Node-pressure Eviction
Node-pressure eviction is the process by which the kubelet proactively terminates pods to reclaim resources on nodes.
Kubernetes v1.31 [beta]
(enabled by default: true)
Note:
The split image filesystem feature, which enables support for thecontainerfs
filesystem, adds several new eviction signals, thresholds and metrics. To use
containerfs
, the Kubernetes release v1.31 requires the
KubeletSeparateDiskGC
feature gate
to be enabled. Currently, only CRI-O (v1.29 or higher) offers the containerfs
filesystem support.The kubelet monitors resources like memory, disk space, and filesystem inodes on your cluster's nodes. When one or more of these resources reach specific consumption levels, the kubelet can proactively fail one or more pods on the node to reclaim resources and prevent starvation.
During a node-pressure eviction, the kubelet sets the phase for the
selected pods to Failed
, and terminates the Pod.
Node-pressure eviction is not the same as API-initiated eviction.
The kubelet does not respect your configured PodDisruptionBudget
or the pod's
terminationGracePeriodSeconds
. If you use soft eviction thresholds,
the kubelet respects your configured eviction-max-pod-grace-period
. If you use
hard eviction thresholds, the kubelet uses a 0s
grace period (immediate shutdown) for termination.
Self healing behavior
The kubelet attempts to reclaim node-level resources before it terminates end-user pods. For example, it removes unused container images when disk resources are starved.
If the pods are managed by a workload
management object (such as StatefulSet
or Deployment) that
replaces failed pods, the control plane (kube-controller-manager
) creates new
pods in place of the evicted pods.
Self healing for static pods
If you are running a static pod on a node that is under resource pressure, the kubelet may evict that static Pod. The kubelet then tries to create a replacement, because static Pods always represent an intent to run a Pod on that node.
The kubelet takes the priority of the static pod into account when creating a replacement. If the static pod manifest specifies a low priority, and there are higher-priority Pods defined within the cluster's control plane, and the node is under resource pressure, the kubelet may not be able to make room for that static pod. The kubelet continues to attempt to run all static pods even when there is resource pressure on a node.
Eviction signals and thresholds
The kubelet uses various parameters to make eviction decisions, like the following:
- Eviction signals
- Eviction thresholds
- Monitoring intervals
Eviction signals
Eviction signals are the current state of a particular resource at a specific point in time. The kubelet uses eviction signals to make eviction decisions by comparing the signals to eviction thresholds, which are the minimum amount of the resource that should be available on the node.
The kubelet uses the following eviction signals:
Eviction Signal | Description | Linux Only |
---|---|---|
memory.available |
memory.available := node.status.capacity[memory] - node.stats.memory.workingSet |
|
nodefs.available |
nodefs.available := node.stats.fs.available |
|
nodefs.inodesFree |
nodefs.inodesFree := node.stats.fs.inodesFree |
• |
imagefs.available |
imagefs.available := node.stats.runtime.imagefs.available |
|
imagefs.inodesFree |
imagefs.inodesFree := node.stats.runtime.imagefs.inodesFree |
• |
containerfs.available |
containerfs.available := node.stats.runtime.containerfs.available |
|
containerfs.inodesFree |
containerfs.inodesFree := node.stats.runtime.containerfs.inodesFree |
• |
pid.available |
pid.available := node.stats.rlimit.maxpid - node.stats.rlimit.curproc |
• |
In this table, the Description column shows how kubelet gets the value of the signal. Each signal supports either a percentage or a literal value. The kubelet calculates the percentage value relative to the total capacity associated with the signal.
Memory signals
On Linux nodes, the value for memory.available
is derived from the cgroupfs instead of tools
like free -m
. This is important because free -m
does not work in a
container, and if users use the node allocatable
feature, out of resource decisions
are made local to the end user Pod part of the cgroup hierarchy as well as the
root node. This script or
cgroupv2 script
reproduces the same set of steps that the kubelet performs to calculate
memory.available
. The kubelet excludes inactive_file (the number of bytes of
file-backed memory on the inactive LRU list) from its calculation, as it assumes that
memory is reclaimable under pressure.
On Windows nodes, the value for memory.available
is derived from the node's global
memory commit levels (queried through the GetPerformanceInfo()
system call) by subtracting the node's global CommitTotal
from the node's CommitLimit
. Please note that CommitLimit
can change if the node's page-file size changes!
Filesystem signals
The kubelet recognizes three specific filesystem identifiers that can be used with
eviction signals (<identifier>.inodesFree
or <identifier>.available
):
-
nodefs
: The node's main filesystem, used for local disk volumes, emptyDir volumes not backed by memory, log storage, ephemeral storage, and more. For example,nodefs
contains/var/lib/kubelet
. -
imagefs
: An optional filesystem that container runtimes can use to store container images (which are the read-only layers) and container writable layers. -
containerfs
: An optional filesystem that container runtime can use to store the writeable layers. Similar to the main filesystem (seenodefs
), it's used to store local disk volumes, emptyDir volumes not backed by memory, log storage, and ephemeral storage, except for the container images. Whencontainerfs
is used, theimagefs
filesystem can be split to only store images (read-only layers) and nothing else.
As such, kubelet generally allows three options for container filesystems:
-
Everything is on the single
nodefs
, also referred to as "rootfs" or simply "root", and there is no dedicated image filesystem. -
Container storage (see
nodefs
) is on a dedicated disk, andimagefs
(writable and read-only layers) is separate from the root filesystem. This is often referred to as "split disk" (or "separate disk") filesystem. -
Container filesystem
containerfs
(same asnodefs
plus writable layers) is on root and the container images (read-only layers) are stored on separateimagefs
. This is often referred to as "split image" filesystem.
The kubelet will attempt to auto-discover these filesystems with their current configuration directly from the underlying container runtime and will ignore other local node filesystems.
The kubelet does not support other container filesystems or storage configurations, and it does not currently support multiple filesystems for images and containers.
Deprecated kubelet garbage collection features
Some kubelet garbage collection features are deprecated in favor of eviction:
Existing Flag | Rationale |
---|---|
--maximum-dead-containers |
deprecated once old logs are stored outside of container's context |
--maximum-dead-containers-per-container |
deprecated once old logs are stored outside of container's context |
--minimum-container-ttl-duration |
deprecated once old logs are stored outside of container's context |
Eviction thresholds
You can specify custom eviction thresholds for the kubelet to use when it makes eviction decisions. You can configure soft and hard eviction thresholds.
Eviction thresholds have the form [eviction-signal][operator][quantity]
, where:
eviction-signal
is the eviction signal to use.operator
is the relational operator you want, such as<
(less than).quantity
is the eviction threshold amount, such as1Gi
. The value ofquantity
must match the quantity representation used by Kubernetes. You can use either literal values or percentages (%
).
For example, if a node has 10GiB of total memory and you want trigger eviction if
the available memory falls below 1GiB, you can define the eviction threshold as
either memory.available<10%
or memory.available<1Gi
(you cannot use both).
Soft eviction thresholds
A soft eviction threshold pairs an eviction threshold with a required administrator-specified grace period. The kubelet does not evict pods until the grace period is exceeded. The kubelet returns an error on startup if you do not specify a grace period.
You can specify both a soft eviction threshold grace period and a maximum allowed pod termination grace period for kubelet to use during evictions. If you specify a maximum allowed grace period and the soft eviction threshold is met, the kubelet uses the lesser of the two grace periods. If you do not specify a maximum allowed grace period, the kubelet kills evicted pods immediately without graceful termination.
You can use the following flags to configure soft eviction thresholds:
eviction-soft
: A set of eviction thresholds likememory.available<1.5Gi
that can trigger pod eviction if held over the specified grace period.eviction-soft-grace-period
: A set of eviction grace periods likememory.available=1m30s
that define how long a soft eviction threshold must hold before triggering a Pod eviction.eviction-max-pod-grace-period
: The maximum allowed grace period (in seconds) to use when terminating pods in response to a soft eviction threshold being met.
Hard eviction thresholds
A hard eviction threshold has no grace period. When a hard eviction threshold is met, the kubelet kills pods immediately without graceful termination to reclaim the starved resource.
You can use the eviction-hard
flag to configure a set of hard eviction
thresholds like memory.available<1Gi
.
The kubelet has the following default hard eviction thresholds:
memory.available<100Mi
(Linux nodes)memory.available<500Mi
(Windows nodes)nodefs.available<10%
imagefs.available<15%
nodefs.inodesFree<5%
(Linux nodes)imagefs.inodesFree<5%
(Linux nodes)
These default values of hard eviction thresholds will only be set if none of the parameters is changed. If you change the value of any parameter, then the values of other parameters will not be inherited as the default values and will be set to zero. In order to provide custom values, you should provide all the thresholds respectively.
The containerfs.available
and containerfs.inodesFree
(Linux nodes) default
eviction thresholds will be set as follows:
-
If a single filesystem is used for everything, then
containerfs
thresholds are set the same asnodefs
. -
If separate filesystems are configured for both images and containers, then
containerfs
thresholds are set the same asimagefs
.
Setting custom overrides for thresholds related to containersfs
is currently
not supported, and a warning will be issued if an attempt to do so is made; any
provided custom values will, as such, be ignored.
Eviction monitoring interval
The kubelet evaluates eviction thresholds based on its configured housekeeping-interval
,
which defaults to 10s
.
Node conditions
The kubelet reports node conditions to reflect that the node is under pressure because hard or soft eviction threshold is met, independent of configured grace periods.
The kubelet maps eviction signals to node conditions as follows:
Node Condition | Eviction Signal | Description |
---|---|---|
MemoryPressure |
memory.available |
Available memory on the node has satisfied an eviction threshold |
DiskPressure |
nodefs.available , nodefs.inodesFree , imagefs.available , imagefs.inodesFree , containerfs.available , or containerfs.inodesFree |
Available disk space and inodes on either the node's root filesystem, image filesystem, or container filesystem has satisfied an eviction threshold |
PIDPressure |
pid.available |
Available processes identifiers on the (Linux) node has fallen below an eviction threshold |
The control plane also maps these node conditions to taints.
The kubelet updates the node conditions based on the configured
--node-status-update-frequency
, which defaults to 10s
.
Node condition oscillation
In some cases, nodes oscillate above and below soft eviction thresholds without
holding for the defined grace periods. This causes the reported node condition
to constantly switch between true
and false
, leading to bad eviction decisions.
To protect against oscillation, you can use the eviction-pressure-transition-period
flag, which controls how long the kubelet must wait before transitioning a node
condition to a different state. The transition period has a default value of 5m
.
Reclaiming node level resources
The kubelet tries to reclaim node-level resources before it evicts end-user pods.
When a DiskPressure
node condition is reported, the kubelet reclaims node-level
resources based on the filesystems on the node.
Without imagefs
or containerfs
If the node only has a nodefs
filesystem that meets eviction thresholds,
the kubelet frees up disk space in the following order:
- Garbage collect dead pods and containers.
- Delete unused images.
With imagefs
If the node has a dedicated imagefs
filesystem for container runtimes to use,
the kubelet does the following:
-
If the
nodefs
filesystem meets the eviction thresholds, the kubelet garbage collects dead pods and containers. -
If the
imagefs
filesystem meets the eviction thresholds, the kubelet deletes all unused images.
With imagefs
and containerfs
If the node has a dedicated containerfs
alongside the imagefs
filesystem
configured for the container runtimes to use, then kubelet will attempt to
reclaim resources as follows:
-
If the
containerfs
filesystem meets the eviction thresholds, the kubelet garbage collects dead pods and containers. -
If the
imagefs
filesystem meets the eviction thresholds, the kubelet deletes all unused images.
Pod selection for kubelet eviction
If the kubelet's attempts to reclaim node-level resources don't bring the eviction signal below the threshold, the kubelet begins to evict end-user pods.
The kubelet uses the following parameters to determine the pod eviction order:
- Whether the pod's resource usage exceeds requests
- Pod Priority
- The pod's resource usage relative to requests
As a result, kubelet ranks and evicts pods in the following order:
-
BestEffort
orBurstable
pods where the usage exceeds requests. These pods are evicted based on their Priority and then by how much their usage level exceeds the request. -
Guaranteed
pods andBurstable
pods where the usage is less than requests are evicted last, based on their Priority.
Note:
The kubelet does not use the pod's QoS class to determine the eviction order. You can use the QoS class to estimate the most likely pod eviction order when reclaiming resources like memory. QoS classification does not apply to EphemeralStorage requests, so the above scenario will not apply if the node is, for example, underDiskPressure
.Guaranteed
pods are guaranteed only when requests and limits are specified for
all the containers and they are equal. These pods will never be evicted because
of another pod's resource consumption. If a system daemon (such as kubelet
and journald
) is consuming more resources than were reserved via
system-reserved
or kube-reserved
allocations, and the node only has
Guaranteed
or Burstable
pods using less resources than requests left on it,
then the kubelet must choose to evict one of these pods to preserve node stability
and to limit the impact of resource starvation on other pods. In this case, it
will choose to evict pods of lowest Priority first.
If you are running a static pod
and want to avoid having it evicted under resource pressure, set the
priority
field for that Pod directly. Static pods do not support the
priorityClassName
field.
When the kubelet evicts pods in response to inode or process ID starvation, it uses the Pods' relative priority to determine the eviction order, because inodes and PIDs have no requests.
The kubelet sorts pods differently based on whether the node has a dedicated
imagefs
or containerfs
filesystem:
Without imagefs
or containerfs
(nodefs
and imagefs
use the same filesystem)
- If
nodefs
triggers evictions, the kubelet sorts pods based on their total disk usage (local volumes + logs and a writable layer of all containers
).
With imagefs
(nodefs
and imagefs
filesystems are separate)
-
If
nodefs
triggers evictions, the kubelet sorts pods based onnodefs
usage (local volumes + logs of all containers
). -
If
imagefs
triggers evictions, the kubelet sorts pods based on the writable layer usage of all containers.
With imagesfs
and containerfs
(imagefs
and containerfs
have been split)
-
If
containerfs
triggers evictions, the kubelet sorts pods based oncontainerfs
usage (local volumes + logs and a writable layer of all containers
). -
If
imagefs
triggers evictions, the kubelet sorts pods based on thestorage of images
rank, which represents the disk usage of a given image.
Minimum eviction reclaim
Note:
As of Kubernetes v1.31, you cannot set a custom value for thecontainerfs.available
metric. The configuration for this specific
metric will be set automatically to reflect values set for either the nodefs
or imagefs
, depending on the configuration.In some cases, pod eviction only reclaims a small amount of the starved resource. This can lead to the kubelet repeatedly hitting the configured eviction thresholds and triggering multiple evictions.
You can use the --eviction-minimum-reclaim
flag or a kubelet config file
to configure a minimum reclaim amount for each resource. When the kubelet notices
that a resource is starved, it continues to reclaim that resource until it
reclaims the quantity you specify.
For example, the following configuration sets minimum reclaim amounts:
apiVersion: kubelet.config.k8s.io/v1beta1
kind: KubeletConfiguration
evictionHard:
memory.available: "500Mi"
nodefs.available: "1Gi"
imagefs.available: "100Gi"
evictionMinimumReclaim:
memory.available: "0Mi"
nodefs.available: "500Mi"
imagefs.available: "2Gi"
In this example, if the nodefs.available
signal meets the eviction threshold,
the kubelet reclaims the resource until the signal reaches the threshold of 1GiB,
and then continues to reclaim the minimum amount of 500MiB, until the available
nodefs storage value reaches 1.5GiB.
Similarly, the kubelet tries to reclaim the imagefs
resource until the imagefs.available
value reaches 102Gi
, representing 102 GiB of available container image storage. If the amount
of storage that the kubelet could reclaim is less than 2GiB, the kubelet doesn't reclaim anything.
The default eviction-minimum-reclaim
is 0
for all resources.
Node out of memory behavior
If the node experiences an out of memory (OOM) event prior to the kubelet being able to reclaim memory, the node depends on the oom_killer to respond.
The kubelet sets an oom_score_adj
value for each container based on the QoS for the pod.
Quality of Service | oom_score_adj |
---|---|
Guaranteed |
-997 |
BestEffort |
1000 |
Burstable |
min(max(2, 1000 - (1000 × memoryRequestBytes) / machineMemoryCapacityBytes), 999) |
Note:
The kubelet also sets anoom_score_adj
value of -997
for any containers in Pods that have
system-node-critical
Priority.If the kubelet can't reclaim memory before a node experiences OOM, the
oom_killer
calculates an oom_score
based on the percentage of memory it's
using on the node, and then adds the oom_score_adj
to get an effective oom_score
for each container. It then kills the container with the highest score.
This means that containers in low QoS pods that consume a large amount of memory relative to their scheduling requests are killed first.
Unlike pod eviction, if a container is OOM killed, the kubelet can restart it
based on its restartPolicy
.
Good practices
The following sections describe good practice for eviction configuration.
Schedulable resources and eviction policies
When you configure the kubelet with an eviction policy, you should make sure that the scheduler will not schedule pods if they will trigger eviction because they immediately induce memory pressure.
Consider the following scenario:
- Node memory capacity: 10GiB
- Operator wants to reserve 10% of memory capacity for system daemons (kernel,
kubelet
, etc.) - Operator wants to evict Pods at 95% memory utilization to reduce incidence of system OOM.
For this to work, the kubelet is launched as follows:
--eviction-hard=memory.available<500Mi
--system-reserved=memory=1.5Gi
In this configuration, the --system-reserved
flag reserves 1.5GiB of memory
for the system, which is 10% of the total memory + the eviction threshold amount
.
The node can reach the eviction threshold if a pod is using more than its request,
or if the system is using more than 1GiB of memory, which makes the memory.available
signal fall below 500MiB and triggers the threshold.
DaemonSets and node-pressure eviction
Pod priority is a major factor in making eviction decisions. If you do not want
the kubelet to evict pods that belong to a DaemonSet, give those pods a high
enough priority by specifying a suitable priorityClassName
in the pod spec.
You can also use a lower priority, or the default, to only allow pods from that
DaemonSet to run when there are enough resources.
Known issues
The following sections describe known issues related to out of resource handling.
kubelet may not observe memory pressure right away
By default, the kubelet polls cAdvisor to collect memory usage stats at a
regular interval. If memory usage increases within that window rapidly, the
kubelet may not observe MemoryPressure
fast enough, and the OOM killer
will still be invoked.
You can use the --kernel-memcg-notification
flag to enable the memcg
notification API on the kubelet to get notified immediately when a threshold
is crossed.
If you are not trying to achieve extreme utilization, but a sensible measure of
overcommit, a viable workaround for this issue is to use the --kube-reserved
and --system-reserved
flags to allocate memory for the system.
active_file memory is not considered as available memory
On Linux, the kernel tracks the number of bytes of file-backed memory on active
least recently used (LRU) list as the active_file
statistic. The kubelet treats active_file
memory
areas as not reclaimable. For workloads that make intensive use of block-backed
local storage, including ephemeral local storage, kernel-level caches of file
and block data means that many recently accessed cache pages are likely to be
counted as active_file
. If enough of these kernel block buffers are on the
active LRU list, the kubelet is liable to observe this as high resource use and
taint the node as experiencing memory pressure - triggering pod eviction.
For more details, see https://github.com/kubernetes/kubernetes/issues/43916
You can work around that behavior by setting the memory limit and memory request the same for containers likely to perform intensive I/O activity. You will need to estimate or measure an optimal memory limit value for that container.
What's next
- Learn about API-initiated Eviction
- Learn about Pod Priority and Preemption
- Learn about PodDisruptionBudgets
- Learn about Quality of Service (QoS)
- Check out the Eviction API