Assigning Pods to Nodes
You can constrain a Pod so that it is restricted to run on particular node(s), or to prefer to run on particular nodes. There are several ways to do this and the recommended approaches all use label selectors to facilitate the selection. Often, you do not need to set any such constraints; the scheduler will automatically do a reasonable placement (for example, spreading your Pods across nodes so as not place Pods on a node with insufficient free resources). However, there are some circumstances where you may want to control which node the Pod deploys to, for example, to ensure that a Pod ends up on a node with an SSD attached to it, or to co-locate Pods from two different services that communicate a lot into the same availability zone.
You can use any of the following methods to choose where Kubernetes schedules specific Pods:
- nodeSelector field matching against node labels
- Affinity and anti-affinity
- nodeName field
- Pod topology spread constraints
Node labels
Like many other Kubernetes objects, nodes have labels. You can attach labels manually. Kubernetes also populates a standard set of labels on all nodes in a cluster.
Note:
The value of these labels is cloud provider specific and is not guaranteed to be reliable. For example, the value ofkubernetes.io/hostname
may be the same as the node name in some environments
and a different value in other environments.Node isolation/restriction
Adding labels to nodes allows you to target Pods for scheduling on specific nodes or groups of nodes. You can use this functionality to ensure that specific Pods only run on nodes with certain isolation, security, or regulatory properties.
If you use labels for node isolation, choose label keys that the kubelet cannot modify. This prevents a compromised node from setting those labels on itself so that the scheduler schedules workloads onto the compromised node.
The NodeRestriction
admission plugin
prevents the kubelet from setting or modifying labels with a
node-restriction.kubernetes.io/
prefix.
To make use of that label prefix for node isolation:
- Ensure you are using the Node authorizer and have enabled the
NodeRestriction
admission plugin. - Add labels with the
node-restriction.kubernetes.io/
prefix to your nodes, and use those labels in your node selectors. For example,example.com.node-restriction.kubernetes.io/fips=true
orexample.com.node-restriction.kubernetes.io/pci-dss=true
.
nodeSelector
nodeSelector
is the simplest recommended form of node selection constraint.
You can add the nodeSelector
field to your Pod specification and specify the
node labels you want the target node to have.
Kubernetes only schedules the Pod onto nodes that have each of the labels you
specify.
See Assign Pods to Nodes for more information.
Affinity and anti-affinity
nodeSelector
is the simplest way to constrain Pods to nodes with specific
labels. Affinity and anti-affinity expands the types of constraints you can
define. Some of the benefits of affinity and anti-affinity include:
- The affinity/anti-affinity language is more expressive.
nodeSelector
only selects nodes with all the specified labels. Affinity/anti-affinity gives you more control over the selection logic. - You can indicate that a rule is soft or preferred, so that the scheduler still schedules the Pod even if it can't find a matching node.
- You can constrain a Pod using labels on other Pods running on the node (or other topological domain), instead of just node labels, which allows you to define rules for which Pods can be co-located on a node.
The affinity feature consists of two types of affinity:
- Node affinity functions like the
nodeSelector
field but is more expressive and allows you to specify soft rules. - Inter-pod affinity/anti-affinity allows you to constrain Pods against labels on other Pods.
Node affinity
Node affinity is conceptually similar to nodeSelector
, allowing you to constrain which nodes your
Pod can be scheduled on based on node labels. There are two types of node
affinity:
requiredDuringSchedulingIgnoredDuringExecution
: The scheduler can't schedule the Pod unless the rule is met. This functions likenodeSelector
, but with a more expressive syntax.preferredDuringSchedulingIgnoredDuringExecution
: The scheduler tries to find a node that meets the rule. If a matching node is not available, the scheduler still schedules the Pod.
Note:
In the preceding types,IgnoredDuringExecution
means that if the node labels
change after Kubernetes schedules the Pod, the Pod continues to run.You can specify node affinities using the .spec.affinity.nodeAffinity
field in
your Pod spec.
For example, consider the following Pod spec:
apiVersion: v1
kind: Pod
metadata:
name: with-node-affinity
spec:
affinity:
nodeAffinity:
requiredDuringSchedulingIgnoredDuringExecution:
nodeSelectorTerms:
- matchExpressions:
- key: topology.kubernetes.io/zone
operator: In
values:
- antarctica-east1
- antarctica-west1
preferredDuringSchedulingIgnoredDuringExecution:
- weight: 1
preference:
matchExpressions:
- key: another-node-label-key
operator: In
values:
- another-node-label-value
containers:
- name: with-node-affinity
image: registry.k8s.io/pause:2.0
In this example, the following rules apply:
- The node must have a label with the key
topology.kubernetes.io/zone
and the value of that label must be eitherantarctica-east1
orantarctica-west1
. - The node preferably has a label with the key
another-node-label-key
and the valueanother-node-label-value
.
You can use the operator
field to specify a logical operator for Kubernetes to use when
interpreting the rules. You can use In
, NotIn
, Exists
, DoesNotExist
,
Gt
and Lt
.
Read Operators to learn more about how these work.
NotIn
and DoesNotExist
allow you to define node anti-affinity behavior.
Alternatively, you can use node taints
to repel Pods from specific nodes.
Note:
If you specify both nodeSelector
and nodeAffinity
, both must be satisfied
for the Pod to be scheduled onto a node.
If you specify multiple terms in nodeSelectorTerms
associated with nodeAffinity
types, then the Pod can be scheduled onto a node if one of the specified terms
can be satisfied (terms are ORed).
If you specify multiple expressions in a single matchExpressions
field associated with a
term in nodeSelectorTerms
, then the Pod can be scheduled onto a node only
if all the expressions are satisfied (expressions are ANDed).
See Assign Pods to Nodes using Node Affinity for more information.
Node affinity weight
You can specify a weight
between 1 and 100 for each instance of the
preferredDuringSchedulingIgnoredDuringExecution
affinity type. When the
scheduler finds nodes that meet all the other scheduling requirements of the Pod, the
scheduler iterates through every preferred rule that the node satisfies and adds the
value of the weight
for that expression to a sum.
The final sum is added to the score of other priority functions for the node. Nodes with the highest total score are prioritized when the scheduler makes a scheduling decision for the Pod.
For example, consider the following Pod spec:
apiVersion: v1
kind: Pod
metadata:
name: with-affinity-preferred-weight
spec:
affinity:
nodeAffinity:
requiredDuringSchedulingIgnoredDuringExecution:
nodeSelectorTerms:
- matchExpressions:
- key: kubernetes.io/os
operator: In
values:
- linux
preferredDuringSchedulingIgnoredDuringExecution:
- weight: 1
preference:
matchExpressions:
- key: label-1
operator: In
values:
- key-1
- weight: 50
preference:
matchExpressions:
- key: label-2
operator: In
values:
- key-2
containers:
- name: with-node-affinity
image: registry.k8s.io/pause:2.0
If there are two possible nodes that match the
preferredDuringSchedulingIgnoredDuringExecution
rule, one with the
label-1:key-1
label and another with the label-2:key-2
label, the scheduler
considers the weight
of each node and adds the weight to the other scores for
that node, and schedules the Pod onto the node with the highest final score.
Note:
If you want Kubernetes to successfully schedule the Pods in this example, you must have existing nodes with thekubernetes.io/os=linux
label.Node affinity per scheduling profile
Kubernetes v1.20 [beta]
When configuring multiple scheduling profiles, you can associate
a profile with a node affinity, which is useful if a profile only applies to a specific set of nodes.
To do so, add an addedAffinity
to the args
field of the NodeAffinity
plugin
in the scheduler configuration. For example:
apiVersion: kubescheduler.config.k8s.io/v1beta3
kind: KubeSchedulerConfiguration
profiles:
- schedulerName: default-scheduler
- schedulerName: foo-scheduler
pluginConfig:
- name: NodeAffinity
args:
addedAffinity:
requiredDuringSchedulingIgnoredDuringExecution:
nodeSelectorTerms:
- matchExpressions:
- key: scheduler-profile
operator: In
values:
- foo
The addedAffinity
is applied to all Pods that set .spec.schedulerName
to foo-scheduler
, in addition to the
NodeAffinity specified in the PodSpec.
That is, in order to match the Pod, nodes need to satisfy addedAffinity
and
the Pod's .spec.NodeAffinity
.
Since the addedAffinity
is not visible to end users, its behavior might be
unexpected to them. Use node labels that have a clear correlation to the
scheduler profile name.
Note:
The DaemonSet controller, which creates Pods for DaemonSets, does not support scheduling profiles. When the DaemonSet controller creates Pods, the default Kubernetes scheduler places those Pods and honors anynodeAffinity
rules in the DaemonSet controller.Inter-pod affinity and anti-affinity
Inter-pod affinity and anti-affinity allow you to constrain which nodes your Pods can be scheduled on based on the labels of Pods already running on that node, instead of the node labels.
Inter-pod affinity and anti-affinity rules take the form "this Pod should (or, in the case of anti-affinity, should not) run in an X if that X is already running one or more Pods that meet rule Y", where X is a topology domain like node, rack, cloud provider zone or region, or similar and Y is the rule Kubernetes tries to satisfy.
You express these rules (Y) as label selectors with an optional associated list of namespaces. Pods are namespaced objects in Kubernetes, so Pod labels also implicitly have namespaces. Any label selectors for Pod labels should specify the namespaces in which Kubernetes should look for those labels.
You express the topology domain (X) using a topologyKey
, which is the key for
the node label that the system uses to denote the domain. For examples, see
Well-Known Labels, Annotations and Taints.
Note:
Inter-pod affinity and anti-affinity require substantial amounts of processing which can slow down scheduling in large clusters significantly. We do not recommend using them in clusters larger than several hundred nodes.Note:
Pod anti-affinity requires nodes to be consistently labeled, in other words, every node in the cluster must have an appropriate label matchingtopologyKey
.
If some or all nodes are missing the specified topologyKey
label, it can lead
to unintended behavior.Types of inter-pod affinity and anti-affinity
Similar to node affinity are two types of Pod affinity and anti-affinity as follows:
requiredDuringSchedulingIgnoredDuringExecution
preferredDuringSchedulingIgnoredDuringExecution
For example, you could use
requiredDuringSchedulingIgnoredDuringExecution
affinity to tell the scheduler to
co-locate Pods of two services in the same cloud provider zone because they
communicate with each other a lot. Similarly, you could use
preferredDuringSchedulingIgnoredDuringExecution
anti-affinity to spread Pods
from a service across multiple cloud provider zones.
To use inter-pod affinity, use the affinity.podAffinity
field in the Pod spec.
For inter-pod anti-affinity, use the affinity.podAntiAffinity
field in the Pod
spec.
Scheduling a group of pods with inter-pod affinity to themselves
If the current Pod being scheduled is the first in a series that have affinity to themselves, it is allowed to be scheduled if it passes all other affinity checks. This is determined by verifying that no other pod in the cluster matches the namespace and selector of this pod, that the pod matches its own terms, and the chosen node matches all requested topologies. This ensures that there will not be a deadlock even if all the pods have inter-pod affinity specified.
Pod affinity example
Consider the following Pod spec:
apiVersion: v1
kind: Pod
metadata:
name: with-pod-affinity
spec:
affinity:
podAffinity:
requiredDuringSchedulingIgnoredDuringExecution:
- labelSelector:
matchExpressions:
- key: security
operator: In
values:
- S1
topologyKey: topology.kubernetes.io/zone
podAntiAffinity:
preferredDuringSchedulingIgnoredDuringExecution:
- weight: 100
podAffinityTerm:
labelSelector:
matchExpressions:
- key: security
operator: In
values:
- S2
topologyKey: topology.kubernetes.io/zone
containers:
- name: with-pod-affinity
image: registry.k8s.io/pause:2.0
This example defines one Pod affinity rule and one Pod anti-affinity rule. The
Pod affinity rule uses the "hard"
requiredDuringSchedulingIgnoredDuringExecution
, while the anti-affinity rule
uses the "soft" preferredDuringSchedulingIgnoredDuringExecution
.
The affinity rule specifies that the scheduler is allowed to place the example Pod
on a node only if that node belongs to a specific zone
where other Pods have been labeled with security=S1
.
For instance, if we have a cluster with a designated zone, let's call it "Zone V,"
consisting of nodes labeled with topology.kubernetes.io/zone=V
, the scheduler can
assign the Pod to any node within Zone V, as long as there is at least one Pod within
Zone V already labeled with security=S1
. Conversely, if there are no Pods with security=S1
labels in Zone V, the scheduler will not assign the example Pod to any node in that zone.
The anti-affinity rule specifies that the scheduler should try to avoid scheduling the Pod
on a node if that node belongs to a specific zone
where other Pods have been labeled with security=S2
.
For instance, if we have a cluster with a designated zone, let's call it "Zone R,"
consisting of nodes labeled with topology.kubernetes.io/zone=R
, the scheduler should avoid
assigning the Pod to any node within Zone R, as long as there is at least one Pod within
Zone R already labeled with security=S2
. Conversely, the anti-affinity rule does not impact
scheduling into Zone R if there are no Pods with security=S2
labels.
To get yourself more familiar with the examples of Pod affinity and anti-affinity, refer to the design proposal.
You can use the In
, NotIn
, Exists
and DoesNotExist
values in the
operator
field for Pod affinity and anti-affinity.
Read Operators to learn more about how these work.
In principle, the topologyKey
can be any allowed label key with the following
exceptions for performance and security reasons:
- For Pod affinity and anti-affinity, an empty
topologyKey
field is not allowed in bothrequiredDuringSchedulingIgnoredDuringExecution
andpreferredDuringSchedulingIgnoredDuringExecution
. - For
requiredDuringSchedulingIgnoredDuringExecution
Pod anti-affinity rules, the admission controllerLimitPodHardAntiAffinityTopology
limitstopologyKey
tokubernetes.io/hostname
. You can modify or disable the admission controller if you want to allow custom topologies.
In addition to labelSelector
and topologyKey
, you can optionally specify a list
of namespaces which the labelSelector
should match against using the
namespaces
field at the same level as labelSelector
and topologyKey
.
If omitted or empty, namespaces
defaults to the namespace of the Pod where the
affinity/anti-affinity definition appears.
Namespace selector
Kubernetes v1.24 [stable]
You can also select matching namespaces using namespaceSelector
, which is a label query over the set of namespaces.
The affinity term is applied to namespaces selected by both namespaceSelector
and the namespaces
field.
Note that an empty namespaceSelector
({}) matches all namespaces, while a null or empty namespaces
list and
null namespaceSelector
matches the namespace of the Pod where the rule is defined.
matchLabelKeys
Kubernetes v1.31 [beta]
(enabled by default: true)
Note:
The matchLabelKeys
field is a beta-level field and is enabled by default in
Kubernetes 1.31.
When you want to disable it, you have to disable it explicitly via the
MatchLabelKeysInPodAffinity
feature gate.
Kubernetes includes an optional matchLabelKeys
field for Pod affinity
or anti-affinity. The field specifies keys for the labels that should match with the incoming Pod's labels,
when satisfying the Pod (anti)affinity.
The keys are used to look up values from the pod labels; those key-value labels are combined
(using AND
) with the match restrictions defined using the labelSelector
field. The combined
filtering selects the set of existing pods that will be taken into Pod (anti)affinity calculation.
A common use case is to use matchLabelKeys
with pod-template-hash
(set on Pods
managed as part of a Deployment, where the value is unique for each revision).
Using pod-template-hash
in matchLabelKeys
allows you to target the Pods that belong
to the same revision as the incoming Pod, so that a rolling upgrade won't break affinity.
apiVersion: apps/v1
kind: Deployment
metadata:
name: application-server
...
spec:
template:
spec:
affinity:
podAffinity:
requiredDuringSchedulingIgnoredDuringExecution:
- labelSelector:
matchExpressions:
- key: app
operator: In
values:
- database
topologyKey: topology.kubernetes.io/zone
# Only Pods from a given rollout are taken into consideration when calculating pod affinity.
# If you update the Deployment, the replacement Pods follow their own affinity rules
# (if there are any defined in the new Pod template)
matchLabelKeys:
- pod-template-hash
mismatchLabelKeys
Kubernetes v1.31 [beta]
(enabled by default: true)
Note:
The mismatchLabelKeys
field is a beta-level field and is enabled by default in
Kubernetes 1.31.
When you want to disable it, you have to disable it explicitly via the
MatchLabelKeysInPodAffinity
feature gate.
Kubernetes includes an optional mismatchLabelKeys
field for Pod affinity
or anti-affinity. The field specifies keys for the labels that should not match with the incoming Pod's labels,
when satisfying the Pod (anti)affinity.
One example use case is to ensure Pods go to the topology domain (node, zone, etc) where only Pods from the same tenant or team are scheduled in. In other words, you want to avoid running Pods from two different tenants on the same topology domain at the same time.
apiVersion: v1
kind: Pod
metadata:
labels:
# Assume that all relevant Pods have a "tenant" label set
tenant: tenant-a
...
spec:
affinity:
podAffinity:
requiredDuringSchedulingIgnoredDuringExecution:
# ensure that pods associated with this tenant land on the correct node pool
- matchLabelKeys:
- tenant
topologyKey: node-pool
podAntiAffinity:
requiredDuringSchedulingIgnoredDuringExecution:
# ensure that pods associated with this tenant can't schedule to nodes used for another tenant
- mismatchLabelKeys:
- tenant # whatever the value of the "tenant" label for this Pod, prevent
# scheduling to nodes in any pool where any Pod from a different
# tenant is running.
labelSelector:
# We have to have the labelSelector which selects only Pods with the tenant label,
# otherwise this Pod would hate Pods from daemonsets as well, for example,
# which aren't supposed to have the tenant label.
matchExpressions:
- key: tenant
operator: Exists
topologyKey: node-pool
More practical use-cases
Inter-pod affinity and anti-affinity can be even more useful when they are used with higher level collections such as ReplicaSets, StatefulSets, Deployments, etc. These rules allow you to configure that a set of workloads should be co-located in the same defined topology; for example, preferring to place two related Pods onto the same node.
For example: imagine a three-node cluster. You use the cluster to run a web application and also an in-memory cache (such as Redis). For this example, also assume that latency between the web application and the memory cache should be as low as is practical. You could use inter-pod affinity and anti-affinity to co-locate the web servers with the cache as much as possible.
In the following example Deployment for the Redis cache, the replicas get the label app=store
. The
podAntiAffinity
rule tells the scheduler to avoid placing multiple replicas
with the app=store
label on a single node. This creates each cache in a
separate node.
apiVersion: apps/v1
kind: Deployment
metadata:
name: redis-cache
spec:
selector:
matchLabels:
app: store
replicas: 3
template:
metadata:
labels:
app: store
spec:
affinity:
podAntiAffinity:
requiredDuringSchedulingIgnoredDuringExecution:
- labelSelector:
matchExpressions:
- key: app
operator: In
values:
- store
topologyKey: "kubernetes.io/hostname"
containers:
- name: redis-server
image: redis:3.2-alpine
The following example Deployment for the web servers creates replicas with the label app=web-store
.
The Pod affinity rule tells the scheduler to place each replica on a node that has a Pod
with the label app=store
. The Pod anti-affinity rule tells the scheduler never to place
multiple app=web-store
servers on a single node.
apiVersion: apps/v1
kind: Deployment
metadata:
name: web-server
spec:
selector:
matchLabels:
app: web-store
replicas: 3
template:
metadata:
labels:
app: web-store
spec:
affinity:
podAntiAffinity:
requiredDuringSchedulingIgnoredDuringExecution:
- labelSelector:
matchExpressions:
- key: app
operator: In
values:
- web-store
topologyKey: "kubernetes.io/hostname"
podAffinity:
requiredDuringSchedulingIgnoredDuringExecution:
- labelSelector:
matchExpressions:
- key: app
operator: In
values:
- store
topologyKey: "kubernetes.io/hostname"
containers:
- name: web-app
image: nginx:1.16-alpine
Creating the two preceding Deployments results in the following cluster layout, where each web server is co-located with a cache, on three separate nodes.
node-1 | node-2 | node-3 |
---|---|---|
webserver-1 | webserver-2 | webserver-3 |
cache-1 | cache-2 | cache-3 |
The overall effect is that each cache instance is likely to be accessed by a single client that is running on the same node. This approach aims to minimize both skew (imbalanced load) and latency.
You might have other reasons to use Pod anti-affinity. See the ZooKeeper tutorial for an example of a StatefulSet configured with anti-affinity for high availability, using the same technique as this example.
nodeName
nodeName
is a more direct form of node selection than affinity or
nodeSelector
. nodeName
is a field in the Pod spec. If the nodeName
field
is not empty, the scheduler ignores the Pod and the kubelet on the named node
tries to place the Pod on that node. Using nodeName
overrules using
nodeSelector
or affinity and anti-affinity rules.
Some of the limitations of using nodeName
to select nodes are:
- If the named node does not exist, the Pod will not run, and in some cases may be automatically deleted.
- If the named node does not have the resources to accommodate the Pod, the Pod will fail and its reason will indicate why, for example OutOfmemory or OutOfcpu.
- Node names in cloud environments are not always predictable or stable.
Warning:
nodeName
is intended for use by custom schedulers or advanced use cases where
you need to bypass any configured schedulers. Bypassing the schedulers might lead to
failed Pods if the assigned Nodes get oversubscribed. You can use node affinity
or the nodeSelector
field to assign a Pod to a specific Node without bypassing the schedulers.Here is an example of a Pod spec using the nodeName
field:
apiVersion: v1
kind: Pod
metadata:
name: nginx
spec:
containers:
- name: nginx
image: nginx
nodeName: kube-01
The above Pod will only run on the node kube-01
.
Pod topology spread constraints
You can use topology spread constraints to control how Pods are spread across your cluster among failure-domains such as regions, zones, nodes, or among any other topology domains that you define. You might do this to improve performance, expected availability, or overall utilization.
Read Pod topology spread constraints to learn more about how these work.
Operators
The following are all the logical operators that you can use in the operator
field for nodeAffinity
and podAffinity
mentioned above.
Operator | Behavior |
---|---|
In |
The label value is present in the supplied set of strings |
NotIn |
The label value is not contained in the supplied set of strings |
Exists |
A label with this key exists on the object |
DoesNotExist |
No label with this key exists on the object |
The following operators can only be used with nodeAffinity
.
Operator | Behavior |
---|---|
Gt |
The field value will be parsed as an integer, and that integer is less than the integer that results from parsing the value of a label named by this selector |
Lt |
The field value will be parsed as an integer, and that integer is greater than the integer that results from parsing the value of a label named by this selector |
Note:
Gt
and Lt
operators will not work with non-integer values. If the given value
doesn't parse as an integer, the pod will fail to get scheduled. Also, Gt
and Lt
are not available for podAffinity
.What's next
- Read more about taints and tolerations.
- Read the design docs for node affinity and for inter-pod affinity/anti-affinity.
- Learn about how the topology manager takes part in node-level resource allocation decisions.
- Learn how to use nodeSelector.
- Learn how to use affinity and anti-affinity.