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Control Topology Management Policies on a node
Kubernetes v1.18 [beta]
An increasing number of systems leverage a combination of CPUs and hardware accelerators to support latency-critical execution and high-throughput parallel computation. These include workloads in fields such as telecommunications, scientific computing, machine learning, financial services and data analytics. Such hybrid systems comprise a high performance environment.
In order to extract the best performance, optimizations related to CPU isolation, memory and device locality are required. However, in Kubernetes, these optimizations are handled by a disjoint set of components.
Topology Manager is a Kubelet component that aims to coordinate the set of components that are responsible for these optimizations.
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:
Your Kubernetes server must be at or later than version v1.18. To check the version, enterkubectl version
.How Topology Manager Works
Prior to the introduction of Topology Manager, the CPU and Device Manager in Kubernetes make resource allocation decisions independently of each other. This can result in undesirable allocations on multiple-socketed systems, performance/latency sensitive applications will suffer due to these undesirable allocations. Undesirable in this case meaning for example, CPUs and devices being allocated from different NUMA Nodes thus, incurring additional latency.
The Topology Manager is a Kubelet component, which acts as a source of truth so that other Kubelet components can make topology aligned resource allocation choices.
The Topology Manager provides an interface for components, called Hint Providers, to send and receive topology information. Topology Manager has a set of node level policies which are explained below.
The Topology manager receives Topology information from the Hint Providers as a bitmask denoting NUMA Nodes available and a preferred allocation indication. The Topology Manager policies perform a set of operations on the hints provided and converge on the hint determined by the policy to give the optimal result, if an undesirable hint is stored the preferred field for the hint will be set to false. In the current policies preferred is the narrowest preferred mask. The selected hint is stored as part of the Topology Manager. Depending on the policy configured the pod can be accepted or rejected from the node based on the selected hint. The hint is then stored in the Topology Manager for use by the Hint Providers when making the resource allocation decisions.
Enable the Topology Manager feature
Support for the Topology Manager requires TopologyManager
feature gate to be enabled.
It is enabled by default starting with Kubernetes 1.18.
Topology Manager Scopes and Policies
The Topology Manager currently:
- Aligns Pods of all QoS classes.
- Aligns the requested resources that Hint Provider provides topology hints for.
If these conditions are met, the Topology Manager will align the requested resources.
In order to customise how this alignment is carried out, the Topology Manager provides two
distinct knobs: scope
and policy
.
The scope
defines the granularity at which you would like resource alignment to be performed
(e.g. at the pod
or container
level). And the policy
defines the actual strategy used to
carry out the alignment (e.g. best-effort
, restricted
, single-numa-node
, etc.).
Details on the various scopes
and policies
available today can be found below.
Topology Manager Scopes
The Topology Manager can deal with the alignment of resources in a couple of distinct scopes:
container
(default)pod
Either option can be selected at a time of the kubelet startup, with --topology-manager-scope
flag.
container scope
The container
scope is used by default.
Within this scope, the Topology Manager performs a number of sequential resource alignments, i.e., for each container (in a pod) a separate alignment is computed. In other words, there is no notion of grouping the containers to a specific set of NUMA nodes, for this particular scope. In effect, the Topology Manager performs an arbitrary alignment of individual containers to NUMA nodes.
The notion of grouping the containers was endorsed and implemented on purpose in the following
scope, for example the pod
scope.
pod scope
To select the pod
scope, start the kubelet with the command line option --topology-manager-scope=pod
.
This scope allows for grouping all containers in a pod to a common set of NUMA nodes. That is, the Topology Manager treats a pod as a whole and attempts to allocate the entire pod (all containers) to either a single NUMA node or a common set of NUMA nodes. The following examples illustrate the alignments produced by the Topology Manager on different occasions:
- all containers can be and are allocated to a single NUMA node;
- all containers can be and are allocated to a shared set of NUMA nodes.
The total amount of particular resource demanded for the entire pod is calculated according to effective requests/limits formula, and thus, this total value is equal to the maximum of:
- the sum of all app container requests,
- the maximum of init container requests,
for a resource.
Using the pod
scope in tandem with single-numa-node
Topology Manager policy is specifically
valuable for workloads that are latency sensitive or for high-throughput applications that perform
IPC. By combining both options, you are able to place all containers in a pod onto a single NUMA
node; hence, the inter-NUMA communication overhead can be eliminated for that pod.
In the case of single-numa-node
policy, a pod is accepted only if a suitable set of NUMA nodes
is present among possible allocations. Reconsider the example above:
- a set containing only a single NUMA node - it leads to pod being admitted,
- whereas a set containing more NUMA nodes - it results in pod rejection (because instead of one NUMA node, two or more NUMA nodes are required to satisfy the allocation).
To recap, Topology Manager first computes a set of NUMA nodes and then tests it against Topology Manager policy, which either leads to the rejection or admission of the pod.
Topology Manager Policies
Topology Manager supports four allocation policies. You can set a policy via a Kubelet flag,
--topology-manager-policy
. There are four supported policies:
none
(default)best-effort
restricted
single-numa-node
none policy
This is the default policy and does not perform any topology alignment.
best-effort policy
For each container in a Pod, the kubelet, with best-effort
topology management policy, calls
each Hint Provider to discover their resource availability. Using this information, the Topology
Manager stores the preferred NUMA Node affinity for that container. If the affinity is not
preferred, Topology Manager will store this and admit the pod to the node anyway.
The Hint Providers can then use this information when making the resource allocation decision.
restricted policy
For each container in a Pod, the kubelet, with restricted
topology management policy, calls each
Hint Provider to discover their resource availability. Using this information, the Topology
Manager stores the preferred NUMA Node affinity for that container. If the affinity is not
preferred, Topology Manager will reject this pod from the node. This will result in a pod in a
Terminated
state with a pod admission failure.
Once the pod is in a Terminated
state, the Kubernetes scheduler will not attempt to
reschedule the pod. It is recommended to use a ReplicaSet or Deployment to trigger a redeploy of
the pod. An external control loop could be also implemented to trigger a redeployment of pods that
have the Topology Affinity
error.
If the pod is admitted, the Hint Providers can then use this information when making the resource allocation decision.
single-numa-node policy
For each container in a Pod, the kubelet, with single-numa-node
topology management policy,
calls each Hint Provider to discover their resource availability. Using this information, the
Topology Manager determines if a single NUMA Node affinity is possible. If it is, Topology
Manager will store this and the Hint Providers can then use this information when making the
resource allocation decision. If, however, this is not possible then the Topology Manager will
reject the pod from the node. This will result in a pod in a Terminated
state with a pod
admission failure.
Once the pod is in a Terminated
state, the Kubernetes scheduler will not attempt to
reschedule the pod. It is recommended to use a Deployment with replicas to trigger a redeploy of
the Pod.An external control loop could be also implemented to trigger a redeployment of pods
that have the Topology Affinity
error.
Pod Interactions with Topology Manager Policies
Consider the containers in the following pod specs:
spec:
containers:
- name: nginx
image: nginx
This pod runs in the BestEffort
QoS class because no resource requests
or limits
are specified.
spec:
containers:
- name: nginx
image: nginx
resources:
limits:
memory: "200Mi"
requests:
memory: "100Mi"
This pod runs in the Burstable
QoS class because requests are less than limits.
If the selected policy is anything other than none
, Topology Manager would consider these Pod
specifications. The Topology Manager would consult the Hint Providers to get topology hints.
In the case of the static
, the CPU Manager policy would return default topology hint, because
these Pods do not have explicitly request CPU resources.
spec:
containers:
- name: nginx
image: nginx
resources:
limits:
memory: "200Mi"
cpu: "2"
example.com/device: "1"
requests:
memory: "200Mi"
cpu: "2"
example.com/device: "1"
This pod with integer CPU request runs in the Guaranteed
QoS class because requests
are equal
to limits
.
spec:
containers:
- name: nginx
image: nginx
resources:
limits:
memory: "200Mi"
cpu: "300m"
example.com/device: "1"
requests:
memory: "200Mi"
cpu: "300m"
example.com/device: "1"
This pod with sharing CPU request runs in the Guaranteed
QoS class because requests
are equal
to limits
.
spec:
containers:
- name: nginx
image: nginx
resources:
limits:
example.com/deviceA: "1"
example.com/deviceB: "1"
requests:
example.com/deviceA: "1"
example.com/deviceB: "1"
This pod runs in the BestEffort
QoS class because there are no CPU and memory requests.
The Topology Manager would consider the above pods. The Topology Manager would consult the Hint Providers, which are CPU and Device Manager to get topology hints for the pods.
In the case of the Guaranteed
pod with integer CPU request, the static
CPU Manager policy
would return topology hints relating to the exclusive CPU and the Device Manager would send back
hints for the requested device.
In the case of the Guaranteed
pod with sharing CPU request, the static
CPU Manager policy
would return default topology hint as there is no exclusive CPU request and the Device Manager
would send back hints for the requested device.
In the above two cases of the Guaranteed
pod, the none
CPU Manager policy would return default
topology hint.
In the case of the BestEffort
pod, the static
CPU Manager policy would send back the default
topology hint as there is no CPU request and the Device Manager would send back the hints for each
of the requested devices.
Using this information the Topology Manager calculates the optimal hint for the pod and stores this information, which will be used by the Hint Providers when they are making their resource assignments.
Known Limitations
The maximum number of NUMA nodes that Topology Manager allows is 8. With more than 8 NUMA nodes there will be a state explosion when trying to enumerate the possible NUMA affinities and generating their hints.
The scheduler is not topology-aware, so it is possible to be scheduled on a node and then fail on the node due to the Topology Manager.