Reserve Compute Resources for System Daemons

Kubernetes nodes can be scheduled to Capacity. Pods can consume all the available capacity on a node by default. This is an issue because nodes typically run quite a few system daemons that power the OS and Kubernetes itself. Unless resources are set aside for these system daemons, pods and system daemons compete for resources and lead to resource starvation issues on the node.

The kubelet exposes a feature named 'Node Allocatable' that helps to reserve compute resources for system daemons. Kubernetes recommends cluster administrators to configure 'Node Allocatable' based on their workload density on each node.

Before you begin

You need to have a Kubernetes cluster, and the kubectl command-line tool must be configured to communicate with your cluster. It is recommended to run this tutorial on a cluster with at least two nodes that are not acting as control plane hosts. If you do not already have a cluster, you can create one by using minikube or you can use one of these Kubernetes playgrounds:

You can configure below kubelet configuration settings using the kubelet configuration file.

Node Allocatable

node capacity

'Allocatable' on a Kubernetes node is defined as the amount of compute resources that are available for pods. The scheduler does not over-subscribe 'Allocatable'. 'CPU', 'memory' and 'ephemeral-storage' are supported as of now.

Node Allocatable is exposed as part of v1.Node object in the API and as part of kubectl describe node in the CLI.

Resources can be reserved for two categories of system daemons in the kubelet.

Enabling QoS and Pod level cgroups

To properly enforce node allocatable constraints on the node, you must enable the new cgroup hierarchy via the cgroupsPerQOS setting. This setting is enabled by default. When enabled, the kubelet will parent all end-user pods under a cgroup hierarchy managed by the kubelet.

Configuring a cgroup driver

The kubelet supports manipulation of the cgroup hierarchy on the host using a cgroup driver. The driver is configured via the cgroupDriver setting.

The supported values are the following:

  • cgroupfs is the default driver that performs direct manipulation of the cgroup filesystem on the host in order to manage cgroup sandboxes.
  • systemd is an alternative driver that manages cgroup sandboxes using transient slices for resources that are supported by that init system.

Depending on the configuration of the associated container runtime, operators may have to choose a particular cgroup driver to ensure proper system behavior. For example, if operators use the systemd cgroup driver provided by the containerd runtime, the kubelet must be configured to use the systemd cgroup driver.

Kube Reserved

  • KubeletConfiguration Setting: kubeReserved: {}. Example value {cpu: 100m, memory: 100Mi, ephemeral-storage: 1Gi, pid=1000}
  • KubeletConfiguration Setting: kubeReservedCgroup: ""

kubeReserved is meant to capture resource reservation for kubernetes system daemons like the kubelet, container runtime, etc. It is not meant to reserve resources for system daemons that are run as pods. kubeReserved is typically a function of pod density on the nodes.

In addition to cpu, memory, and ephemeral-storage, pid may be specified to reserve the specified number of process IDs for kubernetes system daemons.

To optionally enforce kubeReserved on kubernetes system daemons, specify the parent control group for kube daemons as the value for kubeReservedCgroup setting, and add kube-reserved to enforceNodeAllocatable.

It is recommended that the kubernetes system daemons are placed under a top level control group (runtime.slice on systemd machines for example). Each system daemon should ideally run within its own child control group. Refer to the design proposal for more details on recommended control group hierarchy.

Note that Kubelet does not create kubeReservedCgroup if it doesn't exist. The kubelet will fail to start if an invalid cgroup is specified. With systemd cgroup driver, you should follow a specific pattern for the name of the cgroup you define: the name should be the value you set for kubeReservedCgroup, with .slice appended.

System Reserved

  • KubeletConfiguration Setting: systemReserved: {}. Example value {cpu: 100m, memory: 100Mi, ephemeral-storage: 1Gi, pid=1000}
  • KubeletConfiguration Setting: systemReservedCgroup: ""

systemReserved is meant to capture resource reservation for OS system daemons like sshd, udev, etc. systemReserved should reserve memory for the kernel too since kernel memory is not accounted to pods in Kubernetes at this time. Reserving resources for user login sessions is also recommended (user.slice in systemd world).

In addition to cpu, memory, and ephemeral-storage, pid may be specified to reserve the specified number of process IDs for OS system daemons.

To optionally enforce systemReserved on system daemons, specify the parent control group for OS system daemons as the value for systemReservedCgroup setting, and add system-reserved to enforceNodeAllocatable.

It is recommended that the OS system daemons are placed under a top level control group (system.slice on systemd machines for example).

Note that kubelet does not create systemReservedCgroup if it doesn't exist. kubelet will fail if an invalid cgroup is specified. With systemd cgroup driver, you should follow a specific pattern for the name of the cgroup you define: the name should be the value you set for systemReservedCgroup, with .slice appended.

Explicitly Reserved CPU List

FEATURE STATE: Kubernetes v1.17 [stable]

KubeletConfiguration Setting: reservedSystemCPUs:. Example value 0-3

reservedSystemCPUs is meant to define an explicit CPU set for OS system daemons and kubernetes system daemons. reservedSystemCPUs is for systems that do not intend to define separate top level cgroups for OS system daemons and kubernetes system daemons with regard to cpuset resource. If the Kubelet does not have kubeReservedCgroup and systemReservedCgroup, the explicit cpuset provided by reservedSystemCPUs will take precedence over the CPUs defined by kubeReservedCgroup and systemReservedCgroup options.

This option is specifically designed for Telco/NFV use cases where uncontrolled interrupts/timers may impact the workload performance. you can use this option to define the explicit cpuset for the system/kubernetes daemons as well as the interrupts/timers, so the rest CPUs on the system can be used exclusively for workloads, with less impact from uncontrolled interrupts/timers. To move the system daemon, kubernetes daemons and interrupts/timers to the explicit cpuset defined by this option, other mechanism outside Kubernetes should be used. For example: in Centos, you can do this using the tuned toolset.

Eviction Thresholds

KubeletConfiguration Setting: evictionHard: {memory.available: "100Mi", nodefs.available: "10%", nodefs.inodesFree: "5%", imagefs.available: "15%"}. Example value: {memory.available: "<500Mi"}

Memory pressure at the node level leads to System OOMs which affects the entire node and all pods running on it. Nodes can go offline temporarily until memory has been reclaimed. To avoid (or reduce the probability of) system OOMs kubelet provides out of resource management. Evictions are supported for memory and ephemeral-storage only. By reserving some memory via evictionHard setting, the kubelet attempts to evict pods whenever memory availability on the node drops below the reserved value. Hypothetically, if system daemons did not exist on a node, pods cannot use more than capacity - eviction-hard. For this reason, resources reserved for evictions are not available for pods.

Enforcing Node Allocatable

KubeletConfiguration setting: enforceNodeAllocatable: [pods]. Example value: [pods,system-reserved,kube-reserved]

The scheduler treats 'Allocatable' as the available capacity for pods.

kubelet enforce 'Allocatable' across pods by default. Enforcement is performed by evicting pods whenever the overall usage across all pods exceeds 'Allocatable'. More details on eviction policy can be found on the node pressure eviction page. This enforcement is controlled by specifying pods value to the KubeletConfiguration setting enforceNodeAllocatable.

Optionally, kubelet can be made to enforce kubeReserved and systemReserved by specifying kube-reserved & system-reserved values in the same setting. Note that to enforce kubeReserved or systemReserved, kubeReservedCgroup or systemReservedCgroup needs to be specified respectively.

General Guidelines

System daemons are expected to be treated similar to Guaranteed pods. System daemons can burst within their bounding control groups and this behavior needs to be managed as part of kubernetes deployments. For example, kubelet should have its own control group and share kubeReserved resources with the container runtime. However, Kubelet cannot burst and use up all available Node resources if kubeReserved is enforced.

Be extra careful while enforcing systemReserved reservation since it can lead to critical system services being CPU starved, OOM killed, or unable to fork on the node. The recommendation is to enforce systemReserved only if a user has profiled their nodes exhaustively to come up with precise estimates and is confident in their ability to recover if any process in that group is oom-killed.

  • To begin with enforce 'Allocatable' on pods.
  • Once adequate monitoring and alerting is in place to track kube system daemons, attempt to enforce kubeReserved based on usage heuristics.
  • If absolutely necessary, enforce systemReserved over time.

The resource requirements of kube system daemons may grow over time as more and more features are added. Over time, kubernetes project will attempt to bring down utilization of node system daemons, but that is not a priority as of now. So expect a drop in Allocatable capacity in future releases.

Example Scenario

Here is an example to illustrate Node Allocatable computation:

  • Node has 32Gi of memory, 16 CPUs and 100Gi of Storage
  • kubeReserved is set to {cpu: 1000m, memory: 2Gi, ephemeral-storage: 1Gi}
  • systemReserved is set to {cpu: 500m, memory: 1Gi, ephemeral-storage: 1Gi}
  • evictionHard is set to {memory.available: "<500Mi", nodefs.available: "<10%"}

Under this scenario, 'Allocatable' will be 14.5 CPUs, 28.5Gi of memory and 88Gi of local storage. Scheduler ensures that the total memory requests across all pods on this node does not exceed 28.5Gi and storage doesn't exceed 88Gi. Kubelet evicts pods whenever the overall memory usage across pods exceeds 28.5Gi, or if overall disk usage exceeds 88Gi. If all processes on the node consume as much CPU as they can, pods together cannot consume more than 14.5 CPUs.

If kubeReserved and/or systemReserved is not enforced and system daemons exceed their reservation, kubelet evicts pods whenever the overall node memory usage is higher than 31.5Gi or storage is greater than 90Gi.

Last modified December 15, 2024 at 6:24 PM PST: Merge pull request #49087 from Arhell/es-link (2c4497f)