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Objects In Kubernetes
Kubernetes objects are persistent entities in the Kubernetes system. Kubernetes uses these entities to represent the state of your cluster. Learn about the Kubernetes object model and how to work with these objects.
This page explains how Kubernetes objects are represented in the Kubernetes API, and how you can
express them in .yaml
format.
Understanding Kubernetes objects
Kubernetes objects are persistent entities in the Kubernetes system. Kubernetes uses these
entities to represent the state of your cluster. Specifically, they can describe:
- What containerized applications are running (and on which nodes)
- The resources available to those applications
- The policies around how those applications behave, such as restart policies, upgrades, and fault-tolerance
A Kubernetes object is a "record of intent"--once you create the object, the Kubernetes system
will constantly work to ensure that the object exists. By creating an object, you're effectively
telling the Kubernetes system what you want your cluster's workload to look like; this is your
cluster's desired state.
To work with Kubernetes objects—whether to create, modify, or delete them—you'll need to use the
Kubernetes API. When you use the kubectl
command-line
interface, for example, the CLI makes the necessary Kubernetes API calls for you. You can also use
the Kubernetes API directly in your own programs using one of the
Client Libraries.
Object spec and status
Almost every Kubernetes object includes two nested object fields that govern
the object's configuration: the object spec
and the object status
.
For objects that have a spec
, you have to set this when you create the object,
providing a description of the characteristics you want the resource to have:
its desired state.
The status
describes the current state of the object, supplied and updated
by the Kubernetes system and its components. The Kubernetes
control plane continually
and actively manages every object's actual state to match the desired state you
supplied.
For example: in Kubernetes, a Deployment is an object that can represent an
application running on your cluster. When you create the Deployment, you
might set the Deployment spec
to specify that you want three replicas of
the application to be running. The Kubernetes system reads the Deployment
spec and starts three instances of your desired application--updating
the status to match your spec. If any of those instances should fail
(a status change), the Kubernetes system responds to the difference
between spec and status by making a correction--in this case, starting
a replacement instance.
For more information on the object spec, status, and metadata, see the
Kubernetes API Conventions.
Describing a Kubernetes object
When you create an object in Kubernetes, you must provide the object spec that describes its
desired state, as well as some basic information about the object (such as a name). When you use
the Kubernetes API to create the object (either directly or via kubectl
), that API request must
include that information as JSON in the request body.
Most often, you provide the information to kubectl
in a file known as a manifest.
By convention, manifests are YAML (you could also use JSON format).
Tools such as kubectl
convert the information from a manifest into JSON or another supported
serialization format when making the API request over HTTP.
Here's an example manifest that shows the required fields and object spec for a Kubernetes
Deployment:
apiVersion: apps/v1
kind: Deployment
metadata:
name: nginx-deployment
spec:
selector:
matchLabels:
app: nginx
replicas: 2 # tells deployment to run 2 pods matching the template
template:
metadata:
labels:
app: nginx
spec:
containers:
- name: nginx
image: nginx:1.14.2
ports:
- containerPort: 80
One way to create a Deployment using a manifest file like the one above is to use the
kubectl apply
command
in the kubectl
command-line interface, passing the .yaml
file as an argument. Here's an example:
kubectl apply -f https://k8s.io/examples/application/deployment.yaml
The output is similar to this:
deployment.apps/nginx-deployment created
Required fields
In the manifest (YAML or JSON file) for the Kubernetes object you want to create, you'll need to set values for
the following fields:
apiVersion
- Which version of the Kubernetes API you're using to create this object
kind
- What kind of object you want to create
metadata
- Data that helps uniquely identify the object, including a name
string, UID
, and optional namespace
spec
- What state you desire for the object
The precise format of the object spec
is different for every Kubernetes object, and contains
nested fields specific to that object. The Kubernetes API Reference
can help you find the spec format for all of the objects you can create using Kubernetes.
For example, see the spec
field
for the Pod API reference.
For each Pod, the .spec
field specifies the pod and its desired state (such as the container image name for
each container within that pod).
Another example of an object specification is the
spec
field
for the StatefulSet API. For StatefulSet, the .spec
field specifies the StatefulSet and
its desired state.
Within the .spec
of a StatefulSet is a template
for Pod objects. That template describes Pods that the StatefulSet controller will create in order to
satisfy the StatefulSet specification.
Different kinds of objects can also have different .status
; again, the API reference pages
detail the structure of that .status
field, and its content for each different type of object.
Server side field validation
Starting with Kubernetes v1.25, the API server offers server side
field validation
that detects unrecognized or duplicate fields in an object. It provides all the functionality
of kubectl --validate
on the server side.
The kubectl
tool uses the --validate
flag to set the level of field validation. It accepts the
values ignore
, warn
, and strict
while also accepting the values true
(equivalent to strict
)
and false
(equivalent to ignore
). The default validation setting for kubectl
is --validate=true
.
Strict
- Strict field validation, errors on validation failure
Warn
- Field validation is performed, but errors are exposed as warnings rather than failing the request
Ignore
- No server side field validation is performed
When kubectl
cannot connect to an API server that supports field validation it will fall back
to using client-side validation. Kubernetes 1.27 and later versions always offer field validation;
older Kubernetes releases might not. If your cluster is older than v1.27, check the documentation
for your version of Kubernetes.
What's next
If you're new to Kubernetes, read more about the following:
Kubernetes Object Management
explains how to use kubectl
to manage objects.
You might need to install kubectl if you don't already have it available.
To learn about the Kubernetes API in general, visit:
To learn about objects in Kubernetes in more depth, read other pages in this section:
1 - Kubernetes Object Management
The kubectl
command-line tool supports several different ways to create and manage
Kubernetes objects. This document provides an overview of the different
approaches. Read the Kubectl book for
details of managing objects by Kubectl.
Management techniques
Warning:
A Kubernetes object should be managed using only one technique. Mixing
and matching techniques for the same object results in undefined behavior.
Management technique |
Operates on |
Recommended environment |
Supported writers |
Learning curve |
Imperative commands |
Live objects |
Development projects |
1+ |
Lowest |
Imperative object configuration |
Individual files |
Production projects |
1 |
Moderate |
Declarative object configuration |
Directories of files |
Production projects |
1+ |
Highest |
Imperative commands
When using imperative commands, a user operates directly on live objects
in a cluster. The user provides operations to
the kubectl
command as arguments or flags.
This is the recommended way to get started or to run a one-off task in
a cluster. Because this technique operates directly on live
objects, it provides no history of previous configurations.
Examples
Run an instance of the nginx container by creating a Deployment object:
kubectl create deployment nginx --image nginx
Trade-offs
Advantages compared to object configuration:
- Commands are expressed as a single action word.
- Commands require only a single step to make changes to the cluster.
Disadvantages compared to object configuration:
- Commands do not integrate with change review processes.
- Commands do not provide an audit trail associated with changes.
- Commands do not provide a source of records except for what is live.
- Commands do not provide a template for creating new objects.
Imperative object configuration
In imperative object configuration, the kubectl command specifies the
operation (create, replace, etc.), optional flags and at least one file
name. The file specified must contain a full definition of the object
in YAML or JSON format.
See the API reference
for more details on object definitions.
Warning:
The imperative replace
command replaces the existing
spec with the newly provided one, dropping all changes to the object missing from
the configuration file. This approach should not be used with resource
types whose specs are updated independently of the configuration file.
Services of type LoadBalancer
, for example, have their externalIPs
field updated
independently from the configuration by the cluster.
Examples
Create the objects defined in a configuration file:
kubectl create -f nginx.yaml
Delete the objects defined in two configuration files:
kubectl delete -f nginx.yaml -f redis.yaml
Update the objects defined in a configuration file by overwriting
the live configuration:
kubectl replace -f nginx.yaml
Trade-offs
Advantages compared to imperative commands:
- Object configuration can be stored in a source control system such as Git.
- Object configuration can integrate with processes such as reviewing changes before push and audit trails.
- Object configuration provides a template for creating new objects.
Disadvantages compared to imperative commands:
- Object configuration requires basic understanding of the object schema.
- Object configuration requires the additional step of writing a YAML file.
Advantages compared to declarative object configuration:
- Imperative object configuration behavior is simpler and easier to understand.
- As of Kubernetes version 1.5, imperative object configuration is more mature.
Disadvantages compared to declarative object configuration:
- Imperative object configuration works best on files, not directories.
- Updates to live objects must be reflected in configuration files, or they will be lost during the next replacement.
Declarative object configuration
When using declarative object configuration, a user operates on object
configuration files stored locally, however the user does not define the
operations to be taken on the files. Create, update, and delete operations
are automatically detected per-object by kubectl
. This enables working on
directories, where different operations might be needed for different objects.
Note:
Declarative object configuration retains changes made by other
writers, even if the changes are not merged back to the object configuration file.
This is possible by using the patch
API operation to write only
observed differences, instead of using the replace
API operation to replace the entire object configuration.
Examples
Process all object configuration files in the configs
directory, and create or
patch the live objects. You can first diff
to see what changes are going to be
made, and then apply:
kubectl diff -f configs/
kubectl apply -f configs/
Recursively process directories:
kubectl diff -R -f configs/
kubectl apply -R -f configs/
Trade-offs
Advantages compared to imperative object configuration:
- Changes made directly to live objects are retained, even if they are not merged back into the configuration files.
- Declarative object configuration has better support for operating on directories and automatically detecting operation types (create, patch, delete) per-object.
Disadvantages compared to imperative object configuration:
- Declarative object configuration is harder to debug and understand results when they are unexpected.
- Partial updates using diffs create complex merge and patch operations.
What's next
2 - Object Names and IDs
Each object in your cluster has a Name that is unique for that type of resource.
Every Kubernetes object also has a UID that is unique across your whole cluster.
For example, you can only have one Pod named myapp-1234
within the same namespace, but you can have one Pod and one Deployment that are each named myapp-1234
.
For non-unique user-provided attributes, Kubernetes provides labels and annotations.
Names
A client-provided string that refers to an object in a resource URL, such as /api/v1/pods/some-name
.
Only one object of a given kind can have a given name at a time. However, if you delete the object, you can make a new object with the same name.
Names must be unique across all API versions
of the same resource. API resources are distinguished by their API group, resource type, namespace
(for namespaced resources), and name. In other words, API version is irrelevant in this context.
Note:
In cases when objects represent a physical entity, like a Node representing a physical host, when the host is re-created under the same name without deleting and re-creating the Node, Kubernetes treats the new host as the old one, which may lead to inconsistencies.
The server may generate a name when generateName
is provided instead of name
in a resource create request.
When generateName
is used, the provided value is used as a name prefix, which server appends a generated suffix
to. Even though the name is generated, it may conflict with existing names resulting in a HTTP 409 resopnse. This
became far less likely to happen in Kubernetes v1.31 and later, since the server will make up to 8 attempt to generate a
unique name before returning a HTTP 409 response.
Below are four types of commonly used name constraints for resources.
DNS Subdomain Names
Most resource types require a name that can be used as a DNS subdomain name
as defined in RFC 1123.
This means the name must:
- contain no more than 253 characters
- contain only lowercase alphanumeric characters, '-' or '.'
- start with an alphanumeric character
- end with an alphanumeric character
RFC 1123 Label Names
Some resource types require their names to follow the DNS
label standard as defined in RFC 1123.
This means the name must:
- contain at most 63 characters
- contain only lowercase alphanumeric characters or '-'
- start with an alphanumeric character
- end with an alphanumeric character
RFC 1035 Label Names
Some resource types require their names to follow the DNS
label standard as defined in RFC 1035.
This means the name must:
- contain at most 63 characters
- contain only lowercase alphanumeric characters or '-'
- start with an alphabetic character
- end with an alphanumeric character
Note:
The only difference between the RFC 1035 and RFC 1123
label standards is that RFC 1123 labels are allowed to
start with a digit, whereas RFC 1035 labels can start
with a lowercase alphabetic character only.
Path Segment Names
Some resource types require their names to be able to be safely encoded as a
path segment. In other words, the name may not be "." or ".." and the name may
not contain "/" or "%".
Here's an example manifest for a Pod named nginx-demo
.
apiVersion: v1
kind: Pod
metadata:
name: nginx-demo
spec:
containers:
- name: nginx
image: nginx:1.14.2
ports:
- containerPort: 80
Note:
Some resource types have additional restrictions on their names.
UIDs
A Kubernetes systems-generated string to uniquely identify objects.
Every object created over the whole lifetime of a Kubernetes cluster has a distinct UID. It is intended to distinguish between historical occurrences of similar entities.
Kubernetes UIDs are universally unique identifiers (also known as UUIDs).
UUIDs are standardized as ISO/IEC 9834-8 and as ITU-T X.667.
What's next
3 - Labels and Selectors
Labels are key/value pairs that are attached to
objects such as Pods.
Labels are intended to be used to specify identifying attributes of objects
that are meaningful and relevant to users, but do not directly imply semantics
to the core system. Labels can be used to organize and to select subsets of
objects. Labels can be attached to objects at creation time and subsequently
added and modified at any time. Each object can have a set of key/value labels
defined. Each Key must be unique for a given object.
"metadata": {
"labels": {
"key1" : "value1",
"key2" : "value2"
}
}
Labels allow for efficient queries and watches and are ideal for use in UIs
and CLIs. Non-identifying information should be recorded using
annotations.
Motivation
Labels enable users to map their own organizational structures onto system objects
in a loosely coupled fashion, without requiring clients to store these mappings.
Service deployments and batch processing pipelines are often multi-dimensional entities
(e.g., multiple partitions or deployments, multiple release tracks, multiple tiers,
multiple micro-services per tier). Management often requires cross-cutting operations,
which breaks encapsulation of strictly hierarchical representations, especially rigid
hierarchies determined by the infrastructure rather than by users.
Example labels:
"release" : "stable"
, "release" : "canary"
"environment" : "dev"
, "environment" : "qa"
, "environment" : "production"
"tier" : "frontend"
, "tier" : "backend"
, "tier" : "cache"
"partition" : "customerA"
, "partition" : "customerB"
"track" : "daily"
, "track" : "weekly"
These are examples of
commonly used labels;
you are free to develop your own conventions.
Keep in mind that label Key must be unique for a given object.
Syntax and character set
Labels are key/value pairs. Valid label keys have two segments: an optional
prefix and name, separated by a slash (/
). The name segment is required and
must be 63 characters or less, beginning and ending with an alphanumeric
character ([a-z0-9A-Z]
) with dashes (-
), underscores (_
), dots (.
),
and alphanumerics between. The prefix is optional. If specified, the prefix
must be a DNS subdomain: a series of DNS labels separated by dots (.
),
not longer than 253 characters in total, followed by a slash (/
).
If the prefix is omitted, the label Key is presumed to be private to the user.
Automated system components (e.g. kube-scheduler
, kube-controller-manager
,
kube-apiserver
, kubectl
, or other third-party automation) which add labels
to end-user objects must specify a prefix.
The kubernetes.io/
and k8s.io/
prefixes are
reserved for Kubernetes core components.
Valid label value:
- must be 63 characters or less (can be empty),
- unless empty, must begin and end with an alphanumeric character (
[a-z0-9A-Z]
),
- could contain dashes (
-
), underscores (_
), dots (.
), and alphanumerics between.
For example, here's a manifest for a Pod that has two labels
environment: production
and app: nginx
:
apiVersion: v1
kind: Pod
metadata:
name: label-demo
labels:
environment: production
app: nginx
spec:
containers:
- name: nginx
image: nginx:1.14.2
ports:
- containerPort: 80
Label selectors
Unlike names and UIDs, labels
do not provide uniqueness. In general, we expect many objects to carry the same label(s).
Via a label selector, the client/user can identify a set of objects.
The label selector is the core grouping primitive in Kubernetes.
The API currently supports two types of selectors: equality-based and set-based.
A label selector can be made of multiple requirements which are comma-separated.
In the case of multiple requirements, all must be satisfied so the comma separator
acts as a logical AND (&&
) operator.
The semantics of empty or non-specified selectors are dependent on the context,
and API types that use selectors should document the validity and meaning of
them.
Note:
For some API types, such as ReplicaSets, the label selectors of two instances must
not overlap within a namespace, or the controller can see that as conflicting
instructions and fail to determine how many replicas should be present.
Caution:
For both equality-based and set-based conditions there is no logical OR (||
) operator.
Ensure your filter statements are structured accordingly.
Equality-based requirement
Equality- or inequality-based requirements allow filtering by label keys and values.
Matching objects must satisfy all of the specified label constraints, though they may
have additional labels as well. Three kinds of operators are admitted =
,==
,!=
.
The first two represent equality (and are synonyms), while the latter represents inequality.
For example:
environment = production
tier != frontend
The former selects all resources with key equal to environment
and value equal to production
.
The latter selects all resources with key equal to tier
and value distinct from frontend
,
and all resources with no labels with the tier
key. One could filter for resources in production
excluding frontend
using the comma operator: environment=production,tier!=frontend
One usage scenario for equality-based label requirement is for Pods to specify
node selection criteria. For example, the sample Pod below selects nodes where
the accelerator
label exists and is set to nvidia-tesla-p100
.
apiVersion: v1
kind: Pod
metadata:
name: cuda-test
spec:
containers:
- name: cuda-test
image: "registry.k8s.io/cuda-vector-add:v0.1"
resources:
limits:
nvidia.com/gpu: 1
nodeSelector:
accelerator: nvidia-tesla-p100
Set-based requirement
Set-based label requirements allow filtering keys according to a set of values.
Three kinds of operators are supported: in
,notin
and exists
(only the key identifier).
For example:
environment in (production, qa)
tier notin (frontend, backend)
partition
!partition
- The first example selects all resources with key equal to
environment
and value
equal to production
or qa
.
- The second example selects all resources with key equal to
tier
and values other
than frontend
and backend
, and all resources with no labels with the tier
key.
- The third example selects all resources including a label with key
partition
;
no values are checked.
- The fourth example selects all resources without a label with key
partition
;
no values are checked.
Similarly the comma separator acts as an AND operator. So filtering resources
with a partition
key (no matter the value) and with environment
different
than qa
can be achieved using partition,environment notin (qa)
.
The set-based label selector is a general form of equality since
environment=production
is equivalent to environment in (production)
;
similarly for !=
and notin
.
Set-based requirements can be mixed with equality-based requirements.
For example: partition in (customerA, customerB),environment!=qa
.
API
LIST and WATCH filtering
For list and watch operations, you can specify label selectors to filter the sets of objects
returned; you specify the filter using a query parameter.
(To learn in detail about watches in Kubernetes, read
efficient detection of changes).
Both requirements are permitted
(presented here as they would appear in a URL query string):
- equality-based requirements:
?labelSelector=environment%3Dproduction,tier%3Dfrontend
- set-based requirements:
?labelSelector=environment+in+%28production%2Cqa%29%2Ctier+in+%28frontend%29
Both label selector styles can be used to list or watch resources via a REST client.
For example, targeting apiserver
with kubectl
and using equality-based one may write:
kubectl get pods -l environment=production,tier=frontend
or using set-based requirements:
kubectl get pods -l 'environment in (production),tier in (frontend)'
As already mentioned set-based requirements are more expressive.
For instance, they can implement the OR operator on values:
kubectl get pods -l 'environment in (production, qa)'
or restricting negative matching via notin operator:
kubectl get pods -l 'environment,environment notin (frontend)'
Set references in API objects
Some Kubernetes objects, such as services
and replicationcontrollers
,
also use label selectors to specify sets of other resources, such as
pods.
Service and ReplicationController
The set of pods that a service
targets is defined with a label selector.
Similarly, the population of pods that a replicationcontroller
should
manage is also defined with a label selector.
Label selectors for both objects are defined in json
or yaml
files using maps,
and only equality-based requirement selectors are supported:
"selector": {
"component" : "redis",
}
or
selector:
component: redis
This selector (respectively in json
or yaml
format) is equivalent to
component=redis
or component in (redis)
.
Resources that support set-based requirements
Newer resources, such as Job
,
Deployment
,
ReplicaSet
, and
DaemonSet
,
support set-based requirements as well.
selector:
matchLabels:
component: redis
matchExpressions:
- { key: tier, operator: In, values: [cache] }
- { key: environment, operator: NotIn, values: [dev] }
matchLabels
is a map of {key,value}
pairs. A single {key,value}
in the
matchLabels
map is equivalent to an element of matchExpressions
, whose key
field is "key", the operator
is "In", and the values
array contains only "value".
matchExpressions
is a list of pod selector requirements. Valid operators include
In, NotIn, Exists, and DoesNotExist. The values set must be non-empty in the case of
In and NotIn. All of the requirements, from both matchLabels
and matchExpressions
are ANDed together -- they must all be satisfied in order to match.
Selecting sets of nodes
One use case for selecting over labels is to constrain the set of nodes onto which
a pod can schedule. See the documentation on
node selection for more information.
Using labels effectively
You can apply a single label to any resources, but this is not always the
best practice. There are many scenarios where multiple labels should be used to
distinguish resource sets from one another.
For instance, different applications would use different values for the app
label, but a
multi-tier application, such as the guestbook example,
would additionally need to distinguish each tier. The frontend could carry the following labels:
labels:
app: guestbook
tier: frontend
while the Redis master and replica would have different tier
labels, and perhaps even an
additional role
label:
labels:
app: guestbook
tier: backend
role: master
and
labels:
app: guestbook
tier: backend
role: replica
The labels allow for slicing and dicing the resources along any dimension specified by a label:
kubectl apply -f examples/guestbook/all-in-one/guestbook-all-in-one.yaml
kubectl get pods -Lapp -Ltier -Lrole
NAME READY STATUS RESTARTS AGE APP TIER ROLE
guestbook-fe-4nlpb 1/1 Running 0 1m guestbook frontend <none>
guestbook-fe-ght6d 1/1 Running 0 1m guestbook frontend <none>
guestbook-fe-jpy62 1/1 Running 0 1m guestbook frontend <none>
guestbook-redis-master-5pg3b 1/1 Running 0 1m guestbook backend master
guestbook-redis-replica-2q2yf 1/1 Running 0 1m guestbook backend replica
guestbook-redis-replica-qgazl 1/1 Running 0 1m guestbook backend replica
my-nginx-divi2 1/1 Running 0 29m nginx <none> <none>
my-nginx-o0ef1 1/1 Running 0 29m nginx <none> <none>
kubectl get pods -lapp=guestbook,role=replica
NAME READY STATUS RESTARTS AGE
guestbook-redis-replica-2q2yf 1/1 Running 0 3m
guestbook-redis-replica-qgazl 1/1 Running 0 3m
Updating labels
Sometimes you may want to relabel existing pods and other resources before creating
new resources. This can be done with kubectl label
.
For example, if you want to label all your NGINX Pods as frontend tier, run:
kubectl label pods -l app=nginx tier=fe
pod/my-nginx-2035384211-j5fhi labeled
pod/my-nginx-2035384211-u2c7e labeled
pod/my-nginx-2035384211-u3t6x labeled
This first filters all pods with the label "app=nginx", and then labels them with the "tier=fe".
To see the pods you labeled, run:
kubectl get pods -l app=nginx -L tier
NAME READY STATUS RESTARTS AGE TIER
my-nginx-2035384211-j5fhi 1/1 Running 0 23m fe
my-nginx-2035384211-u2c7e 1/1 Running 0 23m fe
my-nginx-2035384211-u3t6x 1/1 Running 0 23m fe
This outputs all "app=nginx" pods, with an additional label column of pods' tier
(specified with -L
or --label-columns
).
For more information, please see kubectl label.
What's next
4 - Namespaces
In Kubernetes, namespaces provide a mechanism for isolating groups of resources within a single cluster. Names of resources need to be unique within a namespace, but not across namespaces. Namespace-based scoping is applicable only for namespaced objects (e.g. Deployments, Services, etc.) and not for cluster-wide objects (e.g. StorageClass, Nodes, PersistentVolumes, etc.).
When to Use Multiple Namespaces
Namespaces are intended for use in environments with many users spread across multiple
teams, or projects. For clusters with a few to tens of users, you should not
need to create or think about namespaces at all. Start using namespaces when you
need the features they provide.
Namespaces provide a scope for names. Names of resources need to be unique within a namespace,
but not across namespaces. Namespaces cannot be nested inside one another and each Kubernetes
resource can only be in one namespace.
Namespaces are a way to divide cluster resources between multiple users (via resource quota).
It is not necessary to use multiple namespaces to separate slightly different
resources, such as different versions of the same software: use
labels to distinguish
resources within the same namespace.
Note:
For a production cluster, consider not using the default
namespace. Instead, make other namespaces and use those.
Initial namespaces
Kubernetes starts with four initial namespaces:
default
- Kubernetes includes this namespace so that you can start using your new cluster without first creating a namespace.
kube-node-lease
- This namespace holds Lease objects associated with each node. Node leases allow the kubelet to send heartbeats so that the control plane can detect node failure.
kube-public
- This namespace is readable by all clients (including those not authenticated). This namespace is mostly reserved for cluster usage, in case that some resources should be visible and readable publicly throughout the whole cluster. The public aspect of this namespace is only a convention, not a requirement.
kube-system
- The namespace for objects created by the Kubernetes system.
Working with Namespaces
Creation and deletion of namespaces are described in the
Admin Guide documentation for namespaces.
Note:
Avoid creating namespaces with the prefix kube-
, since it is reserved for Kubernetes system namespaces.
Viewing namespaces
You can list the current namespaces in a cluster using:
NAME STATUS AGE
default Active 1d
kube-node-lease Active 1d
kube-public Active 1d
kube-system Active 1d
Setting the namespace for a request
To set the namespace for a current request, use the --namespace
flag.
For example:
kubectl run nginx --image=nginx --namespace=<insert-namespace-name-here>
kubectl get pods --namespace=<insert-namespace-name-here>
Setting the namespace preference
You can permanently save the namespace for all subsequent kubectl commands in that
context.
kubectl config set-context --current --namespace=<insert-namespace-name-here>
# Validate it
kubectl config view --minify | grep namespace:
Namespaces and DNS
When you create a Service,
it creates a corresponding DNS entry.
This entry is of the form <service-name>.<namespace-name>.svc.cluster.local
, which means
that if a container only uses <service-name>
, it will resolve to the service which
is local to a namespace. This is useful for using the same configuration across
multiple namespaces such as Development, Staging and Production. If you want to reach
across namespaces, you need to use the fully qualified domain name (FQDN).
As a result, all namespace names must be valid
RFC 1123 DNS labels.
Warning:
By creating namespaces with the same name as public top-level
domains, Services in these
namespaces can have short DNS names that overlap with public DNS records.
Workloads from any namespace performing a DNS lookup without a trailing dot will
be redirected to those services, taking precedence over public DNS.
To mitigate this, limit privileges for creating namespaces to trusted users. If
required, you could additionally configure third-party security controls, such
as admission
webhooks,
to block creating any namespace with the name of public
TLDs.
Not all objects are in a namespace
Most Kubernetes resources (e.g. pods, services, replication controllers, and others) are
in some namespaces. However namespace resources are not themselves in a namespace.
And low-level resources, such as
nodes and
persistentVolumes, are not in any namespace.
To see which Kubernetes resources are and aren't in a namespace:
# In a namespace
kubectl api-resources --namespaced=true
# Not in a namespace
kubectl api-resources --namespaced=false
Automatic labelling
FEATURE STATE:
Kubernetes 1.22 [stable]
The Kubernetes control plane sets an immutable label
kubernetes.io/metadata.name
on all namespaces.
The value of the label is the namespace name.
What's next
5 - Annotations
You can use Kubernetes annotations to attach arbitrary non-identifying metadata
to objects.
Clients such as tools and libraries can retrieve this metadata.
You can use either labels or annotations to attach metadata to Kubernetes
objects. Labels can be used to select objects and to find
collections of objects that satisfy certain conditions. In contrast, annotations
are not used to identify and select objects. The metadata
in an annotation can be small or large, structured or unstructured, and can
include characters not permitted by labels. It is possible to use labels as
well as annotations in the metadata of the same object.
Annotations, like labels, are key/value maps:
"metadata": {
"annotations": {
"key1" : "value1",
"key2" : "value2"
}
}
Note:
The keys and the values in the map must be strings. In other words, you cannot use
numeric, boolean, list or other types for either the keys or the values.
Here are some examples of information that could be recorded in annotations:
-
Fields managed by a declarative configuration layer. Attaching these fields
as annotations distinguishes them from default values set by clients or
servers, and from auto-generated fields and fields set by
auto-sizing or auto-scaling systems.
-
Build, release, or image information like timestamps, release IDs, git branch,
PR numbers, image hashes, and registry address.
-
Pointers to logging, monitoring, analytics, or audit repositories.
-
Client library or tool information that can be used for debugging purposes:
for example, name, version, and build information.
-
User or tool/system provenance information, such as URLs of related objects
from other ecosystem components.
-
Lightweight rollout tool metadata: for example, config or checkpoints.
-
Phone or pager numbers of persons responsible, or directory entries that
specify where that information can be found, such as a team web site.
-
Directives from the end-user to the implementations to modify behavior or
engage non-standard features.
Instead of using annotations, you could store this type of information in an
external database or directory, but that would make it much harder to produce
shared client libraries and tools for deployment, management, introspection,
and the like.
Syntax and character set
Annotations are key/value pairs. Valid annotation keys have two segments: an optional prefix and name, separated by a slash (/
). The name segment is required and must be 63 characters or less, beginning and ending with an alphanumeric character ([a-z0-9A-Z]
) with dashes (-
), underscores (_
), dots (.
), and alphanumerics between. The prefix is optional. If specified, the prefix must be a DNS subdomain: a series of DNS labels separated by dots (.
), not longer than 253 characters in total, followed by a slash (/
).
If the prefix is omitted, the annotation Key is presumed to be private to the user. Automated system components (e.g. kube-scheduler
, kube-controller-manager
, kube-apiserver
, kubectl
, or other third-party automation) which add annotations to end-user objects must specify a prefix.
The kubernetes.io/
and k8s.io/
prefixes are reserved for Kubernetes core components.
For example, here's a manifest for a Pod that has the annotation imageregistry: https://hub.docker.com/
:
apiVersion: v1
kind: Pod
metadata:
name: annotations-demo
annotations:
imageregistry: "https://hub.docker.com/"
spec:
containers:
- name: nginx
image: nginx:1.14.2
ports:
- containerPort: 80
What's next
6 - Field Selectors
Field selectors let you select Kubernetes objects based on the
value of one or more resource fields. Here are some examples of field selector queries:
metadata.name=my-service
metadata.namespace!=default
status.phase=Pending
This kubectl
command selects all Pods for which the value of the status.phase
field is Running
:
kubectl get pods --field-selector status.phase=Running
Note:
Field selectors are essentially resource filters. By default, no selectors/filters are applied, meaning that all resources of the specified type are selected. This makes the kubectl
queries kubectl get pods
and kubectl get pods --field-selector ""
equivalent.
Supported fields
Supported field selectors vary by Kubernetes resource type. All resource types support the metadata.name
and metadata.namespace
fields. Using unsupported field selectors produces an error. For example:
kubectl get ingress --field-selector foo.bar=baz
Error from server (BadRequest): Unable to find "ingresses" that match label selector "", field selector "foo.bar=baz": "foo.bar" is not a known field selector: only "metadata.name", "metadata.namespace"
List of supported fields
Kind |
Fields |
Pod |
spec.nodeName
spec.restartPolicy
spec.schedulerName
spec.serviceAccountName
spec.hostNetwork
status.phase
status.podIP
status.nominatedNodeName |
Event |
involvedObject.kind
involvedObject.namespace
involvedObject.name
involvedObject.uid
involvedObject.apiVersion
involvedObject.resourceVersion
involvedObject.fieldPath
reason
reportingComponent
source
type |
Secret |
type |
Namespace |
status.phase |
ReplicaSet |
status.replicas |
ReplicationController |
status.replicas |
Job |
status.successful |
Node |
spec.unschedulable |
CertificateSigningRequest |
spec.signerName |
Custom resources fields
All custom resource types support the metadata.name
and metadata.namespace
fields.
Additionally, the spec.versions[*].selectableFields
field of a CustomResourceDefinition
declares which other fields in a custom resource may be used in field selectors. See selectable fields for custom resources
for more information about how to use field selectors with CustomResourceDefinitions.
Supported operators
You can use the =
, ==
, and !=
operators with field selectors (=
and ==
mean the same thing). This kubectl
command, for example, selects all Kubernetes Services that aren't in the default
namespace:
kubectl get services --all-namespaces --field-selector metadata.namespace!=default
Chained selectors
As with label and other selectors, field selectors can be chained together as a comma-separated list. This kubectl
command selects all Pods for which the status.phase
does not equal Running
and the spec.restartPolicy
field equals Always
:
kubectl get pods --field-selector=status.phase!=Running,spec.restartPolicy=Always
Multiple resource types
You can use field selectors across multiple resource types. This kubectl
command selects all Statefulsets and Services that are not in the default
namespace:
kubectl get statefulsets,services --all-namespaces --field-selector metadata.namespace!=default
7 - Finalizers
Finalizers are namespaced keys that tell Kubernetes to wait until specific
conditions are met before it fully deletes resources marked for deletion.
Finalizers alert controllers
to clean up resources the deleted object owned.
When you tell Kubernetes to delete an object that has finalizers specified for
it, the Kubernetes API marks the object for deletion by populating .metadata.deletionTimestamp
,
and returns a 202
status code (HTTP "Accepted"). The target object remains in a terminating state while the
control plane, or other components, take the actions defined by the finalizers.
After these actions are complete, the controller removes the relevant finalizers
from the target object. When the metadata.finalizers
field is empty,
Kubernetes considers the deletion complete and deletes the object.
You can use finalizers to control garbage collection
of resources. For example, you can define a finalizer to clean up related resources or
infrastructure before the controller deletes the target resource.
You can use finalizers to control garbage collection
of objects by alerting controllers
to perform specific cleanup tasks before deleting the target resource.
Finalizers don't usually specify the code to execute. Instead, they are
typically lists of keys on a specific resource similar to annotations.
Kubernetes specifies some finalizers automatically, but you can also specify
your own.
How finalizers work
When you create a resource using a manifest file, you can specify finalizers in
the metadata.finalizers
field. When you attempt to delete the resource, the
API server handling the delete request notices the values in the finalizers
field
and does the following:
- Modifies the object to add a
metadata.deletionTimestamp
field with the
time you started the deletion.
- Prevents the object from being removed until all items are removed from its
metadata.finalizers
field
- Returns a
202
status code (HTTP "Accepted")
The controller managing that finalizer notices the update to the object setting the
metadata.deletionTimestamp
, indicating deletion of the object has been requested.
The controller then attempts to satisfy the requirements of the finalizers
specified for that resource. Each time a finalizer condition is satisfied, the
controller removes that key from the resource's finalizers
field. When the
finalizers
field is emptied, an object with a deletionTimestamp
field set
is automatically deleted. You can also use finalizers to prevent deletion of unmanaged resources.
A common example of a finalizer is kubernetes.io/pv-protection
, which prevents
accidental deletion of PersistentVolume
objects. When a PersistentVolume
object is in use by a Pod, Kubernetes adds the pv-protection
finalizer. If you
try to delete the PersistentVolume
, it enters a Terminating
status, but the
controller can't delete it because the finalizer exists. When the Pod stops
using the PersistentVolume
, Kubernetes clears the pv-protection
finalizer,
and the controller deletes the volume.
Note:
-
When you DELETE
an object, Kubernetes adds the deletion timestamp for that object and then
immediately starts to restrict changes to the .metadata.finalizers
field for the object that is
now pending deletion. You can remove existing finalizers (deleting an entry from the finalizers
list) but you cannot add a new finalizer. You also cannot modify the deletionTimestamp
for an
object once it is set.
-
After the deletion is requested, you can not resurrect this object. The only way is to delete it and make a new similar object.
Owner references, labels, and finalizers
Like labels,
owner references
describe the relationships between objects in Kubernetes, but are used for a
different purpose. When a
controller manages objects
like Pods, it uses labels to track changes to groups of related objects. For
example, when a Job creates one or
more Pods, the Job controller applies labels to those pods and tracks changes to
any Pods in the cluster with the same label.
The Job controller also adds owner references to those Pods, pointing at the
Job that created the Pods. If you delete the Job while these Pods are running,
Kubernetes uses the owner references (not labels) to determine which Pods in the
cluster need cleanup.
Kubernetes also processes finalizers when it identifies owner references on a
resource targeted for deletion.
In some situations, finalizers can block the deletion of dependent objects,
which can cause the targeted owner object to remain for
longer than expected without being fully deleted. In these situations, you
should check finalizers and owner references on the target owner and dependent
objects to troubleshoot the cause.
Note:
In cases where objects are stuck in a deleting state, avoid manually
removing finalizers to allow deletion to continue. Finalizers are usually added
to resources for a reason, so forcefully removing them can lead to issues in
your cluster. This should only be done when the purpose of the finalizer is
understood and is accomplished in another way (for example, manually cleaning
up some dependent object).
What's next
8 - Owners and Dependents
In Kubernetes, some objects are
owners of other objects. For example, a
ReplicaSet is the owner
of a set of Pods. These owned objects are dependents of their owner.
Ownership is different from the labels and selectors
mechanism that some resources also use. For example, consider a Service that
creates EndpointSlice
objects. The Service uses labels to allow the control plane to
determine which EndpointSlice
objects are used for that Service. In addition
to the labels, each EndpointSlice
that is managed on behalf of a Service has
an owner reference. Owner references help different parts of Kubernetes avoid
interfering with objects they don’t control.
Owner references in object specifications
Dependent objects have a metadata.ownerReferences
field that references their
owner object. A valid owner reference consists of the object name and a UID
within the same namespace as the dependent object. Kubernetes sets the value of
this field automatically for objects that are dependents of other objects like
ReplicaSets, DaemonSets, Deployments, Jobs and CronJobs, and ReplicationControllers.
You can also configure these relationships manually by changing the value of
this field. However, you usually don't need to and can allow Kubernetes to
automatically manage the relationships.
Dependent objects also have an ownerReferences.blockOwnerDeletion
field that
takes a boolean value and controls whether specific dependents can block garbage
collection from deleting their owner object. Kubernetes automatically sets this
field to true
if a controller
(for example, the Deployment controller) sets the value of the
metadata.ownerReferences
field. You can also set the value of the
blockOwnerDeletion
field manually to control which dependents block garbage
collection.
A Kubernetes admission controller controls user access to change this field for
dependent resources, based on the delete permissions of the owner. This control
prevents unauthorized users from delaying owner object deletion.
Note:
Cross-namespace owner references are disallowed by design.
Namespaced dependents can specify cluster-scoped or namespaced owners.
A namespaced owner must exist in the same namespace as the dependent.
If it does not, the owner reference is treated as absent, and the dependent
is subject to deletion once all owners are verified absent.
Cluster-scoped dependents can only specify cluster-scoped owners.
In v1.20+, if a cluster-scoped dependent specifies a namespaced kind as an owner,
it is treated as having an unresolvable owner reference, and is not able to be garbage collected.
In v1.20+, if the garbage collector detects an invalid cross-namespace ownerReference
,
or a cluster-scoped dependent with an ownerReference
referencing a namespaced kind, a warning Event
with a reason of OwnerRefInvalidNamespace
and an involvedObject
of the invalid dependent is reported.
You can check for that kind of Event by running
kubectl get events -A --field-selector=reason=OwnerRefInvalidNamespace
.
Ownership and finalizers
When you tell Kubernetes to delete a resource, the API server allows the
managing controller to process any finalizer rules
for the resource. Finalizers
prevent accidental deletion of resources your cluster may still need to function
correctly. For example, if you try to delete a PersistentVolume that is still
in use by a Pod, the deletion does not happen immediately because the
PersistentVolume
has the kubernetes.io/pv-protection
finalizer on it.
Instead, the volume remains in the Terminating
status until Kubernetes clears
the finalizer, which only happens after the PersistentVolume
is no longer
bound to a Pod.
Kubernetes also adds finalizers to an owner resource when you use either
foreground or orphan cascading deletion.
In foreground deletion, it adds the foreground
finalizer so that the
controller must delete dependent resources that also have
ownerReferences.blockOwnerDeletion=true
before it deletes the owner. If you
specify an orphan deletion policy, Kubernetes adds the orphan
finalizer so
that the controller ignores dependent resources after it deletes the owner
object.
What's next
9 - Recommended Labels
You can visualize and manage Kubernetes objects with more tools than kubectl and
the dashboard. A common set of labels allows tools to work interoperably, describing
objects in a common manner that all tools can understand.
In addition to supporting tooling, the recommended labels describe applications
in a way that can be queried.
The metadata is organized around the concept of an application. Kubernetes is not
a platform as a service (PaaS) and doesn't have or enforce a formal notion of an application.
Instead, applications are informal and described with metadata. The definition of
what an application contains is loose.
Note:
These are recommended labels. They make it easier to manage applications
but aren't required for any core tooling.
Shared labels and annotations share a common prefix: app.kubernetes.io
. Labels
without a prefix are private to users. The shared prefix ensures that shared labels
do not interfere with custom user labels.
Labels
In order to take full advantage of using these labels, they should be applied
on every resource object.
Key |
Description |
Example |
Type |
app.kubernetes.io/name |
The name of the application |
mysql |
string |
app.kubernetes.io/instance |
A unique name identifying the instance of an application |
mysql-abcxyz |
string |
app.kubernetes.io/version |
The current version of the application (e.g., a SemVer 1.0, revision hash, etc.) |
5.7.21 |
string |
app.kubernetes.io/component |
The component within the architecture |
database |
string |
app.kubernetes.io/part-of |
The name of a higher level application this one is part of |
wordpress |
string |
app.kubernetes.io/managed-by |
The tool being used to manage the operation of an application |
Helm |
string |
To illustrate these labels in action, consider the following StatefulSet object:
# This is an excerpt
apiVersion: apps/v1
kind: StatefulSet
metadata:
labels:
app.kubernetes.io/name: mysql
app.kubernetes.io/instance: mysql-abcxyz
app.kubernetes.io/version: "5.7.21"
app.kubernetes.io/component: database
app.kubernetes.io/part-of: wordpress
app.kubernetes.io/managed-by: Helm
Applications And Instances Of Applications
An application can be installed one or more times into a Kubernetes cluster and,
in some cases, the same namespace. For example, WordPress can be installed more
than once where different websites are different installations of WordPress.
The name of an application and the instance name are recorded separately. For
example, WordPress has a app.kubernetes.io/name
of wordpress
while it has
an instance name, represented as app.kubernetes.io/instance
with a value of
wordpress-abcxyz
. This enables the application and instance of the application
to be identifiable. Every instance of an application must have a unique name.
Examples
To illustrate different ways to use these labels the following examples have varying complexity.
A Simple Stateless Service
Consider the case for a simple stateless service deployed using Deployment
and Service
objects. The following two snippets represent how the labels could be used in their simplest form.
The Deployment
is used to oversee the pods running the application itself.
apiVersion: apps/v1
kind: Deployment
metadata:
labels:
app.kubernetes.io/name: myservice
app.kubernetes.io/instance: myservice-abcxyz
...
The Service
is used to expose the application.
apiVersion: v1
kind: Service
metadata:
labels:
app.kubernetes.io/name: myservice
app.kubernetes.io/instance: myservice-abcxyz
...
Web Application With A Database
Consider a slightly more complicated application: a web application (WordPress)
using a database (MySQL), installed using Helm. The following snippets illustrate
the start of objects used to deploy this application.
The start to the following Deployment
is used for WordPress:
apiVersion: apps/v1
kind: Deployment
metadata:
labels:
app.kubernetes.io/name: wordpress
app.kubernetes.io/instance: wordpress-abcxyz
app.kubernetes.io/version: "4.9.4"
app.kubernetes.io/managed-by: Helm
app.kubernetes.io/component: server
app.kubernetes.io/part-of: wordpress
...
The Service
is used to expose WordPress:
apiVersion: v1
kind: Service
metadata:
labels:
app.kubernetes.io/name: wordpress
app.kubernetes.io/instance: wordpress-abcxyz
app.kubernetes.io/version: "4.9.4"
app.kubernetes.io/managed-by: Helm
app.kubernetes.io/component: server
app.kubernetes.io/part-of: wordpress
...
MySQL is exposed as a StatefulSet
with metadata for both it and the larger application it belongs to:
apiVersion: apps/v1
kind: StatefulSet
metadata:
labels:
app.kubernetes.io/name: mysql
app.kubernetes.io/instance: mysql-abcxyz
app.kubernetes.io/version: "5.7.21"
app.kubernetes.io/managed-by: Helm
app.kubernetes.io/component: database
app.kubernetes.io/part-of: wordpress
...
The Service
is used to expose MySQL as part of WordPress:
apiVersion: v1
kind: Service
metadata:
labels:
app.kubernetes.io/name: mysql
app.kubernetes.io/instance: mysql-abcxyz
app.kubernetes.io/version: "5.7.21"
app.kubernetes.io/managed-by: Helm
app.kubernetes.io/component: database
app.kubernetes.io/part-of: wordpress
...
With the MySQL StatefulSet
and Service
you'll notice information about both MySQL and WordPress, the broader application, are included.