom feature source.

NOTE: Be careful when creating and/or updating hook or feature files while NFD is running. In order to avoid race conditions you should write into a temporary file (outside the source.d and features.d directories), and, atomically create/update the original file by doing a filesystem move operation.

A hook example

Consider a shell script /etc/kubernetes/node-feature-discovery/source.d/my-hook.sh having the following stdout output, or alternatively, a plaintext file /etc/kubernetes/node-feature-discovery/features.d/my-features having the following contents:

my-feature.1
my-feature.2=myvalue
my.namespace/my-feature.3=456

This will translate into the following node labels:

feature.node.kubernetes.io/my-feature.1: "true"
feature.node.kubernetes.io/my-feature.2: "myvalue"
my.namespace/my-feature.3: "456"

Note that in the example above -extra-label-ns=my.namespace must be specified on the nfd-master command line.

Hooks

The local source executes hooks found in /etc/kubernetes/node-feature-discovery/source.d/. The hook files must be executable and they are supposed to print all discovered features in stdout. With ELF binaries static linking is recommended as the selection of system libraries available in the NFD release image is very limited. Other runtimes currently supported by the NFD image are bash and perl.

stderr output of hooks is propagated to NFD log so it can be used for debugging and logging.

NFD tries to execute any regular files found from the hooks directory. Any additional data files the hook might need (e.g. a configuration file) should be placed in a separate directory in order to avoid NFD unnecessarily trying to execute them. A subdirectory under the hooks directory can be used, for example /etc/kubernetes/node-feature-discovery/source.d/conf/.

NOTE: NFD will blindly run any executables placed/mounted in the hooks directory. It is the user's responsibility to review the hooks for e.g. possible security implications.

NOTE: The minimal image variant only supports running statically linked binaries.

Feature files

The local source reads files found in /etc/kubernetes/node-feature-discovery/features.d/.

Input format

The hook stdout and feature files are expected to contain features in simple key-value pairs, separated by newlines:

<name>[=<value>]

The label value defaults to true, if not specified.

Label namespace may be specified with <namespace>/<name>[=<value>]. The namespace must be explicitly allowed with the -extra-label-ns command line flag of nfd-master if using something else than [<sub-ns>.]feature.node.kubernetes.io or [<sub-ns>.]profile.node.kubernetes.io.

Mounts

The standard NFD deployments contain hostPath mounts for /etc/kubernetes/node-feature-discovery/source.d/ and /etc/kubernetes/node-feature-discovery/features.d/, making these directories from the host available inside the nfd-worker container.

Injecting labels from other pods

One use case for the hooks and/or feature files is detecting features in other Pods outside NFD, e.g. in Kubernetes device plugins. By using the same hostPath mounts for /etc/kubernetes/node-feature-discovery/source.d/ and /etc/kubernetes/node-feature-discovery/features.d/ in the side-car (e.g. device plugin) creates a shared area for deploying hooks and feature files to NFD. NFD will periodically scan the directories and run any hooks and read any feature files it finds.

Custom feature source

The custom feature source in nfd-worker provides a rule-based mechanism for label creation, similar to the NodeFeatureRule objects. The difference is that the rules are specified in the worker configuration instead of a Kubernetes API object.

See worker configuration for instructions how to set-up and manage the worker configuration.

An example custom feature source configuration

Consider the following referential configuration for nfd-worker:

core:
  labelSources: ["custom"]
sources:
  custom:
    - name: "my sample rule"
      labels:
        "my-sample-feature": "true"
      matchFeatures:
        - feature: kernel.loadedmodule
          matchExpressions:
            dummy: {op: Exists}
        - feature: kernel.config
          matchExpressions:
            X86: {op: In, value: ["y"]}

It specifies one rule which creates node label feature.node.kubenernetes.io/my-sample-feature=true if both of the following conditions are true (matchFeatures implements a logical AND over the matchers):

  • The dummy network driver module has been loaded
  • X86 option in kernel config is set to =y

In addition, the configuration only enables the custom source, disabling all built-in labels.

Now, on X86 platforms the feature label appears after doing modprobe dummy on a system and correspondingly the label is removed after rmmod dummy. Note a re-labeling delay up to the sleep-interval of nfd-worker (1 minute by default).

Additional configuration directory

In addition to the rules defined in the nfd-worker configuration file, the custom feature source can read more configuration files located in the /etc/kubernetes/node-feature-discovery/custom.d/ directory. This makes more dynamic and flexible configuration easier.

As an example, consider having file /etc/kubernetes/node-feature-discovery/custom.d/my-rule.yaml with the following content:

- name: "my e1000 rule"
  labels:
    "e1000.present": "true"
  matchFeatures:
    - feature: kernel.loadedmodule
      matchExpressions:
        e1000: {op: Exists}

This simple rule will create feature.node.kubenernetes.io/e1000.present=true label if the e1000 kernel module has been loaded.

The samples/custom-rules kustomize overlay sample contains an example for deploying a custom rule from a ConfigMap.

Node labels

Feature labels have the following format:

<namespace>/<name> = <value>

The namespace part (i.e. prefix) of the labels is controlled by nfd:

  • All built-in labels use feature.node.kubernetes.io. This is also the default for user defined features that don't specify any namespace.
  • User-defined labels are allowed to use:
    • feature.node.kubernetes.io and profile.node.kubernetes.io plus their sub-namespaces (e.g. vendor.profile.node.kubernetes.io and sub.ns.profile.node.kubernetes.io) by default
    • Additional namespaces may be enabled with the -extra-label-ns command line flag of nfd-master

Label rule format

This section describes the rule format used in NodeFeatureRule objects and in the configuration of the custom feature source.

It is based on a generic feature matcher that covers all features discovered by nfd-worker. The rules rely on a unified data model of the available features and a generic expression-based format. Features that can be used in the rules are described in detail in available features below.

Take this rule as a referential example:

    - name: "my feature rule"
      labels:
        "my-special-feature": "my-value"
      matchFeatures:
        - feature: cpu.cpuid
          matchExpressions:
            AVX512F: {op: Exists}
        - feature: kernel.version
          matchExpressions:
            major: {op: In, value: ["5"]}
            minor: {op: Gt, value: ["1"]}
        - feature: pci.device
          matchExpressions:
            vendor: {op: In, value: ["8086"]}
            class: {op: In, value: ["0200"]}

This will yield feature.node.kubenernetes.io/my-special-feature=my-value node label if all of these are true (matchFeatures implements a logical AND over the matchers):

  • the CPU has AVX512F capability
  • kernel version is 5.2 or later (must be v5.x)
  • an Intel network controller is present

Fields

Name

The .name field is required and used as an identifier of the rule.

Labels

The .labels is a map of the node labels to create if the rule matches.

Labels template

The .labelsTemplate field specifies a text template for dynamically creating labels based on the matched features. See templating for details.

NOTE The labels field has priority over labelsTemplate, i.e. labels specified in the labels field will override anything originating from labelsTemplate.

Vars

The .vars field is a map of values (key-value pairs) to store for subsequent rules to use. In other words, these are variables that are not advertised as node labels. See backreferences for more details on the usage of vars.

Vars template

The .varsTemplate field specifies a text template for dynamically creating vars based on the matched features. See templating for details on using templates and backreferences for more details on the usage of vars.

NOTE The vars field has priority over varsTemplate, i.e. vars specified in the vars field will override anything originating from varsTemplate.

MatchFeatures

The .matchFeatures field specifies a feature matcher, consisting of a list of feature matcher terms. It implements a logical AND over the terms i.e. all of them must match in order for the rule to trigger.

      matchFeatures:
        - feature: <feature-name>
          matchExpressions:
            <key>:
              op: <op>
              value:
                - <value-1>
                - ...

The .matchFeatures[].feature field specifies the feature against which to match.

The .matchFeatures[].matchExpressions field specifies a map of expressions which to evaluate against the elements of the feature.

In each MatchExpression op specifies the operator to apply. Valid values are described below.

Operator Number of values Matches when
In 1 or greater Input is equal to one of the values
NotIn 1 or greater Input is not equal to any of the values
InRegexp 1 or greater Values of the MatchExpression are treated as regexps and input matches one or more of them
Exists 0 The key exists
DoesNotExist 0 The key does not exists
Gt 1 Input is greater than the value. Both the input and value must be integer numbers.
Lt 1 Input is less than the value. Both the input and value must be integer numbers.
GtLt 2 Input is between two values. Both the input and value must be integer numbers.
IsTrue 0 Input is equal to "true"
IsFalse 0 Input is equal "false"

The value field of MatchExpression is a list of string arguments to the operator.

The behavior of MatchExpression depends on the feature type: for flag and attribute features the MatchExpression operates on the feature element whose name matches the <key>. However, for instance features all MatchExpressions are evaluated against the attributes of each instance separately.

A special case of an empty matchExpressions field matches everything, i.e. matches/returns all elements of the feature. This makes it possible to write templates that run over all discovered features.

MatchAny

The .matchAny field is a list of of matchFeatures matchers. A logical OR is applied over the matchers, i.e. at least one of them must match in order for the rule to trigger.

Consider the following example:

      matchAny:
        - matchFeatures:
            - feature: kernel.loadedmodule
              matchExpressions:
                kmod-1: {op: Exists}
            - feature: pci.device
              matchExpressions:
                vendor: {op: In, value: ["0eee"]}
                class: {op: In, value: ["0200"]}
        - matchFeatures:
            - feature: kernel.loadedmodule
              matchExpressions:
                kmod-2: {op: Exists}
            - feature: pci.device
              matchExpressions:
                vendor: {op: In, value: ["0fff"]}
                class: {op: In, value: ["0200"]}

This matches if kernel module kmod-1 is loaded and a network controller from vendor 0eee is present, OR, if kernel module kmod-2 has been loaded and a network controller from vendor 0fff is present (OR both of these conditions are true).

Available features

Feature types

Features are divided into three different types:

  • flag features: a set of names without any associated values, e.g. CPUID flags or loaded kernel modules
  • attribute features: a set of names each of which has a single value associated with it (essentially a map of key-value pairs), e.g. kernel config flags or os release information
  • instance features: a list of instances, each of which has multiple attributes (key-value pairs of their own) associated with it, e.g. PCI or USB devices

List of features

The following features are available for matching:

Feature Feature type Elements Value type Description
cpu.cpuid flag     Supported CPU capabilities
    <cpuid-flag>   CPUID flag is present
cpu.cstate attribute     Status of cstates in the intel_idle cpuidle driver
    enabled bool ‘true' if cstates are set, otherwise ‘false'. Does not exist of intel_idle driver is not active.
cpu.pstate attribute     State of the Intel pstate driver. Does not exist if the driver is not enabled.
    status string Status of the driver, possible values are ‘active' and ‘passive'
    turbo bool ‘true' if turbo frequencies are enabled, otherwise ‘false'
    scaling string Active scaling_governor, possible values are ‘powersave' or ‘performance'.
cpu.rdt flag     Intel RDT capabilities supported by the system
    <rdt-flag>   RDT capability is supported, see RDT flags for details
cpu.sgx attribute     Intel SGX (Software Guard Extensions) capabilities
    enabled bool true if Intel SGX has been enabled, otherwise does not exist
cpu.sst attribute     Intel SST (Speed Select Technology) capabilities
    bf.enabled bool true if Intel SST-BF (Intel Speed Select Technology - Base frequency) has been enabled, otherwise does not exist
cpu.topology attribute     CPU topology related features
    hardware_multithreading bool Hardware multithreading, such as Intel HTT, is enabled
kernel.config attribute     Kernel configuration options
    <config-flag> string Value of the kconfig option
kernel.loadedmodule flag     Loaded kernel modules
    mod-name   Kernel module <mod-name> is loaded
kernel.selinux attribute     Kernel SELinux related features
    enabled bool true if SELinux has been enabled and is in enforcing mode, otherwise false
kernel.version attribute     Kernel version information
    full string Full kernel version (e.g. ‘4.5.6-7-g123abcde')
    major int First component of the kernel version (e.g. ‘4')
    minor int Second component of the kernel version (e.g. ‘5')
    revision int Third component of the kernel version (e.g. ‘6')
local.label attribute     Features from hooks and feature files, i.e. labels from the local feature source
    <label-name> string Label <label-name> created by the local feature source, value equals the value of the label
memory.nv instance     NVDIMM devices present in the system
    <sysfs-attribute> string Value of the sysfs device attribute, available attributes: devtype, mode
memory.numa attribute     NUMA nodes
    is_numa bool true if NUMA architecture, false otherwise
    node_count int Number of NUMA nodes
network.device instance     Physical (non-virtual) network interfaces present in the system
    name string Name of the network interface
    <sysfs-attribute> string Sysfs network interface attribute, available attributes: operstate, speed, sriov_numvfs, sriov_totalvfs
pci.device instance     PCI devices present in the system
    <sysfs-attribute> string Value of the sysfs device attribute, available attributes: class, vendor, device, subsystem_vendor, subsystem_device, sriov_totalvfs, iommu_group/type
storage.device instance     Block storage devices present in the system
    name string Name of the block device
    <sysfs-attribute> string Sysfs network interface attribute, available attributes: dax, rotational, nr_zones, zoned
system.osrelease attribute     System identification data from /etc/os-release
    <parameter> string One parameter from /etc/os-release
system.name attribute     System name information
    nodename string Name of the kubernetes node object
usb.device instance     USB devices present in the system
    <sysfs-attribute> string Value of the sysfs device attribute, available attributes: class, vendor, device, serial
rule.matched attribute     Previously matched rules
    <label-or-var> string Label or var from a preceding rule that matched

Templating

Rules support template-based creation of labels and vars with the .labelsTemplate and .varsTemplate fields. These makes it possible to dynamically generate labels and vars based on the features that matched.

The template must expand into a simple format with <key>=<value> pairs separated by newline.

Consider the following example:

    labelsTemplate: |
      {{ range .pci.device }}vendor-{{ .class }}-{{ .device }}.present=true
      {{ end }}
    matchFeatures:
      - feature: pci.device
        matchExpressions:
          class: {op: InRegexp, value: ["^02"]}
          vendor: ["0fff"]

The rule above will create individual labels feature.node.kubernetes.io/vendor-<class-id>-<device-id>.present=true for each network controller device (device class starting with 02) from vendor 0ffff.

All the matched features of each feature matcher term under matchFeatures fields are available for the template engine. Matched features can be referenced with {{ .<feature-name> }} in the template, and the available data could be described in yaml as follows:

.
  <key-feature>:
    - Name: <matched-key>
    - ...

  <value-feature>:
    - Name: <matched-key>
      Value: <matched-value>
    - ...

  <instance-feature>:
    - <attribute-1-name>: <attribute-1-value>
      <attribute-2-name>: <attribute-2-value>
      ...
    - ...

That is, the per-feature data is a list of objects whose data fields depend on the type of the feature:

  • for flag features only ‘Name' is available
  • for value features ‘Name' and ‘Value' are available
  • for instance features all attributes of the matched instance are available

A simple example of a template utilizing name and value from an attribute feature:

    labelsTemplate: |
      {{ range .system.osrelease }}system-{{ .Name }}={{ .Value }}
      {{ end }}
    matchFeatures:
      - feature: system.osRelease
        matchExpressions:
          ID: {op: Exists}
          VERSION_ID.major: {op: Exists}

NOTE In case of matchAny is specified, the template is executed separately against each individual matchFeatures field and the final set of labels will be superset of all these separate template expansions. E.g. consider the following:

  - name: <name>
    labelsTemplate: <template>
    matchFeatures: <matcher#1>
    matchAny:
      - matchFeatures: <matcher#2>
      - matchFeatures: <matcher#3>

In the example above (assuming the overall result is a match) the template would be executed on matcher#1 as well as on matcher#2 and/or matcher#3 (depending on whether both or only one of them match). All the labels from these separate expansions would be created, i.e. the end result would be a union of all the individual expansions.

A special case of an empty matchExpressions field matches everything, i.e. matches/returns all elements of the feature. This makes it possible to write templates that run over all discovered features.

Consider the following example:

    labelsTemplate: |
      {{ range .network.device }}net-{{ .name }}.speed-mbps={{ .speed }}
      {{ end }}
    matchFeatures:
      - feature: network.device
        matchExpressions: null

This will create individual feature.node.kubernetes.io/net-<if-name>.speed-mbpx=<speed-in-mbps> label for each (physical) network device of the system.

Rule templates use the Golang text/template package and all its built-in functionality (e.g. pipelines and functions) can be used. An example template taking use of the built-in len function, advertising the number of PCI network controllers from a specific vendor:

    labelsTemplate: |
      num-intel-network-controllers={{ .pci.device | len }}
    matchFeatures:
      - feature: pci.device
        matchExpressions:
          vendor: {op: In, value: ["8086"]}
          class: {op: In, value: ["0200"]}

Imaginative template pipelines are possible, but care must be taken in order to produce understandable and maintainable rule sets.

Backreferences

Rules support referencing the output of preceding rules. This enables sophisticated scenarios where multiple rules are combined together to for more complex heuristics than a single rule can provide. The labels and vars created by the execution of preceding rules are available as a special rule.matched feature.

Consider the following configuration:

  - name: "my kernel label rule"
    labels:
      kernel-feature: "true"
    matchFeatures:
      - feature: kernel.version
        matchExpressions:
          major: {op: Gt, value: ["4"]}

  - name: "my var rule"
    vars:
      nolabel-feature: "true"
    matchFeatures:
      - feature: cpu.cpuid
        matchExpressions:
          AVX512F: {op: Exists}
      - feature: pci.device
        matchExpressions:
          vendor: {op: In, value: ["0fff"]}
          device: {op: In, value: ["1234", "1235"]}

  - name: "my high level feature rule"
    labels:
      high-level-feature: "true"
    matchFeatures:
      - feature: rule.matched
        matchExpressions:
          kernel-feature: {op: IsTrue}
          nolabel-feature: {op: IsTrue}

The feature.node.kubernetes.io/high-level-feature = true label depends on thw two previous rules.

Note that when referencing rules accross multiple NodeFeatureRule objects attention must be paid to the ordering. NodeFeatureRule objects are processed in alphabetical order (based on their .metadata.name).

Examples

Some more configuration examples below.

Match certain CPUID features:

  - name: "example cpuid rule"
    labels:
      my-special-cpu-feature: "true"
    matchFeatures:
      - feature: cpu.cpuid
        matchExpressions:
          AESNI: {op: Exists}
          AVX: {op: Exists}

Require a certain loaded kernel module and OS version:

  - name: "my multi-feature rule"
    labels:
      my-special-multi-feature: "true"
    matchFeatures:
      - feature: kernel.loadedmodule
        matchExpressions:
          e1000: {op: Exists}
      - feature: system.osrelease
        matchExpressions:
          NAME: {op: InRegexp, values: ["^openSUSE"]}
          VERSION_ID.major: {op: Gt, values: ["14"]}

Require a loaded kernel module and two specific PCI devices (both of which must be present):

  - name: "my multi-device rule"
    labels:
      my-multi-device-feature: "true"
    matchFeatures:
      - feature: kernel.loadedmodule
        matchExpressions:
          my-driver-module: {op: Exists}
      - pci.device:
          vendor: "0fff"
          device: "1234"
      - pci.device:
          vendor: "0fff"
          device: "abcd"

Legacy custom rule syntax

DEPRECATED: use the new rule syntax instead.

The custom source supports the legacy matchOn rule syntax for backwards-compatibility.

To aid in making the legacy rule syntax clearer, we define a general and a per rule nomenclature, keeping things as consistent as possible.

General nomenclature and definitions

Rule        :Represents a matching logic that is used to match on a feature.
Rule Input  :The input a Rule is provided. This determines how a Rule performs the match operation.
Matcher     :A composition of Rules, each Matcher may be composed of at most one instance of each Rule.

Custom features format (using the nomenclature defined above)

Rules are specified under sources.custom in the nfd-worker configuration file.

sources:
  custom:
  - name: <feature name>
    value: <optional feature value, defaults to "true">
    matchOn:
    - <Rule-1>: <Rule-1 Input>
      [<Rule-2>: <Rule-2 Input>]
    - <Matcher-2>
    - ...
    - ...
    - <Matcher-N>
  - <custom feature 2>
  - ...
  - ...
  - <custom feature M>

The label is constructed by adding custom- prefix to the name field, label value defaults to true if not specified in the rule spec:

feature.node.kubernetes.io/custom-<name> = <value>

Matching process

Specifying Rules to match on a feature is done by providing a list of Matchers. Each Matcher contains one or more Rules.

Logical OR is performed between Matchers and logical AND is performed between Rules of a given Matcher.

Rules

pciid rule

Nomenclature
Attribute   :A PCI attribute.
Element     :An identifier of the PCI attribute.

The PciId Rule allows matching the PCI devices in the system on the following Attributes: class,vendor and device. A list of Elements is provided for each Attribute.

Format
pciId :
  class: [<class id>, ...]
  vendor: [<vendor id>,  ...]
  device: [<device id>, ...]

Matching is done by performing a logical OR between Elements of an Attribute and logical AND between the specified Attributes for each PCI device in the system. At least one Attribute must be specified. Missing attributes will not partake in the matching process.

UsbId rule

Nomenclature
Attribute   :A USB attribute.
Element     :An identifier of the USB attribute.

The UsbId Rule allows matching the USB devices in the system on the following Attributes: class,vendor, device and serial. A list of Elements is provided for each Attribute.

Format
usbId :
  class: [<class id>, ...]
  vendor: [<vendor id>,  ...]
  device: [<device id>, ...]
  serial: [<serial>, ...]

Matching is done by performing a logical OR between Elements of an Attribute and logical AND between the specified Attributes for each USB device in the system. At least one Attribute must be specified. Missing attributes will not partake in the matching process.

LoadedKMod rule

Nomenclature
Element     :A kernel module

The LoadedKMod Rule allows matching the loaded kernel modules in the system against a provided list of Elements.

Format
loadedKMod : [<kernel module>, ...]

Matching is done by performing logical AND for each provided Element, i.e the Rule will match if all provided Elements (kernel modules) are loaded in the system.

CpuId rule

Nomenclature
Element     :A CPUID flag

The Rule allows matching the available CPUID flags in the system against a provided list of Elements.

Format
cpuId : [<CPUID flag string>, ...]

Matching is done by performing logical AND for each provided Element, i.e the Rule will match if all provided Elements (CPUID flag strings) are available in the system.

Kconfig rule

Nomenclature
Element     :A Kconfig option

The Rule allows matching the kconfig options in the system against a provided list of Elements.

Format
kConfig: [<kernel config option ('y' or 'm') or '=<value>'>, ...]

Matching is done by performing logical AND for each provided Element, i.e the Rule will match if all provided Elements (kernel config options) are enabled (y or m) or matching =<value> in the kernel.

Nodename rule

Nomenclature
Element     :A nodename regexp pattern

The Rule allows matching the node's name against a provided list of Elements.

Format
nodename: [ <nodename regexp pattern>, ... ]

Matching is done by performing logical OR for each provided Element, i.e the Rule will match if one of the provided Elements (nodename regexp pattern) matches the node's name.

Legacy custom rule example

custom:
  - name: "my.kernel.feature"
    matchOn:
      - loadedKMod: ["kmod1", "kmod2"]
  - name: "my.pci.feature"
    matchOn:
      - pciId:
          vendor: ["15b3"]
          device: ["1014", "1017"]
  - name: "my.usb.feature"
    matchOn:
      - usbId:
          vendor: ["1d6b"]
          device: ["0003"]
          serial: ["090129a"]
  - name: "my.combined.feature"
    matchOn:
      - loadedKMod : ["vendor_kmod1", "vendor_kmod2"]
        pciId:
          vendor: ["15b3"]
          device: ["1014", "1017"]
  - name: "vendor.feature.node.kubernetes.io/accumulated.feature"
    matchOn:
      - loadedKMod : ["some_kmod1", "some_kmod2"]
      - pciId:
          vendor: ["15b3"]
          device: ["1014", "1017"]
  - name: "my.kernel.featureneedscpu"
    matchOn:
      - kConfig: ["KVM_INTEL"]
      - cpuId: ["VMX"]
  - name: "my.kernel.modulecompiler"
    matchOn:
      - kConfig: ["GCC_VERSION=100101"]
        loadedKMod: ["kmod1"]
  - name: "profile.node.kubernetes.io/my-datacenter"
    value: "datacenter-1"
    matchOn:
      - nodename: [ "node-datacenter1-rack.*-server.*" ]

In the example above:

  • A node would contain the label: feature.node.kubernetes.io/custom-my.kernel.feature=true if the node has kmod1 AND kmod2 kernel modules loaded.
  • A node would contain the label: feature.node.kubernetes.io/custom-my.pci.feature=true if the node contains a PCI device with a PCI vendor ID of 15b3 AND PCI device ID of 1014 OR 1017.
  • A node would contain the label: feature.node.kubernetes.io/custom-my.usb.feature=true if the node contains a USB device with a USB vendor ID of 1d6b AND USB device ID of 0003.
  • A node would contain the label: feature.node.kubernetes.io/custom-my.combined.feature=true if vendor_kmod1 AND vendor_kmod2 kernel modules are loaded AND the node contains a PCI device with a PCI vendor ID of 15b3 AND PCI device ID of 1014 or 1017.
  • A node would contain the label: vendor.feature.node.kubernetes.io/accumulated.feature=true if some_kmod1 AND some_kmod2 kernel modules are loaded OR the node contains a PCI device with a PCI vendor ID of 15b3 AND PCI device ID of 1014 OR 1017.
  • A node would contain the label: feature.node.kubernetes.io/custom-my.kernel.featureneedscpu=true if KVM_INTEL kernel config is enabled AND the node CPU supports VMX virtual machine extensions
  • A node would contain the label: feature.node.kubernetes.io/custom-my.kernel.modulecompiler=true if the in-tree kmod1 kernel module is loaded AND it's built with GCC_VERSION=100101.
  • A node would contain the label: profile.node.kubernetes.io/my-datacenter=datacenter-1 if the node's name matches the node-datacenter1-rack.*-server.* pattern, e.g. node-datacenter1-rack2-server42