---
title: CAPI Provider Operator
authors:
- "@fabriziopandini"
- "@wfernandes"
reviewers:
- "@vincepri"
- "@ncdc"
- "@justinsb"
- "@detiber"
- "@CecileRobertMichon"
creation-date: 2020-09-14
last-updated: 2021-01-20
status: implementable
see-also:
https://github.com/kubernetes-sigs/cluster-api/blob/main/docs/proposals/20191016-clusterctl-redesign.md
---
- Glossary
- Summary
- Motivation
- Proposal
- Additional Details
- Implementation History
- Controller Runtime Types
The lexicon used in this document is described in more detail here. Any discrepancies should be rectified in the main Cluster API glossary.
The clusterctl CLI currently handles the lifecycle of Cluster API providers installed in a management cluster. It provides a great Day 0 and Day 1 experience in getting CAPI up and running. However, clusterctl’s imperative design makes it difficult for cluster admins to stand up and manage CAPI management clusters in their own preferred way.
This proposal provides a solution that leverages a declarative API and an operator to empower admins to handle the lifecycle of providers within the management cluster.
The operator is developed in a separate repository [TBD] and will have its own release cycle.
In its current form clusterctl is designed to provide a simple user experience for day 1 operations of a Cluster API management cluster.
However such design is not optimized for supporting declarative approaches when operating Cluster API management clusters.
These declarative approaches are important to enable GitOps workflows in case
users don't want to rely solely on the clusterctl
CLI.
Providing a declarative API also enables us to leverage controller-runtime's new component config and allow us to configure the controller manager and even the resource limits of the provider's deployment.
Another example is improving cluster upgrades. In order to upgrade a cluster
we now need to supply all the information that was provided initially during a
clusterctl init
which is inconvenient in many cases such as distributed
teams and CI pipelines where the configuration needs to be stored and synced
externally.
With the management cluster operator, we aim to address these use cases by introducing an operator that handles the lifecycle of providers within the management cluster based on a declarative API.
- Define an API that enables declarative management of the lifecycle of Cluster API and all of its providers.
- Support air-gapped environments through sufficient documentation initially.
- Identify and document differences between clusterctl CLI and the operator in managing the lifecycle of providers, if any.
- Define how the clusterctl CLI should be changed in order to interact with the management cluster operator in a transparent and effective way.
- To support the ability to upgrade from a v1alpha3 based version (v0.3.[TBD]) of Cluster API to one managed by the operator.
clusterctl
related changes will be implemented after core operator functionality is complete. For example, deprecatingProvider
type and migrating to new ones.clusterctl
will not be deprecated or replaced with another CLI.- Implement an operator driven version of
clusterctl move
. - Manage cert-manager using the operator.
- Support multiple installations of the same provider within a management cluster in light of issue 3042 and issue 3354.
- Support any template processing engines.
- Support the installation of v1alpha3 providers using the operator.
- As an admin, I want to use a declarative style API to operate the Cluster API providers in a management cluster.
- As an admin, I would like to have an easy and declarative way to change controller settings (e.g. enabling pprof for debugging).
- As an admin, I would like to have an easy and declarative way to change the resource requirements (e.g. such as limits and requests for a provider deployment).
- As an admin, I would like to have the option to use clusterctl CLI as of today, without being concerned about the operator.
- As an admin, I would like to be able to install the operator using kubectl apply, without being forced to use clusterctl.
The clusterctl
CLI will provide a similar UX to the users whilst leveraging
the operator for the functions it can. As stated in the Goals/Non-Goals, the
move operation will not be driven by the operator but rather remain within the
CLI for now. However, this is an implementation detail and will not affect the
users. The move operation and all other clusterctl
refactoring will be
done after core operator functionality is implemented.
The existing Provider
type used by the clusterctl CLI will be deprecated and
its instances will be migrated to instances of the new API types as defined in
the next section.
The management cluster operator will be responsible for migrating the existing
provider types to support GitOps workflows excluding clusterctl
.
These are the new API types being defined.
There are separate types for each provider type - Core, Bootstrap,
ControlPlane, and Infrastructure. However, since each type is similar, their
Spec and Status uses the shared types - ProviderSpec
, ProviderStatus
respectively.
We will scope the CRDs to be namespaced. This will allow us to enforce RBAC restrictions if needed. This also allows us to install multiple versions of the controllers (grouped within namespaces) in the same management cluster although this scenario will not be supported natively in the v1alpha4 iteration.
If you prefer to see how the API can be used instead of reading the type definition feel free to jump to the Example API Usage section
// CoreProvider is the Schema for the CoreProviders API
type CoreProvider struct {
metav1.TypeMeta `json:",inline"`
metav1.ObjectMeta `json:"metadata,omitempty"`
Spec ProviderSpec `json:"spec,omitempty"`
Status ProviderStatus `json:"status,omitempty"`
}
// BootstrapProvider is the Schema for the BootstrapProviders API
type BootstrapProvider struct {
metav1.TypeMeta `json:",inline"`
metav1.ObjectMeta `json:"metadata,omitempty"`
Spec ProviderSpec `json:"spec,omitempty"`
Status ProviderStatus `json:"status,omitempty"`
}
// ControlPlaneProvider is the Schema for the ControlPlaneProviders API
type ControlPlaneProvider struct {
metav1.TypeMeta `json:",inline"`
metav1.ObjectMeta `json:"metadata,omitempty"`
Spec ProviderSpec `json:"spec,omitempty"`
Status ProviderStatus `json:"status,omitempty"`
}
// InfrastructureProvider is the Schema for the InfrastructureProviders API
type InfrastructureProvider struct {
metav1.TypeMeta `json:",inline"`
metav1.ObjectMeta `json:"metadata,omitempty"`
Spec ProviderSpec `json:"spec,omitempty"`
Status ProviderStatus `json:"status,omitempty"`
}
Below you can find details about ProviderSpec
, ProviderStatus
, which is
shared among all the provider types - Core, Bootstrap, ControlPlane, and
Infrastructure.
// ProviderSpec defines the desired state of the Provider.
type ProviderSpec struct {
// Version indicates the provider version.
// +optional
Version *string `json:"version,omitempty"`
// Manager defines the properties that can be enabled on the controller manager for the provider.
// +optional
Manager ManagerSpec `json:"manager,omitempty"`
// Deployment defines the properties that can be enabled on the deployment for the provider.
// +optional
Deployment *DeploymentSpec `json:"deployment,omitempty"`
// SecretName is the name of the Secret providing the configuration
// variables for the current provider instance, like e.g. credentials.
// Such configurations will be used when creating or upgrading provider components.
// The contents of the secret will be treated as immutable. If changes need
// to be made, a new object can be created and the name should be updated.
// The contents should be in the form of key:value. This secret must be in
// the same namespace as the provider.
// +optional
SecretName *string `json:"secretName,omitempty"`
// FetchConfig determines how the operator will fetch the components and metadata for the provider.
// If nil, the operator will try to fetch components according to default
// embedded fetch configuration for the given kind and `ObjectMeta.Name`.
// For example, the infrastructure name `aws` will fetch artifacts from
// https://github.com/kubernetes-sigs/cluster-api-provider-aws/releases.
// +optional
FetchConfig *FetchConfiguration `json:"fetchConfig,omitempty"`
// Paused prevents the operator from reconciling the provider. This can be
// used when doing an upgrade or move action manually.
// +optional
Paused bool `json:"paused,omitempty"`
}
// ManagerSpec defines the properties that can be enabled on the controller manager for the provider.
type ManagerSpec struct {
// ControllerManagerConfigurationSpec defines the desired state of GenericControllerManagerConfiguration.
ctrlruntime.ControllerManagerConfigurationSpec `json:",inline"`
// ProfilerAddress defines the bind address to expose the pprof profiler (e.g. localhost:6060).
// Default empty, meaning the profiler is disabled.
// Controller Manager flag is --profiler-address.
// +optional
ProfilerAddress *string `json:"profilerAddress,omitempty"`
// MaxConcurrentReconciles is the maximum number of concurrent Reconciles
// which can be run. Defaults to 10.
// +optional
MaxConcurrentReconciles *int `json:"maxConcurrentReconciles,omitempty"`
// Verbosity set the logs verbosity. Defaults to 1.
// Controller Manager flag is --verbosity.
// +optional
Verbosity int `json:"verbosity,omitempty"`
// Debug, if set, will override a set of fields with opinionated values for
// a debugging session. (Verbosity=5, ProfilerAddress=localhost:6060)
// +optional
Debug bool `json:"debug,omitempty"`
// FeatureGates define provider specific feature flags that will be passed
// in as container args to the provider's controller manager.
// Controller Manager flag is --feature-gates.
FeatureGates map[string]bool `json:"featureGates,omitempty"`
}
// DeploymentSpec defines the properties that can be enabled on the Deployment for the provider.
type DeploymentSpec struct {
// Number of desired pods. This is a pointer to distinguish between explicit zero and not specified. Defaults to 1.
// +optional
Replicas *int `json:"replicas,omitempty"`
// NodeSelector is a selector which must be true for the pod to fit on a node.
// Selector which must match a node's labels for the pod to be scheduled on that node.
// More info: https://kubernetes.io/docs/concepts/configuration/assign-pod-node/
// +optional
NodeSelector map[string]string `json:"nodeSelector,omitempty"`
// If specified, the pod's tolerations.
// +optional
Tolerations []corev1.Toleration `json:"tolerations,omitempty"`
// If specified, the pod's scheduling constraints
// +optional
Affinity *corev1.Affinity `json:"affinity,omitempty"`
// List of containers specified in the Deployment
// +optional
Containers []ContainerSpec `json:"containers"`
}
// ContainerSpec defines the properties available to override for each
// container in a provider deployment such as Image and Args to the container’s
// entrypoint.
type ContainerSpec struct {
// Name of the container. Cannot be updated.
Name string `json:"name"`
// Container Image Name
// +optional
Image *ImageMeta `json:"image,omitempty"`
// Args represents extra provider specific flags that are not encoded as fields in this API.
// Explicit controller manager properties defined in the `Provider.ManagerSpec`
// will have higher precedence than those defined in `ContainerSpec.Args`.
// For example, `ManagerSpec.SyncPeriod` will be used instead of the
// container arg `--sync-period` if both are defined.
// The same holds for `ManagerSpec.FeatureGates` and `--feature-gates`.
// +optional
Args map[string]string `json:"args,omitempty"`
// List of environment variables to set in the container.
// +optional
Env []corev1.EnvVar `json:"env,omitempty"`
// Compute resources required by this container.
// +optional
Resources *corev1.ResourceRequirements `json:"resources,omitempty"`
}
// ImageMeta allows to customize the image used
type ImageMeta struct {
// Repository sets the container registry to pull images from.
// +optional
Repository *string `json:"repository,omitempty`
// Name allows to specify a name for the image.
// +optional
Name *string `json:"name,omitempty`
// Tag allows to specify a tag for the image.
// +optional
Tag *string `json:"tag,omitempty`
}
// FetchConfiguration determines the way to fetch the components and metadata for the provider.
type FetchConfiguration struct {
// URL to be used for fetching the provider’s components and metadata from a remote Github repository.
// For example, https://github.com/{owner}/{repository}/releases
// The version of the release will be `ProviderSpec.Version` if defined
// otherwise the `latest` version will be computed and used.
// +optional
URL *string `json:"url,omitempty"`
// Selector to be used for fetching provider’s components and metadata from
// ConfigMaps stored inside the cluster. Each ConfigMap is expected to contain
// components and metadata for a specific version only.
// +optional
Selector *metav1.LabelSelector `json:"selector,omitempty"`
}
// ProviderStatus defines the observed state of the Provider.
type ProviderStatus struct {
// Contract will contain the core provider contract that the provider is
// abiding by, like e.g. v1alpha3.
// +optional
Contract *string `json:"contract,omitempty"`
// Conditions define the current service state of the cluster.
// +optional
Conditions Conditions `json:"conditions,omitempty"`
// ObservedGeneration is the latest generation observed by the controller.
// +optional
ObservedGeneration int64 `json:"observedGeneration,omitempty"`
}
Validation and defaulting rules for Provider and ProviderSpec
- The
Name
field withinmetav1.ObjectMeta
could be any valid Kubernetes name; however, it is recommended to use Cluster API provider names. For example, aws, vsphere, kubeadm. These names will be used to fetch the default configurations in case there is no specific FetchConfiguration defined. ProviderSpec.Version
should be a valid default version with the "v" prefix as commonly used in the Kubernetes ecosystem; if this value is nil when a new provider is created, the operator will determine the version to use applying the same rules implemented in clusterctl (latest). Once the latest version is calculated it will be set inProviderSpec.Version
.- Note: As per discussion in the CAEP PR, we will keep the
SecretName
field to allow the provider authors ample time to implement their own credential management to support multiple workload clusters. [See this thread for more info][secret-name-discussion].
Validation rules for ProviderSpec.FetchConfiguration
- If the FetchConfiguration is empty and not defined, then the operator will
apply the embedded fetch configuration for the given kind and
ObjectMeta.Name
. For example, the infrastructure nameaws
will fetch artifacts from https://github.com/kubernetes-sigs/cluster-api-provider-aws/releases. - If FetchConfiguration is not nil, exactly one of
URL
orSelector
must be specified. FetchConfiguration.Selector
is used to fetch provider’s components and metadata from ConfigMaps stored inside the cluster. Each ConfigMap is expected to contain components and metadata for a specific version only. So if multiple versions of the providers need to be specified, they can be added as separate ConfigMaps and labeled with the same selector. This provides the same behavior as the “local” provider repositories but now from within the management cluster.FetchConfiguration
is used only during init and upgrade operations. Changes made to the contents ofFetchConfiguration
will not trigger a reconciliation. This is similar behavior toProviderSpec.SecretName
.
Validation Rules for ProviderSpec.ManagerSpec
- The ControllerManagerConfigurationSpec is a type from
controller-runtime/pkg/config
and is an embedded into theManagerSpec
. This type will expose LeaderElection, SyncPeriod, Webhook, Health and Metrics configurations. - If
ManagerSpec.Debug
is set to true, the operator will not allow changes to other properties since it is in Debug mode. - If you need to set specific concurrency values for each reconcile loop (e.g.
awscluster-concurrency
), you can leaveManagerSpec.MaxConcurrentReconciles
nil and useContainer.Args
. - If
ManagerSpec.MaxConcurrentReconciles
is set and a specific concurrency flag such asawscluster-concurrency
is set on theContainer.Args
, then the more specific concurrency flag will have higher precedence.
Validation Rules for ContainerSpec
- The
ContainerSpec.Args
will ignore the keynamespace
since the operator enforces a deployment model where all the providers should be configured to watch all the namespaces. - Explicit controller manager properties defined in the
Provider.ManagerSpec
will have higher precedence than those defined inContainerSpec.Args
. That is, ifManagerSpec.SyncPeriod
is defined it will be used instead of the container argsync-period
. This is true also forManagerSpec.FeatureGates
, that is, it will have higher precedence to the container argfeature-gates
. - If no
ContainerSpec.Resources
are defined, the defaults on the Deployment object within the provider’s components yaml will be used.
- As an admin, I want to install the aws infrastructure provider with specific controller flags.
apiVersion: v1
kind: Secret
metadata:
name: aws-variables
namespace: capa-system
type: Opaque
data:
AWS_REGION: ...
AWS_ACCESS_KEY_ID: ...
AWS_SECRET_ACCESS_KEY: ...
---
apiVersion: management.cluster.x-k8s.io/v1alpha1
kind: InfrastructureProvider
metadata:
name: aws
namespace: capa-system
spec:
version: v0.6.0
secretName: aws-variables
manager:
# These top level controller manager flags, supported by all the providers.
# These flags come with sensible defaults, thus requiring no or minimal
# changes for the most common scenarios.
metricsAddress: ":8181"
syncPeriod: 660
fetchConfig:
url: https://github.com/kubernetes-sigs/cluster-api-provider-aws/releases
deployment:
containers:
- name: manager
args:
# These are controller flags that are specific to a provider; usage
# is reserved for advanced scenarios only.
awscluster-concurrency: 12
awsmachine-concurrency: 11
- As an admin, I want to install aws infrastructure provider but override the container image of the CAPA deployment.
---
apiVersion: management.cluster.x-k8s.io/v1alpha1
kind: InfrastructureProvider
metadata:
name: aws
namespace: capa-system
spec:
version: v0.6.0
secretName: aws-variables
deployment:
containers:
- name: manager
image: gcr.io/myregistry/capa-controller:v0.6.0-foo
- As an admin, I want to change the resource limits for the manager pod in my control plane provider deployment.
---
apiVersion: management.cluster.x-k8s.io/v1alpha1
kind: ControlPlaneProvider
metadata:
name: kubeadm
namespace: capi-kubeadm-control-plane-system
spec:
version: v0.3.10
secretName: capi-variables
deployment:
containers:
- name: manager
resources:
limits:
cpu: 100m
memory: 30Mi
requests:
cpu: 100m
memory: 20Mi
- As an admin, I would like to fetch my azure provider components from a specific repository which is not the default.
---
apiVersion: management.cluster.x-k8s.io/v1alpha1
kind: InfrastructureProvider
metadata:
name: myazure
namespace: capz-system
spec:
version: v0.4.9
secretName: azure-variables
fetchConfig:
url: https://github.com/myorg/awesome-azure-provider/releases
- As an admin, I would like to use the default fetch configurations by
simply specifying the expected Cluster API provider names such as 'aws',
'vsphere', 'azure', 'kubeadm', 'talos', or 'cluster-api' instead of having
to explicitly specify the fetch configuration.
In the example below, since we are using 'vsphere' as the name of the
InfrastructureProvider the operator will fetch it's configuration from
url: https://github.com/kubernetes-sigs/cluster-api-provider-vsphere/releases
by default.
See more examples in the air-gapped environment section
---
apiVersion: management.cluster.x-k8s.io/v1alpha1
kind: InfrastructureProvider
metadata:
name: vsphere
namespace: capv-system
spec:
version: v0.4.9
secretName: vsphere-variables
In order to install a new Cluster API provider with the management cluster operator you have to create a provider as shown above. See the first example API usage to create the secret with variables and the provider itself.
When processing a Provider object the operator will apply the following rules.
- Providers with
spec.Type == CoreProvider
will be installed first; the other providers will be requeued until the core provider exists. - Before installing any provider following preflight checks will be executed :
- There should not be another instance of the same provider (same Kind, same name) in any namespace.
- The Cluster API contract the provider is abiding by, e.g. v1alpha4, must match the contract of the core provider.
- The operator will set conditions on the Provider object to surface any installation issues such as pre-flight checks and/or order of installation to accurately inform the user.
- Since the FetchConfiguration is empty and not defined, the operator will
apply the embedded fetch configuration for the given kind and
ObjectMeta.Name
. In this case, the operator will fetch artifacts from https://github.com/kubernetes-sigs/cluster-api-provider-aws/releases.
The installation process managed by the operator is consistent with the
implementation underlying the clusterctl init
command and includes the
following steps:
- Fetching the provider artifacts (the components yaml and the metadata.yaml file).
- Applying image overrides, if any.
- Replacing variables in the infrastructure-components from EnvVar and Secret.
- Applying the resulting yaml to the cluster.
As a final consideration, please note that
- The operator executes installation for 1 provider at time, while
clusterctl init
manages installation of a group of providers with a single operation. clusterctl init
uses environment variables and a local configuration file, while the operator uses a Secret; given that we want the users to preserve current behaviour in clusterctl, the init operation should be modified to transfer local configuration to the cluster. As part ofclusterctl init
, it will obtain the list of variables required by the provider components and read the corresponding values from the config or environment variables and build the secret. Any image overrides defined in the clusterctl config will also be applied to the provider's components.
In the following figure, the controllers for the providers are installed in the namespaces that are defined by default.
In the following figure, the controllers for the providers are all installed in the same namespace as configured by the user.
In order to trigger an upgrade of a new Cluster API provider you have to
change the spec.Version
field.
Upgrading a provider in the management cluster must abide by the golden rule that all the providers should respect the same Cluster API contract supported by the core provider.
If the new version of the provider does abide by the same version of the Cluster API contract, the operator will execute the upgrade by performing:
- Delete of the current instance of the provider components, while preserving CRDs, namespace and user objects.
- Install the new version of the provider components
Please note that:
- The operator executes upgrades 1 provider at time, while
clusterctl upgrade apply
manages upgrading a group of providers with a single operation. clusterctl upgrade apply --contract
automatically determines the latest versions available for each provider, while with the Declarative approach the user is responsible for manually editing Provider objects yaml.clusterctl upgrade apply
currently uses environment variables and a local configuration file; this should be changed in order to use in cluster provider configurations.
If the new version of the provider does abide by a new version of the Cluster API contract, it is required to ensure all the other providers in the management cluster should get the new version too.
As a first step, it is required to pause all the providers by setting the
spec.Paused
field to true for each provider; the operator will block any
contract upgrade until all the providers are paused.
After all the providers are in paused state, you can proceed with the upgrade
as described in the previous paragraph (change the spec.Version
field).
When a provider is paused the number of replicas will be scaled to 0; the
operator will add a new
management.cluster.x-k8s.io/original-controller-replicas
annotation to store
the original replica count.
Once all the providers are upgraded to a version that abides to the new contract, it is possible for the operator to unpause providers; the operator does not allow to unpause providers if there are still providers abiding to the old contract.
Please note that we are planning to embed this sequence (pause - upgrade -
unpause) as a part of clusterctl upgrade apply
command when there is a
contract change.
On top of changing a provider version (upgrades), the operator supports also
changing other provider fields, most notably controller flags and variables.
This can be achieved by either kubectl edit
or kubectl apply
to the
provider object.
The operation internally works like upgrades: The current instance of the provider is deleted, while preserving CRDs, namespaced and user objects A new instance of the provider is installed with the new set of flags/variables.
Please note that clusterctl currently does not support this operation.
See Example 1 in Example API Usage
In order to delete a provider you have to delete the corresponding provider object.
Deletion of the provider will be blocked if any workload cluster using the provider still exists.
Additionally, deletion of a core provider should be blocked if there are still other providers in the management cluster.
Cluster API will provide instructions on how to upgrade from a v1alpha3 management cluster, created by clusterctl to the new v1alpha4 management cluster. These operations could require manual actions.
Some of the actions are described below:
- Run webhooks as part of the main manager. See [issue 3822].
More details will be added as we better understand what a v1alpha4 cluster will look like.
- During the first phase of implementation
clusterctl
won't provide support for managing the operator, so the admin will have to install it manually usingkubectl apply
(or similar solutions), the operator yaml that will be published in the operator subproject release artifacts. - In future
clusterctl init
will install the operator and its corresponding CRDs as a pre-requisite if the operator doesn’t already exist. Please note that this command will consider image overrides defined in the local clusterctl config file.
- During the first phase of implementation
clusterctl
operations will not be supported and admin will have to install the operator manually, or in case if the admin doesn’t want to use clusterctl, they can usekubectl apply
(or similar solutions) with the latest version of the operator yaml that will be published in the operator subproject release artifacts. - The transition between manually managed operator and clusterctl managed operator will be documented later as we progress with the implementation.
- In future the admin will be able to use
clusterctl upgrade operator
to upgrade the operator components. Please note that this command will consider image overrides defined in the local clusterctl config file. Other commands such asclusterctl upgrade apply
will also allow to upgrade the operator. clusterctl upgrade plan
will identify when the operator can be upgraded by checking the cluster-api release artifacts.- clusterctl will require a matching operator version. In the future, when clusterctl move to beta/GA, we will reconsider supporting version skew between clusterctl and the operator.
- During the first phase of implementation
clusterctl
operations will not be supported and admin will have to delete the operator manually usingkubectl delete
(or similar solutions). However, it’s the admin’s responsibility to verify that there are no providers running in the management cluster. - In future the clusterctl will delete the operator as part of
the
clusterctl delete --all
command.
In order to install Cluster API providers in an air-gapped environment using the operator, it is required to address the following issues.
- Make the operator work in air-gapped environment
- To provide image overrides for the operator itself in order to pull the images from an accessible image repository. Please note that the overrides will be considered from the image overrides defined in the local clusterctl config file.
- TBD if operator yaml will be embedded in clusterctl or if it should be a special artifact within the core provider repository.
- Make the providers work in air-gapped environment
- To provide fetch configuration for each provider reading from an accessible location (e.g. an internal github repository) or from ConfigMaps pre-created inside the cluster.
- To provide image overrides for each provider in order to pull the images from an accessible image repository.
Example Usage
As an admin, I would like to fetch my azure provider components from within the cluster because I’m working within an air-gapped environment.
In this example, we have two config maps that define the components and
metadata of the provider. They each share the label provider-components: azure
and are within the capz-system
namespace.
The azure InfrastructureProvider has a fetchConfig
which specifies the label
selector. This way the operator knows which versions of the azure provider are
available. Since the provider’s version is marked as v0.4.9
, it uses the
components information from the config map to install the azure provider.
---
apiVersion: v1
kind: ConfigMap
metadata:
labels:
provider-components: azure
name: v0.4.9
namespace: capz-system
data:
components: |
# components for v0.4.9 yaml goes here
metadata: |
# metadata information goes here
---
apiVersion: v1
kind: ConfigMap
metadata:
labels:
provider-components: azure
name: v0.4.8
namespace: capz-system
data:
components: |
# components for v0.4.8 yaml goes here
metadata: |
# metadata information goes here
---
apiVersion: management.cluster.x-k8s.io/v1alpha1
kind: InfrastructureProvider
metadata:
name: azure
namespace: capz-system
spec:
version: v0.4.9
secretName: azure-variables
fetchConfig:
selector:
matchLabels:
provider-components: azure
Currently, clusterctl provides quick feedback regarding required variables etc. With the operator in place we’ll need to ensure that the error messages and logs are easily available to the user to verify progress.
Currently, clusterctl has a few extensibility options. For example, clusterctl is built on-top of a library that can be leveraged to build other tools.
It also exposes an interface for template processing if we choose to go a
different route from envsubst
. This may prove to be challenging in the
context of the operator as this would mean a change to the operator
binary/image. We could introduce a new behavior or communication protocol or
hooks for the operator to interact with the custom template processor. This
could be configured similarly to the fetch config, with multiple options built
in.
We have decided that supporting multiple template processors is a non-goal for
this implementation of the proposal and we will rely on using the default
envsubst
template processor.
As of today, this is hard to define as have yet to understand the definition of what a v1alpha4 cluster will be. Once we better understand what a v1alpha4 cluster will look like, we will then be able to determine the upgrade sequence from v1alpha3.
Cluster API will provide instructions on how to upgrade from a v1alpha3 management cluster, created by clusterctl to the new v1alpha4 management cluster. These operations could require manual actions.
Some of the actions are described below:
- Run webhooks as part of the main manager. See issue 3822
The operator will be written with unit and integration tests using envtest and existing patterns as defined under the Developer Guide/Testing section in the Cluster API book.
Existing E2E tests will verify that existing clusterctl commands such as init
and upgrade
will work as expected. Any necessary changes will be made in
order to make it configurable.
New E2E tests verifying the operator lifecycle itself will be added.
New E2E tests verifying the upgrade from a v1alpha3 to v1alpha4 cluster will be added.
- clusterctl will require a matching operator version. In the future, when clusterctl move to beta/GA, we will reconsider supporting version skew between clusterctl and the operator.
- 09/09/2020: Proposed idea in an issue or community meeting
- 09/14/2020: Compile a Google Doc following the CAEP template
- 09/14/2020: First round of feedback from community
- 10/07/2020: Present proposal at a community meeting
- 10/20/2020: Open proposal PR
These types are pulled from controller-runtime
and component-base. They are used as part of the
ManagerSpec
. They are duplicated here for convenience sake.
// ControllerManagerConfigurationSpec defines the desired state of GenericControllerManagerConfiguration
type ControllerManagerConfigurationSpec struct {
// SyncPeriod determines the minimum frequency at which watched resources are
// reconciled. A lower period will correct entropy more quickly, but reduce
// responsiveness to change if there are many watched resources. Change this
// value only if you know what you are doing. Defaults to 10 hours if unset.
// there will a 10 percent jitter between the SyncPeriod of all controllers
// so that all controllers will not send list requests simultaneously.
// +optional
SyncPeriod *metav1.Duration `json:"syncPeriod,omitempty"`
// LeaderElection is the LeaderElection config to be used when configuring
// the manager.Manager leader election
// +optional
LeaderElection *configv1alpha1.LeaderElectionConfiguration `json:"leaderElection,omitempty"`
// CacheNamespace if specified restricts the manager's cache to watch objects in
// the desired namespace Defaults to all namespaces
//
// Note: If a namespace is specified, controllers can still Watch for a
// cluster-scoped resource (e.g Node). For namespaced resources the cache
// will only hold objects from the desired namespace.
// +optional
CacheNamespace string `json:"cacheNamespace,omitempty"`
// GracefulShutdownTimeout is the duration given to runnable to stop before the manager actually returns on stop.
// To disable graceful shutdown, set to time.Duration(0)
// To use graceful shutdown without timeout, set to a negative duration, e.G. time.Duration(-1)
// The graceful shutdown is skipped for safety reasons in case the leader election lease is lost.
GracefulShutdownTimeout *metav1.Duration `json:"gracefulShutDown,omitempty"`
// Metrics contains thw controller metrics configuration
// +optional
Metrics ControllerMetrics `json:"metrics,omitempty"`
// Health contains the controller health configuration
// +optional
Health ControllerHealth `json:"health,omitempty"`
// Webhook contains the controllers webhook configuration
// +optional
Webhook ControllerWebhook `json:"webhook,omitempty"`
}
// ControllerMetrics defines the metrics configs
type ControllerMetrics struct {
// BindAddress is the TCP address that the controller should bind to
// for serving prometheus metrics.
// It can be set to "0" to disable the metrics serving.
// +optional
BindAddress string `json:"bindAddress,omitempty"`
}
// ControllerHealth defines the health configs
type ControllerHealth struct {
// HealthProbeBindAddress is the TCP address that the controller should bind to
// for serving health probes
// +optional
HealthProbeBindAddress string `json:"healthProbeBindAddress,omitempty"`
// ReadinessEndpointName, defaults to "readyz"
// +optional
ReadinessEndpointName string `json:"readinessEndpointName,omitempty"`
// LivenessEndpointName, defaults to "healthz"
// +optional
LivenessEndpointName string `json:"livenessEndpointName,omitempty"`
}
// ControllerWebhook defines the webhook server for the controller
type ControllerWebhook struct {
// Port is the port that the webhook server serves at.
// It is used to set webhook.Server.Port.
// +optional
Port *int `json:"port,omitempty"`
// Host is the hostname that the webhook server binds to.
// It is used to set webhook.Server.Host.
// +optional
Host string `json:"host,omitempty"`
// CertDir is the directory that contains the server key and certificate.
// if not set, webhook server would look up the server key and certificate in
// {TempDir}/k8s-webhook-server/serving-certs. The server key and certificate
// must be named tls.key and tls.crt, respectively.
// +optional
CertDir string `json:"certDir,omitempty"`
}
// LeaderElectionConfiguration defines the configuration of leader election
// clients for components that can run with leader election enabled.
type LeaderElectionConfiguration struct {
// leaderElect enables a leader election client to gain leadership
// before executing the main loop. Enable this when running replicated
// components for high availability.
LeaderElect *bool `json:"leaderElect"`
// leaseDuration is the duration that non-leader candidates will wait
// after observing a leadership renewal until attempting to acquire
// leadership of a led but unrenewed leader slot. This is effectively the
// maximum duration that a leader can be stopped before it is replaced
// by another candidate. This is only applicable if leader election is
// enabled.
LeaseDuration metav1.Duration `json:"leaseDuration"`
// renewDeadline is the interval between attempts by the acting master to
// renew a leadership slot before it stops leading. This must be less
// than or equal to the lease duration. This is only applicable if leader
// election is enabled.
RenewDeadline metav1.Duration `json:"renewDeadline"`
// retryPeriod is the duration the clients should wait between attempting
// acquisition and renewal of a leadership. This is only applicable if
// leader election is enabled.
RetryPeriod metav1.Duration `json:"retryPeriod"`
// resourceLock indicates the resource object type that will be used to lock
// during leader election cycles.
ResourceLock string `json:"resourceLock"`
// resourceName indicates the name of resource object that will be used to lock
// during leader election cycles.
ResourceName string `json:"resourceName"`
// resourceName indicates the namespace of resource object that will be used to lock
// during leader election cycles.
ResourceNamespace string `json:"resourceNamespace"`
}
[issue 3822]: kubernetes-sigs#3822) [secret-name-discussion]: kubernetes-sigs#3833 (comment)