Deckhouse Commander is a web app that lets one create uniform clusters using UI, and control the lifecycle of those clusters.
Features
- Creation, updating and deleting clusters on major cloud platforms as well as on static resources
- Unification and actualization of clusters configuration using cluster templates
- The control of changes and the reconciliation to the desired configuration
- Cluster operation wia embedded admin console
- Catalogs of resources data utilized in clusters
- Integration API
Coming soon:
- Access control: users and permissions
- Cross-cluster projects
- Cloud resources overview used by cluster
Concepts
dhctl
To install the Deckhouse Kubernetes Platform manually, use the dhctl utility. It accepts three sets of data as input:
- The cluster configuration and cluster installation in the form of a file, hereinafter referred to as config.yaml.
- The SSH connection configuration to the machine that will become the first master node. The configuration is used as dhctl command line keys (it is possible to specify it in the form of YAML). Hereinafter referred to as SSHConfig.
- An optional set of resources that need to be created at the last step of the installation, hereinafter referred to as resources.yaml.
What logical parts are contained in this data?
config.yaml
InitConfiguration
— cluster setup configurationModuleConfig
resources — configuration of built-in modules: explicit enabling or disabling, as well as default settings overrideClusterConfiguration
— Kubernetes configuration: version, pod subnets, services, etc.- Deployment parameters
<Provider>ClusterConfiguration
— parameters of cluster deployment in the cloud or a Virtualization API;- or
StaticClusterConfiguration
if Deckhouse Kubernetes Platform is being installed on static resources;
resources.yaml
- Arbitrary Kubernetes resources, including
ModuleConfig
for non-built-in modules in Deckhouse Kubernetes Platform
- Arbitrary Kubernetes resources, including
SSHConfig
- User name, password and key to connect to an existing machine or the one that will be created during cluster creation
- IP address of the machine, if the cluster is deployed on static resources and the address of the future master node is known in advance
- You can see the rest of the parameters in the help of the dhctl command, in this documentation, additional details are not essential.
For manual cluster management using dhctl, the above configuration types are needed in different combinations for cluster installation, modification, and removal.
Configuration type | Purpose | Installation | Modification | Removal |
---|---|---|---|---|
SSHConfig |
SSH connection to the master node | ✓ | ✓ | ✓ |
config.yaml |
Installation configurationInitConfiguration |
✓ | ||
config.yaml |
Deployment configuration<Provider>ClusterConfiguration or StaticClusterConfiguration |
✓ | ✓ | |
config.yaml |
Kubernetes cluster configurationClusterConfiguration |
✓ | ✓ | |
config.yaml |
Deckhouse Kubernetes Platform configuration (ModuleConfig ) |
✓ | ||
resources.yaml |
Cluster resources | ✓ |
As you can see, all the provided configuration is used to create a cluster. To do this, use dhctl bootstrap
with all the provided configuration.
Changes that can be made to the cluster using the same tool relate to either the deployment
parameters (for example, resources of permanent nodes created by Terraform) or the Kubernetes
parameters. Only the connection settings and general cluster parameters are available for
modification with dhctl converge
. However, it is not possible to apply changes to the platform
configuration or additional cluster resources in this way.
Finally, to delete a cluster, it is enough to have an access to it: the dhctl destroy
operation
uses only SSHConfig
.
Commander
Commander makes use of the same dataset for configuring clusters as dhctl does, however Commander adds the ability to synchronize a complete desired configuration with the cluster. If we imagine Commander as an enhanced version of dhctl, then the table would look like this:
Configuration Type | Purpose | Installation | Modification | Deletion |
---|---|---|---|---|
SSHConfig |
SSH connection to the master node | ✓ | ✓ | ✓ |
config.yaml |
Installation configurationInitConfiguration |
✓ | ||
config.yaml |
Deployment configuration<Provider>ClusterConfiguration or StaticClusterConfiguration |
✓ | ✓ | |
config.yaml |
Kubernetes configurationClusterConfiguration |
✓ | ✓ | |
config.yaml |
Deckhouse Kubernetes Platform configuration (ModuleConfig ) |
✓ | ✓ | |
resources.yaml |
Cluster resources | ✓ | ✓ |
As you can see, Commander has a complete coverage of the Deckhouse Kubernetes Platform configuration
for managing it after installation. Only InitConfiguration
does not participate in modification,
because this part of the configuration does not bring new information to the existing cluster.
Commander is the source of truth for the cluster configuration. Commander monitors that the cluster configuration matches the desired one. If Commander detects a discrepancy, it attempts to bring the cluster to the desired configuration. For this purpose, we will use the term “synchronization” further on.
In Commander, it is possible to specify the initial configuration of cluster resources, which will be applied during the cluster installation but will not be synchronized later on. This is useful when you need to create recommended or initial resources, but want to give control over them to the cluster operators.
Commander divides the Deckhouse Kubernetes Platform configuration based on the principle of traceability. Moreover, the user decides which part of the configuration should be synchronized and which should be set once when creating the cluster. Here is how this configuration looks from Commander’s perspective:
dhctl Configuration Type | Commander Configuration Type | Purpose | Installation | Synchronization | Deletion |
---|---|---|---|---|---|
SSHConfig |
SSH parameters | SSH connection to the master node | ✓ | ✓ | ✓ |
config.yaml |
Deployment | Deployment configuration<Provider>ClusterConfiguration or StaticClusterConfiguration |
✓ | ✓ | |
config.yaml |
Kubernetes | Kubernetes configurationClusterConfiguration |
✓ | ✓ | |
config.yaml |
Resources | Deckhouse Kubernetes Platform configuration (ModuleConfig ) |
✓ | ✓ | |
resources.yaml |
Resources | Cluster resources, including any ModuleConfig |
✓ | ✓ | |
resources.yaml |
Initial resources | Cluster resources, including any ModuleConfig |
✓ | ||
config.yaml |
Installation | Installation configurationInitConfiguration |
✓ |
Note that the last two lines describe a configuration that will not be monitored or synchronized after the cluster is created.
Templates
The Idea
Commander is designed to manage typical clusters. Since all types of configuration in Commander are represented in YAML format, clustering templatization is a markup of the required YAML configuration with parameters and a description of the input parameters scheme of the template. To templatize YAML, the go template syntax and the sprig function set are used. A custom syntax for fields is used to describe the scheme of input parameters.
Type of Commander config | Type | Purpose |
---|---|---|
Input parameters | Scheme | Scheme of input parameters of the template |
Kubernetes | YAML Template | Kubernetes configuration ClusterConfiguration |
Deployment | YAML Template | Deployment configuration <Provider>ClusterConfiguration or StaticClusterConfiguration |
SSH parameters | YAML Template | SSH connection to the master node |
Resources | YAML Template | Cluster resources, including any ModuleConfig |
Primary resources | YAML Template | Cluster resources, including any ModuleConfig |
Installation | YAML Template | Installation configuration InitConfiguration |
The cluster configuration is created by substituting the input parameters into the configuration templates. The input parameters are validated by the scheme specified for them.
Template versions
An important feature of a template is evolution. It is not enough to create a cluster fleet based on templates. Templates are improved and updated to meet the new software versions and new requirements for cluster operation. An updated template allows not only creating new clusters that meet modern requirements, but also updating existing clusters.
To evolve templates in Commander, a versioning mechanism is provided. When a template receives updates, a new version is created for it. The version can be accompanied by a comment. Based on the template version, you can create a cluster and test its performance. If the template version is unsuitable for use, it can be marked as unavailable for use. Then, cluster administrators will not be able to switch the cluster to the template version.
In Commander, each cluster is tied to a specific template version. However, technically, the cluster can be transferred to any other template and any available template version, subject to an invalid configuration that Commander will not allow to save. When the cluster is transferred to a new version or template, it is necessary to update the input parameters so that the updated configuration is created for the cluster. Commander will detect that the target configuration does not match the last applied configuration and create a task to synchronize the cluster.
Complexity of the template
Creating and testing a template is an engineering task, while creating clusters based on a template does not require a deep dive into technical details in general.
The input parameters of a template are presented to the user in the form of an online form, where the user enters or selects the parameters necessary to create a cluster. The entire set of input parameters is defined by the author of the template: which parameters are available, which are mandatory, in what order they are filled in, what test they are accompanied by, and how they are formatted for ease of perception by the end user.
Only the author of the template determines how easy or difficult it will be for the end user to use the template, and what decisions the user needs to make in order to successfully create a cluster. The more complex the template, the more complex the templating code and the more complex the form of the template parameters. Commander users themselves determine the ratio of complexity of the template and the number of templates for different scenarios. Commander is a flexible enough tool. With it, you can create both one template for all occasions and many templates for each individual use case.
Creating a template
You can add a template to Commander in two ways: by importing an existing one (for example, one created earlier in another installation of Commander) or by creating a new one from scratch. Ultimately, the templated configuration must comply with the features of dhctl and Deckhouse Kubernetes Platform of the version that will be installed using the template.
Where to find documentation for configuration types:
- Input parameters: usage.html#cluster-and-resource-parameter-scheme
- Kubernetes:
- Deployment:
- Static resources
- Yandex Cloud: cluster_configuration
- VMware vSphere: cluster_configuration
- OpenStack: cluster_configuration
- Amazon Web Services: cluster_configuration
- Google Cloud Platform: cluster_configuration
- Microsoft Azure: cluster_configuration
- SSH parameters: see examples below
- Resources: arbitrary Kubernetes and Deckhouse resource manifests. Commander will synchronize these resources.
- Primary resources: arbitrary Kubernetes and Deckhouse resource manifests. Commander will not synchronize these resources.
- Installation: InitConfiguration
Special variables
There are several special variables in the cluster templates.
Variable | Purpose |
---|---|
dc_sshPublicKey | The public part of the SSH key. A pair of SSH keys is created for each cluster. Can be used for cloud-init of cloud clusters. |
dc_sshPrivateKey | The private part of the SSH key. A pair of SSH keys is created for each cluster. Can be used to access master nodes of cloud clusters. |
dc_clusterUUID | UUID of the current cluster. Generated for each cluster. Can be used to tag metrics and logs of the cluster. |
dc_domain | The domain on which Commander is hosted. Common for the entire application. Example: commander.example.com |
Required manifests
At the moment, Commander does not create invisible configuration, so the author of the template needs to take into account several manifests in the template to get a full experience using Commander. In the future, Commander will be improved to reduce the impact of technical features on the experience of working with it.
SSH parameters for a cloud cluster
For a cloud cluster, you can use the private key created by Commander if you do not provide a predefined key in the OS image. Also, in the virtual machine images, a user will be created under which Commander will connect to the created machine to start it up as a master node.
apiVersion: dhctl.deckhouse.io/v1
kind: SSHConfig
# The name of the user for SSH is defined in the "Hosting" section of the OS image
sshUser: ubuntu
sshPort: 22
# The private key that will be used to connect to VMs via SSH
sshAgentPrivateKeys:
- key: |
{{- .dc_sshPrivateKey | nindent 4 }}
SSH and resources for static cluster
Since the machines are created in advance and SSH server, user and key are configured on them, these data must be provided in the input parameters of the cluster. Unlike the cloud configuration above, we use not an embedded parameter but one explicitly passed by the user. Some data can always be set within the template if their parameterization is not considered appropriate.
Pay attention to the SSHHost
manifests. They declare IP addresses to which Commander has access.
In this example, it is assumed that the input parameter .masterHosts
is a list of IP addresses
based on which the configuration will contain SSH hosts. Since these are masters, they should be
specified in the quantity of 1 or 3.
apiVersion: dhctl.deckhouse.io/v1
kind: SSHConfig
# username and port for SSH configured on the machines
sshUser: {{ .sshUser }}
sshPort: {{ .sshPort }}
# private key used on machines is passed as an input parameter to the cluster
sshAgentPrivateKeys:
- key: |
{{- .sshPrivateKey | nindent 4 }}
{{- range $masterHost := .masterHosts }}
---
apiVersion: dhctl.deckhouse.io/v1
kind: SSHHost
host: {{ $masterHost.ext_ip }}
{{- end }}
Commander will connect to only one SSH host in the list provided, trying hosts in order until a
successful connection is made. The first connected host will become the master node of the cluster.
Once Deckhouse is installed on the first master node, it will be able to add the remaining two
master nodes to the cluster itself if they are declared in the template. To do this, you need to
tell Deckhouse that the machines exist, how to access them, and that they need to be added to the
cluster. To do this, create a StaticInstance for the two masters, define SSHCredentials for
them, and explicitly write the group of master nodes with the parameter
spec.staticInstances.count=2
. This will ensure that not only are the two static master nodes known
to Deckhouse, but they are also claimed as master nodes. It is advisable to define this part of the
template in the Resources. Below is the code of the template for this task:
---
apiVersion: deckhouse.io/v1alpha1
kind: SSHCredentials
metadata:
name: commander-ssh-credentials
labels:
heritage: deckhouse-commander
spec:
sshPort: {{ .sshPort }}
user: {{ .sshUser }}
privateSSHKey: {{ .sshPrivateKey | b64enc }}
{{- if gt (len .masterHosts) 1 }}
{{- range $masterInstance := slice .masterHosts 1 }}
---
apiVersion: deckhouse.io/v1alpha1
kind: StaticInstance
metadata:
labels:
type: master
heritage: deckhouse-commander
name: {{ $masterInstance.hostname | quote }}
spec:
address: {{ $masterInstance.ip | quote }}
credentialsRef:
apiVersion: deckhouse.io/v1alpha1
kind: SSHCredentials
name: commander-ssh-credentials
{{- end }}
{{- end }}
{{- if gt (len .masterHosts) 1 }}
---
apiVersion: deckhouse.io/v1
kind: NodeGroup
metadata:
name: master
labels:
heritage: deckhouse-commander
spec:
disruptions:
approvalMode: Manual
nodeTemplate:
labels:
node-role.kubernetes.io/control-plane: ""
node-role.kubernetes.io/master: ""
taints:
- effect: NoSchedule
key: node-role.kubernetes.io/master
- effect: NoSchedule
key: node-role.kubernetes.io/control-plane
nodeType: Static
staticInstances:
count: 2
labelSelector:
matchLabels:
type: master
{{- end }}
Resources: deckhouse-commander-agent module
Commander synchronizes resources using the deckhouse-commander-agent module. This module is installed on the target cluster. The commander-agent application requests the current list of resources for the cluster and updates them in the cluster where it is running. To configure the agent correctly, you need to create a manifest in the resources that includes the module.
Please pay attention to commanderUrl
. You will have to specify the scheme of this address: HTTP or
HTTPS.
Cluster and Resource Parameter Scheme
There are two forms based on input parameter scheme:
- cluster parameter form, the input scheme is specified in a cluster template;
- resource form, the input scheme is specified in its catalog.
The scheme defines an object. There is always an option to edit it in the visual form editor.
Common fields
Text input
A string with default value
- key: something
type: string
title: Something
default: No input
Optional parameter
- key: something
type: string
title: Something
optional: true
The parameter is filled once during the creation of the resource or cluster, and then it cannot be edited (immutable
).
- key: something
type: string
title: Something
immutable: true
The password and its description (see format
and description
)
- key: password
type: string
format: password
minLength: 8
span: 2
title: Password
description: |
Create a good password.
The password must contain such and such elements and be updated every N days.
Number input
One can specify the maximum value and mark the field as optional
- key: ordinarySize
type: number
optional: true
max: 13
One can set a minimum and make the input field span over 4 columns (it is maximum width).
- key: eliteSize
type: number
description: In cm
min: 18
span: 4
One can set maximum and minimum values.
- key: elephantSize
type: number
description: In meters
min: 0.7
max: 2.5
span: 1
Predefined values
Simple values
Selection of predefined values. The user sees in the interface the value that they select.
- key: kubeVersion
type: string
title: Kubernetes Version
enum:
- Automatic
- "1.25"
- "1.26"
- "1.27"
Complex values
Selection of pre-defined object values. In the interface, the user sees a value from text
, while
technically value
is chosen for the template. Note that in value
only object (key-value) type
values are available. This value is not described by a schema, the structure of the object is
arbitrary.
- key: kubeVersion
title: Kubernetes Version
select:
- text: Default
value:
version: Automatic
isSupported: true
- text: 1.25 (EOL in March)
value:
version: 1.25.8
isSupported: true
- text: 1.26
value:
version: 1.26.4
isSupported: true
- text: 1.27
value:
version: 1.27.3
isSupported: true
- text: 1.28 (experimental support)
value:
version: 1.28.0
isSupported: false
Fields supported in cluster template
Single resource from a catalog
Catalogs have an unchangeable technical name (slug). It is specified in the catalog
property:
- key: slot
catalog: yandex-cloud-slot
title: Cloud slot for the cluster
immutable: true
description: >
Select a letter. It will determine the domain, prefix in the cloud, and IP address.
This slot is unique for all clusters regardless of the template.
Let's say you chose 'N'. The domain template will be '%s.X.kube.example.com'.
We recommend naming the cluster 'dev-X'.
The login and password are always 'admin@example.com'.
Multiple resources from a catalog
Multiple choice is provided by a pair of properties: minItems
and maxItems
. Any field can be made a list of data if both of these fields are specified.
- key: slot
catalog: virtual-machines
title: Worker nodes
description: Any count of worker nodes
minItems: 0
maxItems: 10000
Auto-selection
Sometimes it is not important to the user which resource is selected from the pool of resources. Therefore, auto-selection makes a substitution of a free resource automatically. The automatically selected resource can be replaced manually with another one.
- key: publicAddressesForFrontendNodes
title: Public addresses
catalog: public-ip-addresses
minItems: 3
maxItems: 3
autoselect: true
Parts
Separators
header
- Type: string
The only type of a divider is a header. It supports only text. It has no other properties.
- header: Access to container images
Properties of input fields
key
- Type: string
- Required
It is necessary to identify the value of an input field in a template. Therefore, there must always be a key field property — this field name will be used in the template during configuration rendering.
In the schema:
- key: podSubnet
title: Pod subnet
type: string
In a template:
podSubnet: {{.podSubnet | quote }}
type
- Type: string
- Required
- Supported values:
string
number
boolean
The value has a predefined type: string, number, or boolean.
title
- Type: string
- Required
The field has a title that conveys meaning. It is one line of text. It is displayed in the parameter form and in the audit.
description
- Type: string
A field may have a comment that reveals the meaning, explains boundary conditions, recording format or exceptions. There may be several lines of text.
default
- Type: depends on
type
The Default value is filled in if the field is marked optional. Also, this value is shown to the
user, for example, in the form of a placeholder. The value type of this property must match the
type
.
format
- Type: string
- Supported values:
password
date-time
url
email
uuid
cuid
cuid2
ulid
emoji
String parameters can have a format that determines the specifics of their display and validation.
span
- Type: number
- Supported values:
1
,2
,3
,4
- Default:
1
This is a decorative property that specifies how much width to occupy on the screen in fractions: from 1 to 4. Input fields fill the form one line at a time horizontally, like text. In this case, the width of a “line” in the form is 4 elements.
optional
- Type: boolean
- Default:
false
This flag indicates that the field is optional. An empty value will be ignored and the property will not be passed to the template.
immutable
- Type: boolean
- Default:
false
This flag indicates that the field is filled only once when it appears in the input parameters. The field becomes unavailable for editing if it has already been filled. This means that when you update a cluster to a new template with an immutable field, you can fill it in.
Immunity depends on the life cycle of the parameter in the form, not the cluster.
enum
- Type: array
Lists the possible values that the field accepts. The field is represented by a select regardless of
the value type selected in type
.
selector
- Type: array
This is a more complex version of enum
. It provides a string representation of an object (text
)
and an arbitrarily complex value in value
that will be selected for the template. The text is
provided for humans, and the values are for the template.
Example:
- key: kubeVersion
title: Kubernetes Version
select:
- text: Default
value:
version: Automatic
isSupported: true
- text: 1.25 (EOL in March)
value:
version: 1.25.8
isSupported: true
- text: 1.26
value:
version: 1.26.4
isSupported: true
- text: 1.27
value:
version: 1.27.3
isSupported: true
- text: 1.28 (experimental support)
value:
version: 1.28.0
isSupported: false
catalog
- Type: string
Selecting one value from the resources catalog. Write the slug of the resources catalog in the
value. The type
field does not need to be specified, because in fact it is object
, the schema of
which is described in the specified catalog. To select several values (and get a list of resources
at the entrance to the template), use minItems
and maxItems
.
Example:
- key: workerMachine
title: Virtual machine
catalog: virtual-machines
- key: workerMachines
title: Virtual machines
catalog: virtual-machines
minItems: 1
maxItems: 10
maxLength
(for strings)
- Type: number
For type: string
, this field adds validation on the string length.
minItems
, maxItems
(for resources selection)
- Type: number
Validation of the number of items selected from the resource catalog. This pair of fields is optional, but it is prohibited to use them separately: if used, then both at once.
autoselect
(for resources selection)
- Type: boolean
- Default:
false
Sometimes, it is not so important for the user which specific resource is chosen. In this case, the form chooses an available resource for the user. However, the user always has the option to change them.
Example:
- key: publicAddressesForFrontendNodes
title: Public addresses
catalog: public-ip-addresses
minItems: 3
maxItems: 3
autoselect: true
identifier
- Type: boolean
- Default: depends on values
A resource is a flat object. A resource has a compact one-line representation made up of the field
values of the resource (without keys). The resource values are separated by commas in the order
specified by the schema. This compact representation can be seen both in the list of resources
inside the directory and in the selection of a resource in a cluster view (dropdown lists). To
select a limited set of fields for a compact display of a resource, use the identifier
property.
For example, consider a resource and its possible schema options.
## Resource
login: John
password: E3xE#%DH@hW
age: 42
Show all fields | Hide a field | Choose shown explicitly | |
---|---|---|---|
Scheme |
|
|
|
Representation |
|
|
|
Behavior |
|
|
|
unique
- Type: boolean
- Default:
false
- This flag marks resource fields that must be unique within a catalog. It is prohibited to create, restore from archive, or import non-unique data.
This flag also marks cluster fields that must be unique among all clusters. Saving a cluster with non-unique data will result in a validation error and prevent creation and editing of the cluster.
The selection from a catalog for clusters is unique to the extent that resources are unique. It is not necessary to mark a selection from a catalog with this flag.
- key: subnetCIDR
type: string
title: Subnet CIDR
unique: true