-
Promoting an existing bundle to a new channel
-
Changing the default channel of a package
-
Custom algorithms for adding, updating, and removing upgrade edges
Operator Lifecycle Manager (OLM) v1 is a Technology Preview feature only. Technology Preview features are not supported with Red Hat production service level agreements (SLAs) and might not be functionally complete. Red Hat does not recommend using them in production. These features provide early access to upcoming product features, enabling customers to test functionality and provide feedback during the development process. For more information about the support scope of Red Hat Technology Preview features, see Technology Preview Features Support Scope. |
Operator Lifecycle Manager (OLM) v1 in OpenShift Container Platform supports file-based catalogs for discovering and sourcing cluster extensions, including Operators, on a cluster.
Currently, Operator Lifecycle Manager (OLM) v1 cannot authenticate private registries, such as the Red Hat-provided Operator catalogs. This is a known issue. As a result, the OLM v1 procedures that rely on having the Red Hat Operators catalog installed do not work. (OCPBUGS-36364) |
File-based catalogs are the latest iteration of the catalog format in Operator Lifecycle Manager (OLM). It is a plain text-based (JSON or YAML) and declarative config evolution of the earlier SQLite database format, and it is fully backwards compatible. The goal of this format is to enable Operator catalog editing, composability, and extensibility.
With file-based catalogs, users interacting with the contents of a catalog are able to make direct changes to the format and verify that their changes are valid. Because this format is plain text JSON or YAML, catalog maintainers can easily manipulate catalog metadata by hand or with widely known and supported JSON or YAML tooling, such as the jq
CLI.
This editability enables the following features and user-defined extensions:
Promoting an existing bundle to a new channel
Changing the default channel of a package
Custom algorithms for adding, updating, and removing upgrade edges
File-based catalogs are stored in an arbitrary directory hierarchy, which enables catalog composition. For example, consider two separate file-based catalog directories: catalogA
and catalogB
. A catalog maintainer can create a new combined catalog by making a new directory catalogC
and copying catalogA
and catalogB
into it.
This composability enables decentralized catalogs. The format permits Operator authors to maintain Operator-specific catalogs, and it permits maintainers to trivially build a catalog composed of individual Operator catalogs. File-based catalogs can be composed by combining multiple other catalogs, by extracting subsets of one catalog, or a combination of both of these.
Duplicate packages and duplicate bundles within a package are not permitted. The |
Because Operator authors are most familiar with their Operator, its dependencies, and its upgrade compatibility, they are able to maintain their own Operator-specific catalog and have direct control over its contents. With file-based catalogs, Operator authors own the task of building and maintaining their packages in a catalog. Composite catalog maintainers, however, only own the task of curating the packages in their catalog and publishing the catalog to users.
The file-based catalog specification is a low-level representation of a catalog. While it can be maintained directly in its low-level form, catalog maintainers can build interesting extensions on top that can be used by their own custom tooling to make any number of mutations.
For example, a tool could translate a high-level API, such as (mode=semver)
, down to the low-level, file-based catalog format for upgrade edges. Or a catalog maintainer might need to customize all of the bundle metadata by adding a new property to bundles that meet a certain criteria.
While this extensibility allows for additional official tooling to be developed on top of the low-level APIs for future OpenShift Container Platform releases, the major benefit is that catalog maintainers have this capability as well.
File-based catalogs can be stored and loaded from directory-based file systems. The opm
CLI loads the catalog by walking the root directory and recursing into subdirectories. The CLI attempts to load every file it finds and fails if any errors occur.
Non-catalog files can be ignored using .indexignore
files, which have the same rules for patterns and precedence as .gitignore
files.
.indexignore
file# Ignore everything except non-object .json and .yaml files
**/*
!*.json
!*.yaml
**/objects/*.json
**/objects/*.yaml
Catalog maintainers have the flexibility to choose their desired layout, but it is recommended to store each package’s file-based catalog blobs in separate subdirectories. Each individual file can be either JSON or YAML; it is not necessary for every file in a catalog to use the same format.
catalog
├── packageA
│ └── index.yaml
├── packageB
│ ├── .indexignore
│ ├── index.yaml
│ └── objects
│ └── packageB.v0.1.0.clusterserviceversion.yaml
└── packageC
└── index.json
└── deprecations.yaml
This recommended structure has the property that each subdirectory in the directory hierarchy is a self-contained catalog, which makes catalog composition, discovery, and navigation trivial file system operations. The catalog can also be included in a parent catalog by copying it into the parent catalog’s root directory.
File-based catalogs use a format, based on the CUE language specification, that can be extended with arbitrary schemas. The following _Meta
CUE schema defines the format that all file-based catalog blobs must adhere to:
_Meta
schema_Meta: {
// schema is required and must be a non-empty string
schema: string & !=""
// package is optional, but if it's defined, it must be a non-empty string
package?: string & !=""
// properties is optional, but if it's defined, it must be a list of 0 or more properties
properties?: [... #Property]
}
#Property: {
// type is required
type: string & !=""
// value is required, and it must not be null
value: !=null
}
No CUE schemas listed in this specification should be considered exhaustive. The |
An Operator Lifecycle Manager (OLM) catalog currently uses three schemas (olm.package
, olm.channel
, and olm.bundle
), which correspond to OLM’s existing package and bundle concepts.
Each Operator package in a catalog requires exactly one olm.package
blob, at least one olm.channel
blob, and one or more olm.bundle
blobs.
All |
The olm.package
schema defines package-level metadata for an Operator. This includes its name, description, default channel, and icon.
olm.package
schema#Package: {
schema: "olm.package"
// Package name
name: string & !=""
// A description of the package
description?: string
// The package's default channel
defaultChannel: string & !=""
// An optional icon
icon?: {
base64data: string
mediatype: string
}
}
The olm.channel
schema defines a channel within a package, the bundle entries that are members of the channel, and the upgrade edges for those bundles.
If a bundle entry represents an edge in multiple olm.channel
blobs, it can only appear once per channel.
It is valid for an entry’s replaces
value to reference another bundle name that cannot be found in this catalog or another catalog. However, all other channel invariants must hold true, such as a channel not having multiple heads.
olm.channel
schema#Channel: {
schema: "olm.channel"
package: string & !=""
name: string & !=""
entries: [...#ChannelEntry]
}
#ChannelEntry: {
// name is required. It is the name of an `olm.bundle` that
// is present in the channel.
name: string & !=""
// replaces is optional. It is the name of bundle that is replaced
// by this entry. It does not have to be present in the entry list.
replaces?: string & !=""
// skips is optional. It is a list of bundle names that are skipped by
// this entry. The skipped bundles do not have to be present in the
// entry list.
skips?: [...string & !=""]
// skipRange is optional. It is the semver range of bundle versions
// that are skipped by this entry.
skipRange?: string & !=""
}
When using the You can update an Operator incrementally while keeping previously installed versions available to users for future installation by using both the |
olm.bundle
schema#Bundle: {
schema: "olm.bundle"
package: string & !=""
name: string & !=""
image: string & !=""
properties: [...#Property]
relatedImages?: [...#RelatedImage]
}
#Property: {
// type is required
type: string & !=""
// value is required, and it must not be null
value: !=null
}
#RelatedImage: {
// image is the image reference
image: string & !=""
// name is an optional descriptive name for an image that
// helps identify its purpose in the context of the bundle
name?: string & !=""
}
The optional olm.deprecations
schema defines deprecation information for packages, bundles, and channels in a catalog. Operator authors can use this schema to provide relevant messages about their Operators, such as support status and recommended upgrade paths, to users running those Operators from a catalog.
When this schema is defined, the OpenShift Container Platform web console displays warning badges for the affected elements of the Operator, including any custom deprecation messages, on both the pre- and post-installation pages of the OperatorHub.
An olm.deprecations
schema entry contains one or more of the following reference
types, which indicates the deprecation scope. After the Operator is installed, any specified messages can be viewed as status conditions on the related Subscription
object.
Type | Scope | Status condition |
---|---|---|
|
Represents the entire package |
|
|
Represents one channel |
|
|
Represents one bundle version |
|
Each reference
type has their own requirements, as detailed in the following example.
olm.deprecations
schema with each reference
typeschema: olm.deprecations
package: my-operator (1)
entries:
- reference:
schema: olm.package (2)
message: | (3)
The 'my-operator' package is end of life. Please use the
'my-operator-new' package for support.
- reference:
schema: olm.channel
name: alpha (4)
message: |
The 'alpha' channel is no longer supported. Please switch to the
'stable' channel.
- reference:
schema: olm.bundle
name: my-operator.v1.68.0 (5)
message: |
my-operator.v1.68.0 is deprecated. Uninstall my-operator.v1.68.0 and
install my-operator.v1.72.0 for support.
1 | Each deprecation schema must have a package value, and that package reference must be unique across the catalog. There must not be an associated name field. |
2 | The olm.package schema must not include a name field, because it is determined by the package field defined earlier in the schema. |
3 | All message fields, for any reference type, must be a non-zero length and represented as an opaque text blob. |
4 | The name field for the olm.channel schema is required. |
5 | The name field for the olm.bundle schema is required. |
The deprecation feature does not consider overlapping deprecation, for example package versus channel versus bundle. |
Operator authors can save olm.deprecations
schema entries as a deprecations.yaml
file in the same directory as the package’s index.yaml
file:
my-catalog
└── my-operator
├── index.yaml
└── deprecations.yaml
Properties are arbitrary pieces of metadata that can be attached to file-based catalog schemas. The type
field is a string that effectively specifies the semantic and syntactic meaning of the value
field. The value can be any arbitrary JSON or YAML.
OLM defines a handful of property types, again using the reserved olm.*
prefix.
The olm.package
property defines the package name and version. This is a required property on bundles, and there must be exactly one of these properties. The packageName
field must match the bundle’s first-class package
field, and the version
field must be a valid semantic version.
olm.package
property#PropertyPackage: {
type: "olm.package"
value: {
packageName: string & !=""
version: string & !=""
}
}
The olm.gvk
property defines the group/version/kind (GVK) of a Kubernetes API that is provided by this bundle. This property is used by OLM to resolve a bundle with this property as a dependency for other bundles that list the same GVK as a required API. The GVK must adhere to Kubernetes GVK validations.
olm.gvk
property#PropertyGVK: {
type: "olm.gvk"
value: {
group: string & !=""
version: string & !=""
kind: string & !=""
}
}
The olm.package.required
property defines the package name and version range of another package that this bundle requires. For every required package property a bundle lists, OLM ensures there is an Operator installed on the cluster for the listed package and in the required version range. The versionRange
field must be a valid semantic version (semver) range.
olm.package.required
property#PropertyPackageRequired: {
type: "olm.package.required"
value: {
packageName: string & !=""
versionRange: string & !=""
}
}
The olm.gvk.required
property defines the group/version/kind (GVK) of a Kubernetes API that this bundle requires. For every required GVK property a bundle lists, OLM ensures there is an Operator installed on the cluster that provides it. The GVK must adhere to Kubernetes GVK validations.
olm.gvk.required
property#PropertyGVKRequired: {
type: "olm.gvk.required"
value: {
group: string & !=""
version: string & !=""
kind: string & !=""
}
}
With file-based catalogs, catalog maintainers can focus on Operator curation and compatibility. Because Operator authors have already produced Operator-specific catalogs for their Operators, catalog maintainers can build their catalog by rendering each Operator catalog into a subdirectory of the catalog’s root directory.
There are many possible ways to build a file-based catalog; the following steps outline a simple approach:
Maintain a single configuration file for the catalog, containing image references for each Operator in the catalog:
name: community-operators
repo: quay.io/community-operators/catalog
tag: latest
references:
- name: etcd-operator
image: quay.io/etcd-operator/index@sha256:5891b5b522d5df086d0ff0b110fbd9d21bb4fc7163af34d08286a2e846f6be03
- name: prometheus-operator
image: quay.io/prometheus-operator/index@sha256:e258d248fda94c63753607f7c4494ee0fcbe92f1a76bfdac795c9d84101eb317
Run a script that parses the configuration file and creates a new catalog from its references:
name=$(yq eval '.name' catalog.yaml)
mkdir "$name"
yq eval '.name + "/" + .references[].name' catalog.yaml | xargs mkdir
for l in $(yq e '.name as $catalog | .references[] | .image + "|" + $catalog + "/" + .name + "/index.yaml"' catalog.yaml); do
image=$(echo $l | cut -d'|' -f1)
file=$(echo $l | cut -d'|' -f2)
opm render "$image" > "$file"
done
opm generate dockerfile "$name"
indexImage=$(yq eval '.repo + ":" + .tag' catalog.yaml)
docker build -t "$indexImage" -f "$name.Dockerfile" .
docker push "$indexImage"
Consider the following guidelines when maintaining file-based catalogs.
The general advice with Operator Lifecycle Manager (OLM) is that bundle images and their metadata should be treated as immutable.
If a broken bundle has been pushed to a catalog, you must assume that at least one of your users has upgraded to that bundle. Based on that assumption, you must release another bundle with an upgrade edge from the broken bundle to ensure users with the broken bundle installed receive an upgrade. OLM will not reinstall an installed bundle if the contents of that bundle are updated in the catalog.
However, there are some cases where a change in the catalog metadata is preferred:
Channel promotion: If you already released a bundle and later decide that you would like to add it to another channel, you can add an entry for your bundle in another olm.channel
blob.
New upgrade edges: If you release a new 1.2.z
bundle version, for example 1.2.4
, but 1.3.0
is already released, you can update the catalog metadata for 1.3.0
to skip 1.2.4
.
Catalog metadata should be stored in source control and treated as the source of truth. Updates to catalog images should include the following steps:
Update the source-controlled catalog directory with a new commit.
Build and push the catalog image. Use a consistent tagging taxonomy, such as :latest
or :<target_cluster_version>
, so that users can receive updates to a catalog as they become available.
For instructions about creating file-based catalogs by using the opm
CLI, see Managing custom catalogs.
For reference documentation about the opm
CLI commands related to managing file-based catalogs, see CLI tools.
Operator authors and catalog maintainers are encouraged to automate their catalog maintenance with CI/CD workflows. Catalog maintainers can further improve on this by building GitOps automation to accomplish the following tasks:
Check that pull request (PR) authors are permitted to make the requested changes, for example by updating their package’s image reference.
Check that the catalog updates pass the opm validate
command.
Check that the updated bundle or catalog image references exist, the catalog images run successfully in a cluster, and Operators from that package can be successfully installed.
Automatically merge PRs that pass the previous checks.
Automatically rebuild and republish the catalog image.