If you are using a released version of Kubernetes, you should refer to the docs that go with that version.
The latest release of this document can be found [here](http://releases.k8s.io/release-1.3/docs/design/extending-api.md).Documentation for other releases can be found at releases.k8s.io.
This document describes the design for implementing the storage of custom API types in the Kubernetes API Server.
The ThirdPartyResource
resource describes the multiple versions of a custom
resource that the user wants to add to the Kubernetes API. ThirdPartyResource
is a non-namespaced resource; attempting to place it in a namespace will return
an error.
Each ThirdPartyResource
resource has the following:
- Standard Kubernetes object metadata.
- ResourceKind - The kind of the resources described by this third party resource.
- Description - A free text description of the resource.
- APIGroup - An API group that this resource should be placed into.
- Versions - One or more
Version
objects.
The Version
object describes a single concrete version of a custom resource.
The Version
object currently only specifies:
- The
Name
of the version. - The
APIGroup
this version should belong to.
Every object that is added to a third-party Kubernetes object store is expected to contain Kubernetes compatible object metadata. This requirement enables the Kubernetes API server to provide the following features:
- Filtering lists of objects via label queries.
resourceVersion
-based optimistic concurrency via compare-and-swap.- Versioned storage.
- Event recording.
- Integration with basic
kubectl
command line tooling. - Watch for resource changes.
The Kind
for an instance of a third-party object (e.g. CronTab) below is
expected to be programmatically convertible to the name of the resource using
the following conversion. Kinds are expected to be of the form
<CamelCaseKind>
, and the APIVersion
for the object is expected to be
<api-group>/<api-version>
. To prevent collisions, it's expected that you'll
use a fully qualified domain name for the API group, e.g. example.com
.
For example stable.example.com/v1
'CamelCaseKind' is the specific type name.
To convert this into the metadata.name
for the ThirdPartyResource
resource
instance, the <domain-name>
is copied verbatim, the CamelCaseKind
is then
converted using '-' instead of capitalization ('camel-case'), with the first
character being assumed to be capitalized. In pseudo code:
var result string
for ix := range kindName {
if isCapital(kindName[ix]) {
result = append(result, '-')
}
result = append(result, toLowerCase(kindName[ix])
}
As a concrete example, the resource named camel-case-kind.example.com
defines
resources of Kind CamelCaseKind
, in the APIGroup with the prefix
example.com/...
.
The reason for this is to enable rapid lookup of a ThirdPartyResource
object
given the kind information. This is also the reason why ThirdPartyResource
is
not namespaced.
When a user creates a new ThirdPartyResource
, the Kubernetes API Server reacts
by creating a new, namespaced RESTful resource path. For now, non-namespaced
objects are not supported. As with existing built-in objects, deleting a
namespace deletes all third party resources in that namespace.
For example, if a user creates:
metadata:
name: cron-tab.stable.example.com
apiVersion: extensions/v1beta1
kind: ThirdPartyResource
description: "A specification of a Pod to run on a cron style schedule"
versions:
- name: v1
- name: v2
Then the API server will program in the new RESTful resource path:
/apis/stable.example.com/v1/namespaces/<namespace>/crontabs/...
Now that this schema has been created, a user can POST
:
{
"metadata": {
"name": "my-new-cron-object"
},
"apiVersion": "stable.example.com/v1",
"kind": "CronTab",
"cronSpec": "* * * * /5",
"image": "my-awesome-cron-image"
}
to: /apis/stable.example.com/v1/namespaces/default/crontabs
and the corresponding data will be stored into etcd by the APIServer, so that when the user issues:
GET /apis/stable.example.com/v1/namespaces/default/crontabs/my-new-cron-object`
And when they do that, they will get back the same data, but with additional
Kubernetes metadata (e.g. resourceVersion
, createdTimestamp
) filled in.
Likewise, to list all resources, a user can issue:
GET /apis/stable.example.com/v1/namespaces/default/crontabs
and get back:
{
"apiVersion": "stable.example.com/v1",
"kind": "CronTabList",
"items": [
{
"metadata": {
"name": "my-new-cron-object"
},
"apiVersion": "stable.example.com/v1",
"kind": "CronTab",
"cronSpec": "* * * * /5",
"image": "my-awesome-cron-image"
}
]
}
Because all objects are expected to contain standard Kubernetes metadata fields, these list operations can also use label queries to filter requests down to specific subsets.
Likewise, clients can use watch endpoints to watch for changes to stored objects.
In order to store custom user data in a versioned fashion inside of etcd, we
need to also introduce a Codec
-compatible object for persistent storage in
etcd. This object is ThirdPartyResourceData
and it contains:
- Standard API Metadata.
Data
: The raw JSON data for this custom object.
Each custom object stored by the API server needs a custom key in storage, this is described below:
resource-namespace
: the namespace of the particular resource that is being storedresource-name
: the name of the particular resource being storedthird-party-resource-namespace
: the namespace of theThirdPartyResource
resource that represents the type for the specific instance being storedthird-party-resource-name
: the name of theThirdPartyResource
resource that represents the type for the specific instance being stored
Given the definitions above, the key for a specific third-party object is:
${standard-k8s-prefix}/third-party-resources/${third-party-resource-namespace}/${third-party-resource-name}/${resource-namespace}/${resource-name}
Thus, listing a third-party resource can be achieved by listing the directory:
${standard-k8s-prefix}/third-party-resources/${third-party-resource-namespace}/${third-party-resource-name}/${resource-namespace}/