Provisioners

When you first installed Karpenter, you set up a default Provisioner. The Provisioner sets constraints on the nodes that can be created by Karpenter and the pods that can run on those nodes. The Provisioner can be set to do things like:

• Define taints to limit the pods that can run on nodes Karpenter creates
• Define any startup taints to inform Karpenter that it should taint the node initially, but that the taint is temporary.
• Limit node creation to certain zones, instance types, and computer architectures
• Set defaults for node expiration

You can change your Provisioner or add other Provisioners to Karpenter. Here are things you should know about Provisioners:

• Karpenter won’t do anything if there is not at least one Provisioner configured.
• Each Provisioner that is configured is looped through by Karpenter.
• If Karpenter encounters a taint in the Provisioner that is not tolerated by a Pod, Karpenter won’t use that Provisioner to provision the pod.
• If Karpenter encounters a startup taint in the Provisioner it will be applied to nodes that are provisioned, but pods do not need to tolerate the taint. Karpenter assumes that the taint is temporary and some other system will remove the taint.
• It is recommended to create Provisioners that are mutually exclusive. So no Pod should match multiple Provisioners. If multiple Provisioners are matched, Karpenter will use the Provisioner with the highest weight.

For some example Provisioner configurations, see the examples in the Karpenter GitHub repository.

apiVersion: karpenter.sh/v1alpha5
kind: Provisioner
metadata:
  name: default
spec:
  # References cloud provider-specific custom resource, see your cloud provider specific documentation
  providerRef:
    name: default

  # Provisioned nodes will have these taints
  # Taints may prevent pods from scheduling if they are not tolerated by the pod.
  taints:
    - key: example.com/special-taint
      effect: NoSchedule

  # Provisioned nodes will have these taints, but pods do not need to tolerate these taints to be provisioned by this
  # provisioner. These taints are expected to be temporary and some other entity (e.g. a DaemonSet) is responsible for
  # removing the taint after it has finished initializing the node.
  startupTaints:
    - key: example.com/another-taint
      effect: NoSchedule

  # Labels are arbitrary key-values that are applied to all nodes
  labels:
    billing-team: my-team

  # Annotations are arbitrary key-values that are applied to all nodes
  annotations:
    example.com/owner: "my-team"

  # Requirements that constrain the parameters of provisioned nodes.
  # These requirements are combined with pod.spec.affinity.nodeAffinity rules.
  # Operators { In, NotIn } are supported to enable including or excluding values
  requirements:
    - key: "karpenter.k8s.aws/instance-category"
      operator: In
      values: ["c", "m", "r"]
    - key: "karpenter.k8s.aws/instance-cpu"
      operator: In
      values: ["4", "8", "16", "32"]
    - key: "karpenter.k8s.aws/instance-hypervisor"
      operator: In
      values: ["nitro"]
    - key: "karpenter.k8s.aws/instance-generation"
      operator: Gt
      values: ["2"]
    - key: "topology.kubernetes.io/zone"
      operator: In
      values: ["us-west-2a", "us-west-2b"]
    - key: "kubernetes.io/arch"
      operator: In
      values: ["arm64", "amd64"]
    - key: "karpenter.sh/capacity-type" # If not included, the webhook for the AWS cloud provider will default to on-demand
      operator: In
      values: ["spot", "on-demand"]

  # Karpenter provides the ability to specify a few additional Kubelet args.
  # These are all optional and provide support for additional customization and use cases.
  kubeletConfiguration:
    clusterDNS: ["10.0.1.100"]
    containerRuntime: containerd
    systemReserved:
      cpu: 100m
      memory: 100Mi
      ephemeral-storage: 1Gi
    kubeReserved:
      cpu: 200m
      memory: 100Mi
      ephemeral-storage: 3Gi
    evictionHard:
      memory.available: 5%
      nodefs.available: 10%
      nodefs.inodesFree: 10%
    evictionSoft:
      memory.available: 500Mi
      nodefs.available: 15%
      nodefs.inodesFree: 15%
    evictionSoftGracePeriod:
      memory.available: 1m
      nodefs.available: 1m30s
      nodefs.inodesFree: 2m
    evictionMaxPodGracePeriod: 60
    imageGCHighThresholdPercent: 85
    imageGCLowThresholdPercent: 80
    cpuCFSQuota: true
    podsPerCore: 2
    maxPods: 20


  # Resource limits constrain the total size of the cluster.
  # Limits prevent Karpenter from creating new instances once the limit is exceeded.
  limits:
    resources:
      cpu: "1000"
      memory: 1000Gi

  # Enables consolidation which attempts to reduce cluster cost by both removing un-needed nodes and down-sizing those
  # that can't be removed.  Mutually exclusive with the ttlSecondsAfterEmpty parameter.
  consolidation:
    enabled: true

  # If omitted, the feature is disabled and nodes will never expire.  If set to less time than it requires for a node
  # to become ready, the node may expire before any pods successfully start.
  ttlSecondsUntilExpired: 2592000 # 30 Days = 60 * 60 * 24 * 30 Seconds;

  # If omitted, the feature is disabled, nodes will never scale down due to low utilization
  ttlSecondsAfterEmpty: 30

  # Priority given to the provisioner when the scheduler considers which provisioner
  # to select. Higher weights indicate higher priority when comparing provisioners.
  # Specifying no weight is equivalent to specifying a weight of 0.
  weight: 10

spec.requirements

Kubernetes defines the following Well-Known Labels, and cloud providers (e.g., AWS) implement them. They are defined at the “spec.requirements” section of the Provisioner API.

In addition to the well-known labels from Kubernetes, Karpenter supports AWS-specific labels for more advanced scheduling. See the full list here.

These well-known labels may be specified at the provisioner level, or in a workload definition (e.g., nodeSelector on a pod.spec). Nodes are chosen using both the provisioner’s and pod’s requirements. If there is no overlap, nodes will not be launched. In other words, a pod’s requirements must be within the provisioner’s requirements. If a requirement is not defined for a well known label, any value available to the cloud provider may be chosen.

For example, an instance type may be specified using a nodeSelector in a pod spec. If the instance type requested is not included in the provisioner list and the provisioner has instance type requirements, Karpenter will not create a node or schedule the pod.

📝 None of these values are required.

Instance Types

• key: node.kubernetes.io/instance-type
• key: karpenter.k8s.aws/instance-family
• key: karpenter.k8s.aws/instance-category
• key: karpenter.k8s.aws/instance-generation

Generally, instance types should be a list and not a single value. Leaving these requirements undefined is recommended, as it maximizes choices for efficiently placing pods.

Review AWS instance types. Most instance types are supported with the exclusion of non-HVM.

requirements:
  - key: karpenter.k8s.aws/instance-category
    operator: In
    values: ["c", "m", "r"]
  - key: karpenter.k8s.aws/instance-generation
    operator: Gt
    values: ["2"]

Availability Zones

• key: topology.kubernetes.io/zone
• value example: us-east-1c
• value list: aws ec2 describe-availability-zones --region <region-name>

Karpenter can be configured to create nodes in a particular zone. Note that the Availability Zone us-east-1a for your AWS account might not have the same location as us-east-1a for another AWS account.

Learn more about Availability Zone IDs.

Architecture

• key: kubernetes.io/arch
• values
  • amd64
  • arm64

Karpenter supports amd64 nodes, and arm64 nodes.

requirements:
  - key: kubernetes.io/arch
    operator: In
    values: ["amd64"]

Operating System

• key: kubernetes.io/os
• values
  • linux
  • windows

Karpenter supports linux and windows operating systems.

requirements:
  - key: kubernetes.io/os
    operator: In
    values: ["linux"]

Capacity Type

• key: karpenter.sh/capacity-type
• values
  • spot
  • on-demand

Karpenter supports specifying capacity type, which is analogous to EC2 purchase options.

Karpenter prioritizes Spot offerings if the provisioner allows Spot and on-demand instances. If the provider API (e.g. EC2 Fleet’s API) indicates Spot capacity is unavailable, Karpenter caches that result across all attempts to provision EC2 capacity for that instance type and zone for the next 45 seconds. If there are no other possible offerings available for Spot, Karpenter will attempt to provision on-demand instances, generally within milliseconds.

Karpenter also allows karpenter.sh/capacity-type to be used as a topology key for enforcing topology-spread.

requirements:
  - key: karpenter.sh/capacity-type
    operator: In
    values: ["on-demand"]

spec.weight

Karpenter allows you to describe provisioner preferences through a weight mechanism similar to how weight is described with pod and node affinities.

For more information on weighting Provisioners, see the Weighting Provisioners section in the scheduling details.

spec.kubeletConfiguration

Karpenter provides the ability to specify a few additional Kubelet args. These are all optional and provide support for additional customization and use cases. Adjust these only if you know you need to do so. For more details on kubelet configuration arguments, see the KubeletConfiguration API specification docs. The implemented fields are a subset of the full list of upstream kubelet configuration arguments. Please cut an issue if you’d like to see another field implemented.

spec:
  ...
  kubeletConfiguration:
    clusterDNS: ["10.0.1.100"]
    containerRuntime: containerd
    systemReserved:
      cpu: 100m
      memory: 100Mi
      ephemeral-storage: 1Gi
    kubeReserved:
      cpu: 200m
      memory: 100Mi
      ephemeral-storage: 3Gi
    evictionHard:
      memory.available: 5%
      nodefs.available: 10%
      nodefs.inodesFree: 10%
    evictionSoft:
      memory.available: 500Mi
      nodefs.available: 15%
      nodefs.inodesFree: 15%
    evictionSoftGracePeriod:
      memory.available: 1m
      nodefs.available: 1m30s
      nodefs.inodesFree: 2m
    evictionMaxPodGracePeriod: 60
    imageGCHighThresholdPercent: 85
    imageGCLowThresholdPercent: 80
    cpuCFSQuota: true
    podsPerCore: 2
    maxPods: 20

You can specify the container runtime to be either dockerd or containerd. By default, containerd is used.

• containerd is the only valid container runtime when using the Bottlerocket AMIFamily or when using Kubernetes version 1.24+ and the AL2, Windows2019, or Windows2022 AMIFamilies.

Reserved Resources

Karpenter will automatically configure the system and kube reserved resource requests on the fly on your behalf. These requests are used to configure your node and to make scheduling decisions for your pods. If you have specific requirements or know that you will have additional capacity requirements, you can optionally override the --system-reserved configuration defaults with the .spec.kubeletConfiguration.systemReserved values and the --kube-reserved configuration defaults with the .spec.kubeletConfiguration.kubeReserved values.

For more information on the default --system-reserved and --kube-reserved configuration refer to the Kubelet Docs

Eviction Thresholds

The kubelet supports eviction thresholds by default. When enough memory or file system pressure is exerted on the node, the kubelet will begin to evict pods to ensure that system daemons and other system processes can continue to run in a healthy manner.

Kubelet has the notion of hard evictions and soft evictions. In hard evictions, pods are evicted as soon as a threshold is met, with no grace period to terminate. Soft evictions, on the other hand, provide an opportunity for pods to be terminated gracefully. They do so by sending a termination signal to pods that are planning to be evicted and allowing those pods to terminate up to their grace period.

Karpenter supports hard evictions through the .spec.kubeletConfiguration.evictionHard field and soft evictions through the .spec.kubeletConfiguration.evictionSoft field. evictionHard and evictionSoft are configured by listing signal names with either percentage values or resource values.

spec:
  ...
  kubeletConfiguration:
    evictionHard:
      memory.available: 500Mi
      nodefs.available: 10%
      nodefs.inodesFree: 10%
      imagefs.available: 5%
      imagefs.inodesFree: 5%
      pid.available: 7%
    evictionSoft:
      memory.available: 1Gi
      nodefs.available: 15%
      nodefs.inodesFree: 15%
      imagefs.available: 10%
      imagefs.inodesFree: 10%
      pid.available: 10%

Supported Eviction Signals

For more information on eviction thresholds, view the Node-pressure Eviction section of the official Kubernetes docs.

Soft Eviction Grace Periods

Soft eviction pairs an eviction threshold with a specified grace period. With soft eviction thresholds, the kubelet will only begin evicting pods when the node exceeds its soft eviction threshold over the entire duration of its grace period. For example, if you specify evictionSoft[memory.available] of 500Mi and a evictionSoftGracePeriod[memory.available] of 1m30, the node must have less than 500Mi of available memory over a minute and a half in order for the kubelet to begin evicting pods.

Optionally, you can specify an evictionMaxPodGracePeriod which defines the administrator-specified maximum pod termination grace period to use during soft eviction. If a namespace-owner had specified a pod terminationGracePeriodInSeconds on pods in their namespace, the minimum of evictionPodGracePeriod and terminationGracePeriodInSeconds would be used.

spec:
  ...
  kubeletConfiguration:
    evictionSoftGracePeriod:
      memory.available: 1m
      nodefs.available: 1m30s
      nodefs.inodesFree: 2m
      imagefs.available: 1m30s
      imagefs.inodesFree: 2m
      pid.available: 2m
    evictionMaxPodGracePeriod: 60

Pod Density

Max Pods

By default, AWS will configure the maximum density of pods on a node based on the node instance type. For small instances that require an increased pod density or large instances that require a reduced pod density, you can override this default value with .spec.kubeletConfiguration.maxPods. This value will be used during Karpenter pod scheduling and passed through to --max-pods on kubelet startup.

Pods Per Core

An alternative way to dynamically set the maximum density of pods on a node is to use the .spec.kubeletConfiguration.podsPerCore value. Karpenter will calculate the pod density during scheduling by multiplying this value by the number of logical cores (vCPUs) on an instance type. This value will also be passed through to the --pods-per-core value on kubelet startup to configure the number of allocatable pods the kubelet can assign to the node instance.

The value generated from podsPerCore cannot exceed maxPods, meaning, if both are set, the minimum of the podsPerCore dynamic pod density and the static maxPods value will be used for scheduling.

spec.limits.resources

The provisioner spec includes a limits section (spec.limits.resources), which constrains the maximum amount of resources that the provisioner will manage.

Karpenter supports limits of any resource type reported by your cloudprovider. It limits instance types when scheduling to those that will not exceed the specified limits. If a limit has been exceeded, nodes provisioning is prevented until some nodes have been terminated.

apiVersion: karpenter.sh/v1alpha5
kind: Provisioner
metadata:
  name: default
spec:
  requirements:
    - key: karpenter.sh/capacity-type
      operator: In
      values: ["spot"]
  limits:
    resources:
      cpu: 1000
      memory: 1000Gi
      nvidia.com/gpu: 2

CPU limits are described with a DecimalSI value. Note that the Kubernetes API will coerce this into a string, so we recommend against using integers to avoid GitOps skew.

Memory limits are described with a BinarySI value, such as 1000Gi.

You can view the current consumption of cpu and memory on your cluster by running:

kubectl get provisioner -o=jsonpath='{.items[0].status}'

Review the Kubernetes core API (k8s.io/api/core/v1) for more information on resources.

spec.providerRef

This field points to the cloud provider-specific custom resource. Learn more about AWSNodeTemplates.

spec.consolidation

You can configure Karpenter to deprovision instances through your Provisioner in multiple ways. You can use spec.ttlSecondsAfterEmpty, spec.ttlSecondsUntilExpired or spec.consolidation.enabled. Read Deprovisioning for more.

Example Use-Cases

Isolating Expensive Hardware

A provisioner can be set up to only provision nodes on particular processor types. The following example sets a taint that only allows pods with tolerations for Nvidia GPUs to be scheduled:

apiVersion: karpenter.sh/v1alpha5
kind: Provisioner
metadata:
  name: gpu
spec:
  consolidation:
    enabled: true
  requirements:
  - key: node.kubernetes.io/instance-type
    operator: In
    values: ["p3.8xlarge", "p3.16xlarge"]
  taints:
  - key: nvidia.com/gpu
    value: "true"
    effect: NoSchedule

In order for a pod to run on a node defined in this provisioner, it must tolerate nvidia.com/gpu in its pod spec.

Cilium Startup Taint

Per the Cilium docs, it’s recommended to place a taint of node.cilium.io/agent-not-ready=true:NoExecute on nodes to allow Cilium to configure networking prior to other pods starting. This can be accomplished via the use of Karpenter startupTaints. These taints are placed on the node, but pods aren’t required to tolerate these taints to be considered for provisioning.

apiVersion: karpenter.sh/v1alpha5
kind: Provisioner
metadata:
  name: cilium-startup
spec:
  consolidation:
    enabled: true
  startupTaints:
  - key: node.cilium.io/agent-not-ready
    value: "true"
    effect: NoExecute