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, and other user-defined topology domains. This can help to achieve high availability as well as efficient resource utilization.
You can set cluster-level constraints as a default, or configure topology spread constraints for individual workloads.
Motivation
Imagine that you have a cluster of up to twenty nodes, and you want to run a workload that automatically scales how many replicas it uses. There could be as few as two Pods or as many as fifteen. When there are only two Pods, you'd prefer not to have both of those Pods run on the same node: you would run the risk that a single node failure takes your workload offline.
In addition to this basic usage, there are some advanced usage examples that enable your workloads to benefit on high availability and cluster utilization.
As you scale up and run more Pods, a different concern becomes important. Imagine that you have three nodes running five Pods each. The nodes have enough capacity to run that many replicas; however, the clients that interact with this workload are split across three different datacenters (or infrastructure zones). Now you have less concern about a single node failure, but you notice that latency is higher than you'd like, and you are paying for network costs associated with sending network traffic between the different zones.
You decide that under normal operation you'd prefer to have a similar number of replicas scheduled into each infrastructure zone, and you'd like the cluster to self-heal in the case that there is a problem.
Pod topology spread constraints offer you a declarative way to configure that.
topologySpreadConstraints
field
The Pod API includes a field, spec.topologySpreadConstraints
. The usage of this field looks like
the following:
---
apiVersion: v1
kind: Pod
metadata:
name: example-pod
spec:
# Configure a topology spread constraint
topologySpreadConstraints:
- maxSkew: <integer>
minDomains: <integer> # optional
topologyKey: <string>
whenUnsatisfiable: <string>
labelSelector: <object>
matchLabelKeys: <list> # optional; beta since v1.27
nodeAffinityPolicy: [Honor|Ignore] # optional; beta since v1.26
nodeTaintsPolicy: [Honor|Ignore] # optional; beta since v1.26
### other Pod fields go here
You can read more about this field by running kubectl explain Pod.spec.topologySpreadConstraints
or
refer to the scheduling section of the API reference for Pod.
Spread constraint definition
You can define one or multiple topologySpreadConstraints
entries to instruct the
kube-scheduler how to place each incoming Pod in relation to the existing Pods across
your cluster. Those fields are:
maxSkew describes the degree to which Pods may be unevenly distributed. You must specify this field and the number must be greater than zero. Its semantics differ according to the value of
whenUnsatisfiable
:- if you select
whenUnsatisfiable: DoNotSchedule
, thenmaxSkew
defines the maximum permitted difference between the number of matching pods in the target topology and the global minimum (the minimum number of matching pods in an eligible domain or zero if the number of eligible domains is less than MinDomains). For example, if you have 3 zones with 2, 2 and 1 matching pods respectively,MaxSkew
is set to 1 then the global minimum is 1. - if you select
whenUnsatisfiable: ScheduleAnyway
, the scheduler gives higher precedence to topologies that would help reduce the skew.
- if you select
minDomains indicates a minimum number of eligible domains. This field is optional. A domain is a particular instance of a topology. An eligible domain is a domain whose nodes match the node selector.
Note:
Before Kubernetes v1.30, theminDomains
field was only available if theMinDomainsInPodTopologySpread
feature gate was enabled (default since v1.28). In older Kubernetes clusters it might be explicitly disabled or the field might not be available.- The value of
minDomains
must be greater than 0, when specified. You can only specifyminDomains
in conjunction withwhenUnsatisfiable: DoNotSchedule
. - When the number of eligible domains with match topology keys is less than
minDomains
, Pod topology spread treats global minimum as 0, and then the calculation ofskew
is performed. The global minimum is the minimum number of matching Pods in an eligible domain, or zero if the number of eligible domains is less thanminDomains
. - When the number of eligible domains with matching topology keys equals or is greater than
minDomains
, this value has no effect on scheduling. - If you do not specify
minDomains
, the constraint behaves as ifminDomains
is 1.
- The value of
topologyKey is the key of node labels. Nodes that have a label with this key and identical values are considered to be in the same topology. We call each instance of a topology (in other words, a <key, value> pair) a domain. The scheduler will try to put a balanced number of pods into each domain. Also, we define an eligible domain as a domain whose nodes meet the requirements of nodeAffinityPolicy and nodeTaintsPolicy.
whenUnsatisfiable indicates how to deal with a Pod if it doesn't satisfy the spread constraint:
DoNotSchedule
(default) tells the scheduler not to schedule it.ScheduleAnyway
tells the scheduler to still schedule it while prioritizing nodes that minimize the skew.
labelSelector is used to find matching Pods. Pods that match this label selector are counted to determine the number of Pods in their corresponding topology domain. See Label Selectors for more details.
matchLabelKeys is a list of pod label keys to select the pods over which spreading will be calculated. The keys are used to lookup values from the pod labels, those key-value labels are ANDed with
labelSelector
to select the group of existing pods over which spreading will be calculated for the incoming pod. The same key is forbidden to exist in bothmatchLabelKeys
andlabelSelector
.matchLabelKeys
cannot be set whenlabelSelector
isn't set. Keys that don't exist in the pod labels will be ignored. A null or empty list means only match against thelabelSelector
.With
matchLabelKeys
, you don't need to update thepod.spec
between different revisions. The controller/operator just needs to set different values to the same label key for different revisions. The scheduler will assume the values automatically based onmatchLabelKeys
. For example, if you are configuring a Deployment, you can use the label keyed with pod-template-hash, which is added automatically by the Deployment controller, to distinguish between different revisions in a single Deployment.topologySpreadConstraints: - maxSkew: 1 topologyKey: kubernetes.io/hostname whenUnsatisfiable: DoNotSchedule labelSelector: matchLabels: app: foo matchLabelKeys: - pod-template-hash
Note:
ThematchLabelKeys
field is a beta-level field and enabled by default in 1.27. You can disable it by disabling theMatchLabelKeysInPodTopologySpread
feature gate.nodeAffinityPolicy indicates how we will treat Pod's nodeAffinity/nodeSelector when calculating pod topology spread skew. Options are:
- Honor: only nodes matching nodeAffinity/nodeSelector are included in the calculations.
- Ignore: nodeAffinity/nodeSelector are ignored. All nodes are included in the calculations.
If this value is null, the behavior is equivalent to the Honor policy.
Note:
ThenodeAffinityPolicy
is a beta-level field and enabled by default in 1.26. You can disable it by disabling theNodeInclusionPolicyInPodTopologySpread
feature gate.nodeTaintsPolicy indicates how we will treat node taints when calculating pod topology spread skew. Options are:
- Honor: nodes without taints, along with tainted nodes for which the incoming pod has a toleration, are included.
- Ignore: node taints are ignored. All nodes are included.
If this value is null, the behavior is equivalent to the Ignore policy.
Note:
ThenodeTaintsPolicy
is a beta-level field and enabled by default in 1.26. You can disable it by disabling theNodeInclusionPolicyInPodTopologySpread
feature gate.
When a Pod defines more than one topologySpreadConstraint
, those constraints are
combined using a logical AND operation: the kube-scheduler looks for a node for the incoming Pod
that satisfies all the configured constraints.
Node labels
Topology spread constraints rely on node labels to identify the topology domain(s) that each node is in. For example, a node might have labels:
region: us-east-1
zone: us-east-1a
Note:
For brevity, this example doesn't use the
well-known label keys
topology.kubernetes.io/zone
and topology.kubernetes.io/region
. However,
those registered label keys are nonetheless recommended rather than the private
(unqualified) label keys region
and zone
that are used here.
You can't make a reliable assumption about the meaning of a private label key between different contexts.
Suppose you have a 4-node cluster with the following labels:
NAME STATUS ROLES AGE VERSION LABELS
node1 Ready <none> 4m26s v1.16.0 node=node1,zone=zoneA
node2 Ready <none> 3m58s v1.16.0 node=node2,zone=zoneA
node3 Ready <none> 3m17s v1.16.0 node=node3,zone=zoneB
node4 Ready <none> 2m43s v1.16.0 node=node4,zone=zoneB
Then the cluster is logically viewed as below:
Consistency
You should set the same Pod topology spread constraints on all pods in a group.
Usually, if you are using a workload controller such as a Deployment, the pod template takes care of this for you. If you mix different spread constraints then Kubernetes follows the API definition of the field; however, the behavior is more likely to become confusing and troubleshooting is less straightforward.
You need a mechanism to ensure that all the nodes in a topology domain (such as a
cloud provider region) are labeled consistently.
To avoid you needing to manually label nodes, most clusters automatically
populate well-known labels such as kubernetes.io/hostname
. Check whether
your cluster supports this.
Topology spread constraint examples
Example: one topology spread constraint
Suppose you have a 4-node cluster where 3 Pods labeled foo: bar
are located in
node1, node2 and node3 respectively:
If you want an incoming Pod to be evenly spread with existing Pods across zones, you can use a manifest similar to:
kind: Pod
apiVersion: v1
metadata:
name: mypod
labels:
foo: bar
spec:
topologySpreadConstraints:
- maxSkew: 1
topologyKey: zone
whenUnsatisfiable: DoNotSchedule
labelSelector:
matchLabels:
foo: bar
containers:
- name: pause
image: registry.k8s.io/pause:3.1
From that manifest, topologyKey: zone
implies the even distribution will only be applied
to nodes that are labeled zone: <any value>
(nodes that don't have a zone
label
are skipped). The field whenUnsatisfiable: DoNotSchedule
tells the scheduler to let the
incoming Pod stay pending if the scheduler can't find a way to satisfy the constraint.
If the scheduler placed this incoming Pod into zone A
, the distribution of Pods would
become [3, 1]
. That means the actual skew is then 2 (calculated as 3 - 1
), which
violates maxSkew: 1
. To satisfy the constraints and context for this example, the
incoming Pod can only be placed onto a node in zone B
:
OR
You can tweak the Pod spec to meet various kinds of requirements:
- Change
maxSkew
to a bigger value - such as2
- so that the incoming Pod can be placed into zoneA
as well. - Change
topologyKey
tonode
so as to distribute the Pods evenly across nodes instead of zones. In the above example, ifmaxSkew
remains1
, the incoming Pod can only be placed onto the nodenode4
. - Change
whenUnsatisfiable: DoNotSchedule
towhenUnsatisfiable: ScheduleAnyway
to ensure the incoming Pod to be always schedulable (suppose other scheduling APIs are satisfied). However, it's preferred to be placed into the topology domain which has fewer matching Pods. (Be aware that this preference is jointly normalized with other internal scheduling priorities such as resource usage ratio).
Example: multiple topology spread constraints
This builds upon the previous example. Suppose you have a 4-node cluster where 3
existing Pods labeled foo: bar
are located on node1, node2 and node3 respectively:
You can combine two topology spread constraints to control the spread of Pods both by node and by zone:
kind: Pod
apiVersion: v1
metadata:
name: mypod
labels:
foo: bar
spec:
topologySpreadConstraints:
- maxSkew: 1
topologyKey: zone
whenUnsatisfiable: DoNotSchedule
labelSelector:
matchLabels:
foo: bar
- maxSkew: 1
topologyKey: node
whenUnsatisfiable: DoNotSchedule
labelSelector:
matchLabels:
foo: bar
containers:
- name: pause
image: registry.k8s.io/pause:3.1
In this case, to match the first constraint, the incoming Pod can only be placed onto
nodes in zone B
; while in terms of the second constraint, the incoming Pod can only be
scheduled to the node node4
. The scheduler only considers options that satisfy all
defined constraints, so the only valid placement is onto node node4
.
Example: conflicting topology spread constraints
Multiple constraints can lead to conflicts. Suppose you have a 3-node cluster across 2 zones:
If you were to apply
two-constraints.yaml
(the manifest from the previous example)
to this cluster, you would see that the Pod mypod
stays in the Pending
state.
This happens because: to satisfy the first constraint, the Pod mypod
can only
be placed into zone B
; while in terms of the second constraint, the Pod mypod
can only schedule to node node2
. The intersection of the two constraints returns
an empty set, and the scheduler cannot place the Pod.
To overcome this situation, you can either increase the value of maxSkew
or modify
one of the constraints to use whenUnsatisfiable: ScheduleAnyway
. Depending on
circumstances, you might also decide to delete an existing Pod manually - for example,
if you are troubleshooting why a bug-fix rollout is not making progress.
Interaction with node affinity and node selectors
The scheduler will skip the non-matching nodes from the skew calculations if the
incoming Pod has spec.nodeSelector
or spec.affinity.nodeAffinity
defined.
Example: topology spread constraints with node affinity
Suppose you have a 5-node cluster ranging across zones A to C:
and you know that zone C
must be excluded. In this case, you can compose a manifest
as below, so that Pod mypod
will be placed into zone B
instead of zone C
.
Similarly, Kubernetes also respects spec.nodeSelector
.
kind: Pod
apiVersion: v1
metadata:
name: mypod
labels:
foo: bar
spec:
topologySpreadConstraints:
- maxSkew: 1
topologyKey: zone
whenUnsatisfiable: DoNotSchedule
labelSelector:
matchLabels:
foo: bar
affinity:
nodeAffinity:
requiredDuringSchedulingIgnoredDuringExecution:
nodeSelectorTerms:
- matchExpressions:
- key: zone
operator: NotIn
values:
- zoneC
containers:
- name: pause
image: registry.k8s.io/pause:3.1
Implicit conventions
There are some implicit conventions worth noting here:
Only the Pods holding the same namespace as the incoming Pod can be matching candidates.
The scheduler bypasses any nodes that don't have any
topologySpreadConstraints[*].topologyKey
present. This implies that:- any Pods located on those bypassed nodes do not impact
maxSkew
calculation - in the above example, suppose the nodenode1
does not have a label "zone", then the 2 Pods will be disregarded, hence the incoming Pod will be scheduled into zoneA
. - the incoming Pod has no chances to be scheduled onto this kind of nodes -
in the above example, suppose a node
node5
has the mistyped labelzone-typo: zoneC
(and nozone
label set). After nodenode5
joins the cluster, it will be bypassed and Pods for this workload aren't scheduled there.
- any Pods located on those bypassed nodes do not impact
Be aware of what will happen if the incoming Pod's
topologySpreadConstraints[*].labelSelector
doesn't match its own labels. In the above example, if you remove the incoming Pod's labels, it can still be placed onto nodes in zoneB
, since the constraints are still satisfied. However, after that placement, the degree of imbalance of the cluster remains unchanged - it's still zoneA
having 2 Pods labeled asfoo: bar
, and zoneB
having 1 Pod labeled asfoo: bar
. If this is not what you expect, update the workload'stopologySpreadConstraints[*].labelSelector
to match the labels in the pod template.
Cluster-level default constraints
It is possible to set default topology spread constraints for a cluster. Default topology spread constraints are applied to a Pod if, and only if:
- It doesn't define any constraints in its
.spec.topologySpreadConstraints
. - It belongs to a Service, ReplicaSet, StatefulSet or ReplicationController.
Default constraints can be set as part of the PodTopologySpread
plugin
arguments in a scheduling profile.
The constraints are specified with the same API above, except that
labelSelector
must be empty. The selectors are calculated from the Services,
ReplicaSets, StatefulSets or ReplicationControllers that the Pod belongs to.
An example configuration might look like follows:
apiVersion: kubescheduler.config.k8s.io/v1beta3
kind: KubeSchedulerConfiguration
profiles:
- schedulerName: default-scheduler
pluginConfig:
- name: PodTopologySpread
args:
defaultConstraints:
- maxSkew: 1
topologyKey: topology.kubernetes.io/zone
whenUnsatisfiable: ScheduleAnyway
defaultingType: List
Built-in default constraints
Kubernetes v1.24 [stable]
If you don't configure any cluster-level default constraints for pod topology spreading, then kube-scheduler acts as if you specified the following default topology constraints:
defaultConstraints:
- maxSkew: 3
topologyKey: "kubernetes.io/hostname"
whenUnsatisfiable: ScheduleAnyway
- maxSkew: 5
topologyKey: "topology.kubernetes.io/zone"
whenUnsatisfiable: ScheduleAnyway
Also, the legacy SelectorSpread
plugin, which provides an equivalent behavior,
is disabled by default.
Note:
The PodTopologySpread
plugin does not score the nodes that don't have
the topology keys specified in the spreading constraints. This might result
in a different default behavior compared to the legacy SelectorSpread
plugin when
using the default topology constraints.
If your nodes are not expected to have both kubernetes.io/hostname
and
topology.kubernetes.io/zone
labels set, define your own constraints
instead of using the Kubernetes defaults.
If you don't want to use the default Pod spreading constraints for your cluster,
you can disable those defaults by setting defaultingType
to List
and leaving
empty defaultConstraints
in the PodTopologySpread
plugin configuration:
apiVersion: kubescheduler.config.k8s.io/v1beta3
kind: KubeSchedulerConfiguration
profiles:
- schedulerName: default-scheduler
pluginConfig:
- name: PodTopologySpread
args:
defaultConstraints: []
defaultingType: List
Comparison with podAffinity and podAntiAffinity
In Kubernetes, inter-Pod affinity and anti-affinity control how Pods are scheduled in relation to one another - either more packed or more scattered.
podAffinity
- attracts Pods; you can try to pack any number of Pods into qualifying topology domain(s).
podAntiAffinity
- repels Pods. If you set this to
requiredDuringSchedulingIgnoredDuringExecution
mode then only a single Pod can be scheduled into a single topology domain; if you choosepreferredDuringSchedulingIgnoredDuringExecution
then you lose the ability to enforce the constraint.
For finer control, you can specify topology spread constraints to distribute Pods across different topology domains - to achieve either high availability or cost-saving. This can also help on rolling update workloads and scaling out replicas smoothly.
For more context, see the Motivation section of the enhancement proposal about Pod topology spread constraints.
Known limitations
There's no guarantee that the constraints remain satisfied when Pods are removed. For example, scaling down a Deployment may result in imbalanced Pods distribution.
You can use a tool such as the Descheduler to rebalance the Pods distribution.
Pods matched on tainted nodes are respected. See Issue 80921.
The scheduler doesn't have prior knowledge of all the zones or other topology domains that a cluster has. They are determined from the existing nodes in the cluster. This could lead to a problem in autoscaled clusters, when a node pool (or node group) is scaled to zero nodes, and you're expecting the cluster to scale up, because, in this case, those topology domains won't be considered until there is at least one node in them.
You can work around this by using a cluster autoscaling tool that is aware of Pod topology spread constraints and is also aware of the overall set of topology domains.
What's next
- The blog article Introducing PodTopologySpread
explains
maxSkew
in some detail, as well as covering some advanced usage examples. - Read the scheduling section of the API reference for Pod.