Este contenido no está disponible en el idioma seleccionado.
Chapter 6. Service Catalog Components
6.1. Service Catalog
6.1.1. Overview
When developing microservices-based applications to run on cloud native platforms, there are many ways to provision different resources and share their coordinates, credentials, and configuration, depending on the service provider and the platform.
To give developers a more seamless experience, OpenShift Container Platform includes a service catalog, an implementation of the Open Service Broker API (OSB API) for Kubernetes. This allows users to connect any of their applications deployed in OpenShift Container Platform to a wide variety of service brokers.
The service catalog allows cluster administrators to integrate multiple platforms using a single API specification. The OpenShift Container Platform web console displays the cluster service classes offered by service brokers in the service catalog, allowing users to discover and instantiate those services for use with their applications.
As a result, service users benefit from ease and consistency of use across different types of services from different providers, while service providers benefit from having one integration point that gives them access to multiple platforms.
6.1.2. Design
The design of the service catalog follows this basic workflow:
New terms in the following are defined further in Concepts and Terminology.
- A cluster administrator registers one or more cluster service brokers with their OpenShift Container Platform cluster. This can be done automatically during installation for some default-provided service brokers or manually.
- Each service broker specifies a set of cluster service classes and variations of those services (service plans) to OpenShift Container Platform that should be made available to users.
- Using the OpenShift Container Platform web console or CLI, users discover the services that are available. For example, a cluster service class may be available that is a database-as-a-service called BestDataBase.
- A user chooses a cluster service class and requests a new instance of their own. For example, a service instance may be a BestDataBase instance named
my_db
. - A user links, or binds, their service instance to a set of pods (their application). For example, the
my_db
service instance may be bound to the user’s application calledmy_app
.
When a user makes a request to provision or deprovision a resource, the request is made to the service catalog, which then sends a request to the appropriate cluster service broker. With some services, some operations such as provision
, deprovision
, and update
are expected to take some time to fulfill. If the cluster service broker is unavailable, the service catalog will continue to retry the operation.
This infrastructure allows a loose coupling between applications running in OpenShift Container Platform and the services they use. This allows the application that uses those services to focus on its own business logic while leaving the management of these services to the provider.
6.1.2.1. Deleting Resources
When a user is done with a service (or perhaps no longer wishes to be billed), the service instance can be deleted. In order to delete the service instance, the service bindings must be removed first. Deleting the service bindings is known as unbinding. Part of the deletion process includes deleting the secret that references the service binding being deleted.
Once all the service bindings are removed, the service instance may be deleted. Deleting the service instance is known as deprovisioning.
If a project or namespace containing service bindings and service instances is deleted, the service catalog must first request the cluster service broker to delete the associated instances and bindings. This is expected to delay the actual deletion of the project or namespace since the service catalog must communicate with cluster service brokers and wait for them to perform their deprovisioning work. In normal circumstances, this may take several minutes or longer depending on the service.
If you delete a service binding used by a deployment, you must also remove any references to the binding secret from the deployment. Otherwise, the next rollout will fail.
6.1.3. Concepts and Terminology
- Cluster Service Broker
A cluster service broker is a server that conforms to the OSB API specification and manages a set of one or more services. The software could be hosted within your own OpenShift Container Platform cluster or elsewhere.
Cluster administrators can create
ClusterServiceBroker
API resources representing cluster service brokers and register them with their OpenShift Container Platform cluster. This allows cluster administrators to make new types of managed services using that cluster service broker available within their cluster.A
ClusterServiceBroker
resource specifies connection details for a cluster service broker and the set of services (and variations of those services) to OpenShift Container Platform that should then be made available to users. Of special note is theauthInfo
section, which contains the data used to authenticate with the cluster service broker.Example
ClusterServiceBroker
ResourceapiVersion: servicecatalog.k8s.io/v1beta1 kind: ClusterServiceBroker metadata: name: BestCompanySaaS spec: url: http://bestdatabase.example.com authInfo: basic: secretRef: namespace: test-ns name: secret-name
- Cluster Service Class
Also synonymous with "service" in the context of the service catalog, a cluster service class is a type of managed service offered by a particular cluster service broker. Each time a new cluster service broker resource is added to the cluster, the service catalog controller connects to the corresponding cluster service broker to obtain a list of service offerings. A new
ClusterServiceClass
resource is automatically created for each.NoteOpenShift Container Platform also has a core concept called services, which are separate Kubernetes resources related to internal load balancing. These resources are not to be confused with how the term is used in the context of the service catalog and OSB API.
Example
ClusterServiceClass
ResourceapiVersion: servicecatalog.k8s.io/v1beta1 kind: ClusterServiceClass metadata: name: smallDB brokerName: BestDataBase plans: [...]
- Cluster Service Plan
- A cluster service plan represents tiers of a cluster service class. For example, a cluster service class may expose a set of plans that offer varying degrees of quality-of-service (QoS), each with a different cost associated with it.
- Service Instance
A service instance is a provisioned instance of a cluster service class. When a user wants to use the capability provided by a service class, they can create a new service instance.
When a new
ServiceInstance
resource is created, the service catalog controller connects to the appropriate cluster service broker and instructs it to provision the service instance.Example
ServiceInstance
ResourceapiVersion: servicecatalog.k8s.io/v1beta1 kind: ServiceInstance metadata: name: my_db namespace: test-ns spec: externalClusterServiceClassName: smallDB externalClusterServicePlanName: default
- Application
- The term application refers to the OpenShift Container Platform deployment artifacts, for example pods running in a user’s project, that will use a service instance.
- Credentials
- Credentials are information needed by an application to communicate with a service instance.
- Service Binding
A service binding is a link between a service instance and an application. These are created by cluster users who wish for their applications to reference and use a service instance.
Upon creation, the service catalog controller creates a Kubernetes secret containing connection details and credentials for the service instance. Such secrets can be mounted into pods as usual.
Example
ServiceBinding
ResourceapiVersion: servicecatalog.k8s.io/v1beta1 kind: ServiceBinding metadata: name: myBinding namespace: test-ns spec: instanceRef: name: my_db parameters: securityLevel: confidential secretName: mySecret
Users should not use the web console to change the prefix of environment variables for instantiated instances, as it can cause application routes to become inaccessible.
- Parameters
A parameter is a special field available to pass additional data to the cluster service broker when using either service bindings or service instances. The only formatting requirement is for the parameters to be valid YAML (or JSON). In the above example, a security level parameter is passed to the cluster service broker in the service binding request. For parameters that need more security, place them in a secret and reference them using
parametersFrom
.Example Service Binding Resource Referencing a Secret
apiVersion: servicecatalog.k8s.io/v1beta1 kind: ServiceBinding metadata: name: myBinding namespace: test-ns spec: instanceRef: name: my_db parametersFrom: - secretKeyRef: name: securityLevel key: myKey secretName: mySecret
6.1.4. Provided Cluster Service Brokers
OpenShift Container Platform provides the following cluster service brokers for use with the service catalog.
6.2. Service catalog command-line interface (CLI)
6.2.1. Overview
The basic workflow of interacting with the service catalog is that:
- The cluster administrator installs and registers a broker server to make available its services.
- The users use those services by instantiating them in an OpenShift project and linking those service instances to their pods.
The Service Catalog command-line interface (CLI) utility called svcat
is available to handle these user related tasks. While oc
commands can perform the same tasks, you can use svcat
for easier interaction with Service Catalog resources. svcat
communicates with the Service Catalog API by using the aggregated API endpoint on an OpenShift cluster.
6.2.2. Installing svcat
You can install svcat
as an RPM by using Red Hat Subscription Management (RHSM) if you have an active OpenShift Enterprise subscription on your Red Hat account:
# yum install atomic-enterprise-service-catalog-svcat
6.2.2.1. Considerations for cloud providers
Google Compute Engine For Google Cloud Platform, run the following command to setup firewall rules to allow incoming traffic:
$ gcloud compute firewall-rules create allow-service-catalog-secure --allow tcp:30443 --description "Allow incoming traffic on 30443 port."
6.2.3. Using svcat
This section includes common commands to handle the user associated tasks listed in the service catalog workflow. Use the svcat --help
command to get more information and view other available command-line options. The sample output in this section assumes that the Ansible Service Broker is already installed on the cluster.
6.2.3.1. Get broker details
You can view a list available brokers, sync the broker catalog, and get details about brokers deployed in the service catalog.
6.2.3.1.1. Find brokers
To view all the brokers installed on the cluster:
$ svcat get brokers
Example Output
NAME URL STATUS +-------------------------+-------------------------------------------------------------------------------------------+--------+ ansible-service-broker https://asb.openshift-ansible-service-broker.svc:1338/ansible-service-broker Ready template-service-broker https://apiserver.openshift-template-service-broker.svc:443/brokers/template.openshift.io Ready
6.2.3.1.2. Sync broker catalog
To refresh the catalog metadata from the broker:
$ svcat sync broker ansible-service-broker
Example Output
Synchronization requested for broker: ansible-service-broker
6.2.3.1.3. View broker details
To view the details of the broker:
$ svcat describe broker ansible-service-broker
Example Output
Name: ansible-service-broker URL: https://openshift-automation-service-broker.openshift-automation-service-broker.svc:1338/openshift-automation-service-broker/ Status: Ready - Successfully fetched catalog entries from broker @ 2018-06-07 00:32:59 +0000 UTC
6.2.3.2. View service classes and service plans
When you create a ClusterServiceBroker
resource, the service catalog controller queries the broker server to find all services it offers and creates a service class (ClusterServiceClass
) for each of those services. Additionally, it also creates service plans (ClusterServicePlan
) for each of the broker’s services.
6.2.3.2.1. View service classes
To view the available ClusterServiceClass resources:
$ svcat get classes
Example Output
NAME DESCRIPTION +-------------------+--------------------------------+ rh-mediawiki-apb Mediawiki apb implementation ... rh-mariadb-apb Mariadb apb implementation rh-mysql-apb Software Collections MySQL APB rh-postgresql-apb SCL PostgreSQL apb implementation
To view details of a service class:
$ svcat describe class rh-postgresql-apb
Example Output
Name: rh-postgresql-apb Description: SCL PostgreSQL apb implementation UUID: d5915e05b253df421efe6e41fb6a66ba Status: Active Tags: database, postgresql Broker: ansible-service-broker Plans: NAME DESCRIPTION +------+--------------------------------+ prod A single DB server with persistent storage dev A single DB server with no storage
6.2.3.2.2. View service plans
To view the ClusterServicePlan resources available in the cluster:
$ svcat get plans
Example Output
NAME CLASS DESCRIPTION +---------+-------------------+--------------------------------+ default rh-mediawiki-apb An APB that deploys MediaWiki ... prod rh-mariadb-apb This plan deploys a single MariaDB instance with 10 GiB of persistent storage dev rh-mariadb-apb This plan deploys a single MariaDB instance with ephemeral storage prod rh-mysql-apb A MySQL server with persistent storage dev rh-mysql-apb A MySQL server with ephemeral storage prod rh-postgresql-apb A single DB server with persistent storage dev rh-postgresql-apb A single DB server with no storage
View details of a plan:
$ svcat describe plan rh-postgresql-apb/dev
Example Output
Name: dev Description: A single DB server with no storage UUID: 9783fc2e859f9179833a7dd003baa841 Status: Active Free: true Class: rh-postgresql-apb Instances: No instances defined Instance Create Parameter Schema: $schema: http://json-schema.org/draft-04/schema additionalProperties: false properties: postgresql_database: default: admin pattern: ^[a-zA-Z_][a-zA-Z0-9_]*$ title: PostgreSQL Database Name type: string postgresql_password: pattern: ^[a-zA-Z0-9_~!@#$%^&*()-=<>,.?;:|]+$ title: PostgreSQL Password type: string postgresql_user: default: admin maxLength: 63 pattern: ^[a-zA-Z_][a-zA-Z0-9_]*$ title: PostgreSQL User type: string postgresql_version: default: "9.6" enum: - "9.6" - "9.5" - "9.4" title: PostgreSQL Version type: string required: - postgresql_database - postgresql_user - postgresql_password - postgresql_version type: object Instance Update Parameter Schema: $schema: http://json-schema.org/draft-04/schema additionalProperties: false properties: postgresql_version: default: "9.6" enum: - "9.6" - "9.5" - "9.4" title: PostgreSQL Version type: string required: - postgresql_version type: object Binding Create Parameter Schema: $schema: http://json-schema.org/draft-04/schema additionalProperties: false type: object
6.2.3.3. Provision services
Provisioning means to make the service available for consumption. To provision a service, you need to create a service instance and then bind to it.
6.2.3.3.1. Create ServiceInstance
Service instances must be created inside an OpenShift namespace.
Create a new project.
$ oc new-project <project-name> 1
- 1
- Replace
<project-name>
with the name of your project.
Create service instance using the command:
$ svcat provision postgresql-instance --class rh-postgresql-apb --plan dev --params-json '{"postgresql_database":"admin","postgresql_password":"admin","postgresql_user":"admin","postgresql_version":"9.6"}' -n szh-project
Example Output
Name: postgresql-instance Namespace: szh-project Status: Class: rh-postgresql-apb Plan: dev Parameters: postgresql_database: admin postgresql_password: admin postgresql_user: admin postgresql_version: "9.6"
6.2.3.3.1.1. View service instance details
To view service instance details:
$ svcat get instance
Example Output
NAME NAMESPACE CLASS PLAN STATUS +---------------------+-------------+-------------------+------+--------+ postgresql-instance szh-project rh-postgresql-apb dev Ready
6.2.3.3.2. Create ServiceBinding
When you create a ServiceBinding
resource:
- The service catalog controller communicates with the broker server to initiate the binding.
- The broker server create credentials and issue them to the service catalog controller.
- The service catalog controller adds those credentials as secrets to the project.
Create the service binding using the command:
$ svcat bind postgresql-instance --name mediawiki-postgresql-binding
Example Output
Name: mediawiki-postgresql-binding Namespace: szh-project Status: Instance: postgresql-instance Parameters: {}
6.2.3.3.2.1. View service binding details
To view service binding details:
$ svcat get bindings
Example Output
NAME NAMESPACE INSTANCE STATUS +------------------------------+-------------+---------------------+--------+ mediawiki-postgresql-binding szh-project postgresql-instance Ready
Verify the instance details after binding the service:
$ svcat describe instance postgresql-instance
Example Output
Name: postgresql-instance Namespace: szh-project Status: Ready - The instance was provisioned successfully @ 2018-06-05 08:42:55 +0000 UTC Class: rh-postgresql-apb Plan: dev Parameters: postgresql_database: admin postgresql_password: admin postgresql_user: admin postgresql_version: "9.6" Bindings: NAME STATUS +------------------------------+--------+ mediawiki-postgresql-binding Ready
6.2.4. Deleting resources
To delete service catalog related resources, you need to unbind service bindings and deprovision the service instances.
6.2.4.1. Deleting service bindings
To delete all service bindings associated with a service instance:
$ svcat unbind -n <project-name> 1 \ <instance-name> 2
For example:
$ svcat unbind -n szh-project postgresql-instance
Example Output
deleted mediawiki-postgresql-binding
Verify that all service bindings are deleted:
$ svcat get bindings
Example Output
NAME NAMESPACE INSTANCE STATUS +------+-----------+----------+--------+
NoteRunning this command deletes all service bindings for the instance. For deleting individual bindings from within an instance run the command
svcat unbind -n <project-name> --name <binding-name>
. For example,svcat unbind -n szh-project --name mediawiki-postgresql-binding
.Verify that the associated secret is deleted.
$ oc get secret -n szh-project
Example Output
NAME TYPE DATA AGE builder-dockercfg-jxk48 kubernetes.io/dockercfg 1 9m builder-token-92jrf kubernetes.io/service-account-token 4 9m builder-token-b4sm6 kubernetes.io/service-account-token 4 9m default-dockercfg-cggcr kubernetes.io/dockercfg 1 9m default-token-g4sg7 kubernetes.io/service-account-token 4 9m default-token-hvdpq kubernetes.io/service-account-token 4 9m deployer-dockercfg-wm8th kubernetes.io/dockercfg 1 9m deployer-token-hnk5w kubernetes.io/service-account-token 4 9m deployer-token-xfr7c kubernetes.io/service-account-token 4 9m
6.2.4.2. Deleting service instances
To deprovision the service instance:
$ svcat deprovision postgresql-instance
Example Output
deleted postgresql-instance
Verify the instance is deleted:
$ svcat get instance
Example Output
NAME NAMESPACE CLASS PLAN STATUS +------+-----------+-------+------+--------+
6.2.4.3. Deleting service brokers
To remove broker services for the service catalog, delete the
ClusterServiceBroker
resource:$ oc delete clusterservicebrokers template-service-broker
Example Output
clusterservicebroker "template-service-broker" deleted
To view all the brokers installed on the cluster:
$ svcat get brokers
Example Output
NAME URL STATUS +-------------------------+-------------------------------------------------------------------------------------------+--------+ ansible-service-broker https://asb.openshift-ansible-service-broker.svc:1338/ansible-service-broker Ready
View the
ClusterServiceClass
resources for the broker to verify that the broker is removed:$ svcat get classes
Example Output
NAME DESCRIPTION +------+-------------+
6.3. Template Service Broker
The template service broker (TSB) gives the service catalog visibility into the default Instant App and Quickstart templates that have shipped with OpenShift Container Platform since its initial release. The TSB can also make available as a service anything for which an OpenShift Container Platform template has been written, whether provided by Red Hat, a cluster administrator or user, or a third party vendor.
By default, the TSB shows the objects that are globally available from the openshift project. It can also be configured to watch any other project that a cluster administrator chooses.
6.4. OpenShift Ansible Broker
6.4.1. Overview
The OpenShift Ansible broker (OAB) is an implementation of the Open Service Broker (OSB) API that manages applications defined by Ansible playbook bundles (APBs). APBs provide a new method for defining and distributing container applications in OpenShift Container Platform, consisting of a bundle of Ansible playbooks built into a container image with an Ansible runtime. APBs leverage Ansible to create a standard mechanism for automating complex deployments.
The design of the OAB follows this basic workflow:
- A user requests list of available applications from the service catalog using the OpenShift Container Platform web console.
- The service catalog requests the OAB for available applications.
- The OAB communicates with a defined container image registry to learn which APBs are available.
- The user issues a request to provision a specific APB.
- The provision request makes its way to the OAB, which fulfills the user’s request by invoking the provision method on the APB.
6.4.2. Ansible Playbook Bundles
An Ansible playbook bundle (APB) is a lightweight application definition that allows you to leverage existing investment in Ansible roles and playbooks.
APBs use a simple directory with named playbooks to perform OSB API actions, such as provision and bind. Metadata defined in apb.yml spec file contains a list of required and optional parameters for use during deployment.
See the APB Development Guide for details on the overall design and how APBs are written.
6.5. AWS Service Broker
The AWS Service Broker provides access to Amazon Web Services (AWS) through the OpenShift Container Platform service catalog. AWS services and components can be configured and viewed in both the OpenShift Container Platform web console and the AWS dashboards.
Figure 6.1. Example AWS services in the OpenShift Container Platform service catalog
For information on installing the AWS Service Broker, see the AWS Service Broker Documentation in the Amazon Web Services - Labs docs repository.
The AWS Service Broker is supported and qualified on OpenShift Container Platform. It is offered directly from Amazon as a download and as such, many components of this service broker solution are supported directly by Amazon for the most recent two versions with a lag of two months after a new OpenShift Container Platform release. Red Hat provides support for the installation and troubleshooting of the OpenShift cluster and service catalog issues.