How to get started, and achieve tasks, using Kubernetes

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Configuring Out Of Resource Handling

The kubelet needs to preserve node stability when available compute resources are low.

This is especially important when dealing with incompressible resources such as memory or disk.

If either resource is exhausted, the node would become unstable.

Eviction Policy

The kubelet can pro-actively monitor for and prevent against total starvation of a compute resource. In cases where it could appear to occur, the kubelet can pro-actively fail one or more pods in order to reclaim the starved resource. When the kubelet fails a pod, it terminates all containers in the pod, and the PodPhase is transitioned to Failed.

Eviction Signals

The kubelet can support the ability to trigger eviction decisions on the signals described in the table below. The value of each signal is described in the description column based on the kubelet summary API.

Eviction Signal Description
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

Each of the above signals support either a literal or percentage based value. The percentage based value is calculated relative to the total capacity associated with each signal.

kubelet supports only two filesystem partitions.

  1. The nodefs filesystem that kubelet uses for volumes, daemon logs, etc.
  2. The imagefs filesystem that container runtimes uses for storing images and container writable layers.

imagefs is optional. kubelet auto-discovers these filesystems using cAdvisor. kubelet does not care about any other filesystems. Any other types of configurations are not currently supported by the kubelet. For example, it is not OK to store volumes and logs in a dedicated filesystem.

In future releases, the kubelet will deprecate the existing garbage collection support in favor of eviction in response to disk pressure.

Eviction Thresholds

The kubelet supports the ability to specify eviction thresholds that trigger the kubelet to reclaim resources.

Each threshold is of the following form:


For example, if a node has 10Gi of memory, and the desire is to induce eviction if available memory falls below 1Gi, an eviction threshold can be specified as either of the following (but not both).

Soft Eviction Thresholds

A soft eviction threshold pairs an eviction threshold with a required administrator specified grace period. No action is taken by the kubelet to reclaim resources associated with the eviction signal until that grace period has been exceeded. If no grace period is provided, the kubelet will error on startup.

In addition, if a soft eviction threshold has been met, an operator can specify a maximum allowed pod termination grace period to use when evicting pods from the node. If specified, the kubelet will use the lesser value among the pod.Spec.TerminationGracePeriodSeconds and the max allowed grace period. If not specified, the kubelet will kill pods immediately with no graceful termination.

To configure soft eviction thresholds, the following flags are supported:

Hard Eviction Thresholds

A hard eviction threshold has no grace period, and if observed, the kubelet will take immediate action to reclaim the associated starved resource. If a hard eviction threshold is met, the kubelet will kill the pod immediately with no graceful termination.

To configure hard eviction thresholds, the following flag is supported:

The kubelet has the following default hard eviction thresholds:

Eviction Monitoring Interval

The kubelet evaluates eviction thresholds per its configured housekeeping interval.

Node Conditions

The kubelet will map one or more eviction signals to a corresponding node condition.

If a hard eviction threshold has been met, or a soft eviction threshold has been met independent of its associated grace period, the kubelet will report a condition that reflects the node is under pressure.

The following node conditions are defined that correspond to the specified eviction signal.

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, or imagefs.inodesFree Available disk space and inodes on either the node’s root filesytem or image filesystem has satisfied an eviction threshold

The kubelet will continue to report node status updates at the frequency specified by --node-status-update-frequency which defaults to 10s.

Oscillation of node conditions

If a node is oscillating above and below a soft eviction threshold, but not exceeding its associated grace period, it would cause the corresponding node condition to constantly oscillate between true and false, and could cause poor scheduling decisions as a consequence.

To protect against this oscillation, the following flag is defined to control how long the kubelet must wait before transitioning out of a pressure condition.

The kubelet would ensure that it has not observed an eviction threshold being met for the specified pressure condition for the period specified before toggling the condition back to false.

Reclaiming node level resources

If an eviction threshold has been met and the grace period has passed, the kubelet will initiate the process of reclaiming the pressured resource until it has observed the signal has gone below its defined threshold.

The kubelet attempts to reclaim node level resources prior to evicting end-user pods. If disk pressure is observed, the kubelet reclaims node level resources differently if the machine has a dedicated imagefs configured for the container runtime.

With Imagefs

If nodefs filesystem has met eviction thresholds, kubelet will free up disk space in the following order:

  1. Delete dead pods/containers

If imagefs filesystem has met eviction thresholds, kubelet will free up disk space in the following order:

  1. Delete all unused images

Without Imagefs

If nodefs filesystem has met eviction thresholds, kubelet will free up disk space in the following order:

  1. Delete dead pods/containers
  2. Delete all unused images

Evicting end-user pods

If the kubelet is unable to reclaim sufficient resource on the node, it will begin evicting pods.

The kubelet ranks pods for eviction as follows:

As a result, pod eviction occurs in the following order:

A Guaranteed pod is guaranteed to never be evicted because of another pod’s resource consumption. If a system daemon (i.e. kubelet, docker, journald, etc.) is consuming more resources than were reserved via system-reserved or kube-reserved allocations, and the node only has Guaranteed pod(s) remaining, then the node must choose to evict a Guaranteed pod in order to preserve node stability, and to limit the impact of the unexpected consumption to other Guaranteed pod(s).

Local disk is a BestEffort resource. If necessary, kubelet will evict pods one at a time to reclaim disk when DiskPressure is encountered. The kubelet will rank pods by quality of service. If the kubelet is responding to inode starvation, it will reclaim inodes by evicting pods with the lowest quality of service first. If the kubelet is responding to lack of available disk, it will rank pods within a quality of service that consumes the largest amount of disk and kill those first.

With Imagefs

If nodefs is triggering evictions, kubelet will sort pods based on the usage on nodefs - local volumes + logs of all its containers.

If imagefs is triggering evictions, kubelet will sort pods based on the writable layer usage of all its containers.

Without Imagefs

If nodefs is triggering evictions, kubelet will sort pods based on their total disk usage - local volumes + logs & writable layer of all its containers.

Minimum eviction reclaim

In certain scenarios, eviction of pods could result in reclamation of small amount of resources. This can result in kubelet hitting eviction thresholds in repeated successions. In addition to that, eviction of resources like disk, is time consuming.

To mitigate these issues, kubelet can have a per-resource minimum-reclaim. Whenever kubelet observes resource pressure, kubelet will attempt to reclaim at least minimum-reclaim amount of resource below the configured eviction threshold.

For example, with the following configuration:


If an eviction threshold is triggered for memory.available, the kubelet will work to ensure that memory.available is at least 500Mi. For nodefs.available, the kubelet will work to ensure that nodefs.available is at least 1.5Gi, and for imagefs.available it will work to ensure that imagefs.available is at least 102Gi before no longer reporting pressure on their associated resources.

The default eviction-minimum-reclaim is 0 for all resources.


The node will report a condition when a compute resource is under pressure. The scheduler views that condition as a signal to dissuade placing additional pods on the node.

Node Condition Scheduler Behavior
MemoryPressure No new BestEffort pods are scheduled to the node.
DiskPressure No new pods are scheduled to the node.

Node OOM Behavior

If the node experiences a system OOM (out of memory) event prior to the kubelet is able to reclaim memory, the node depends on the oom_killer to respond.

The kubelet sets a oom_score_adj value for each container based on the quality of service for the pod.

Quality of Service oom_score_adj
Guaranteed -998
BestEffort 1000
Burstable min(max(2, 1000 - (1000 * memoryRequestBytes) / machineMemoryCapacityBytes), 999)

If the kubelet is unable to reclaim memory prior to a node experiencing system OOM, the oom_killer will calculate an oom_score based on the percentage of memory its using on the node, and then add the oom_score_adj to get an effective oom_score for the container, and then kills the container with the highest score.

The intended behavior should be that containers with the lowest quality of service that are consuming the largest amount of memory relative to the scheduling request should be killed first in order to reclaim memory.

Unlike pod eviction, if a pod container is OOM killed, it may be restarted by the kubelet based on its RestartPolicy.

Best Practices

Schedulable resources and eviction policies

Let’s imagine the following scenario:

To facilitate this scenario, the kubelet would be launched as follows:


Implicit in this configuration is the understanding that “System reserved” should include the amount of memory covered by the eviction threshold.

To reach that capacity, either some pod is using more than its request, or the system is using more than 500Mi.

This configuration will ensure that the scheduler does not place pods on a node that immediately induce memory pressure and trigger eviction assuming those pods use less than their configured request.


It is never desired for a kubelet to evict a pod that was derived from a DaemonSet since the pod will immediately be recreated and rescheduled back to the same node.

At the moment, the kubelet has no ability to distinguish a pod created from DaemonSet versus any other object. If/when that information is available, the kubelet could pro-actively filter those pods from the candidate set of pods provided to the eviction strategy.

In general, it is strongly recommended that DaemonSet not create BestEffort pods to avoid being identified as a candidate pod for eviction. Instead DaemonSet should ideally launch Guaranteed pods.

Deprecation of existing feature flags to reclaim disk

kubelet has been freeing up disk space on demand to keep the node stable.

As disk based eviction matures, the following kubelet flags will be marked for deprecation in favor of the simpler configuation supported around eviction.

Existing Flag New Flag
--image-gc-high-threshold --eviction-hard or eviction-soft
--image-gc-low-threshold --eviction-minimum-reclaim
--maximum-dead-containers deprecated
--maximum-dead-containers-per-container deprecated
--minimum-container-ttl-duration deprecated
--low-diskspace-threshold-mb --eviction-hard or eviction-soft
--outofdisk-transition-frequency --eviction-pressure-transition-period

Known issues

kubelet may not observe memory pressure right away

The kubelet currently 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 OOMKiller will still be invoked. We intend to integrate with the memcg notification API in a future release to reduce this latency, and instead have the kernel tell us when a threshold has been crossed immmediately.

If you are not trying to achieve extreme utilization, but a sensible measure of overcommit, a viable workaround for this issue is to set eviction thresholds at approximately 75% capacity. This increases the ability of this feature to prevent system OOMs, and promote eviction of workloads so cluster state can rebalance.

kubelet may evict more pods than needed

The pod eviction may evict more pods than needed due to stats collection timing gap. This can be mitigated by adding the ability to get root container stats on an on-demand basis ( in the future.

How kubelet ranks pods for eviction in response to inode exhaustion

At this time, it is not possible to know how many inodes were consumed by a particular container. If the kubelet observes inode exhaustion, it will evict pods by ranking them by quality of service. The following issue has been opened in cadvisor to track per container inode consumption ( which would allow us to rank pods by inode consumption. For example, this would let us identify a container that created large numbers of 0 byte files, and evict that pod over others.


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