Azure-integrator charm
This charm acts as a proxy to Azure and provides an interface to apply a certain set of changes via roles, profiles, and tags to the instances of the applications that are related to this charm.
Usage
When on Azure, this charm can be deployed, granted trust via Juju to access Azure, and then related to an application that supports the interface. The set of permissions that the related application could request is documented in the interface’s Requires API documentation.
For example, Charmed Kubernetes has support for this, and can be deployed with the following bundle overlay (download it here):
description: Charmed Kubernetes overlay to add native Azure support.
applications:
aws-integrator:
annotations:
gui-x: "600"
gui-y: "300"
charm: cs:~containers/azure-integrator
num_units: 1
trust: true
relations:
- ['azure-integrator', 'kubernetes-master']
- ['azure-integrator', 'kubernetes-worker']
To use this overlay with the Charmed Kubernetes bundle, it is specified during deploy like this:
juju deploy charmed-kubernetes --overlay azure-overlay.yaml --trust
To deploy with earlier versions of Juju, or if you wish to provide it different
credentials, you will need to provide the cloud credentials via the credentials
,
charm config options.
Note: The credentials used must have rights to use the API to inspect the instances connecting to it, enable a Managed Service Identity (MSI) for those instances, assign roles to those instances, and create custom roles. This may be different from the access permissions that Juju itself requires.
Resource Usage Note
By relating to this charm, other charms can directly allocate resources, such as managed disks and load balancers, which could lead to cloud charges and count against quotas. Because these resources are not managed by Juju, they will not be automatically deleted when the models or applications are destroyed, nor will they show up in Juju’s status or GUI. It is therefore up to the operator to manually delete these resources when they are no longer needed, using the Azure management website or API.
Examples
Following are some examples using Azure integration with Charmed Kubernetes.
Creating a pod with a Disk Storage-backed volume
This script creates a busybox pod with a persistent volume claim backed by Azure’s Disk Storage.
#!/bin/bash
# create a storage class using the `kubernetes.io/azure-disk` provisioner
kubectl create -f - <<EOY
apiVersion: storage.k8s.io/v1
kind: StorageClass
metadata:
name: azure-standard
provisioner: kubernetes.io/azure-disk
parameters:
storageaccounttype: Standard_LRS
kind: managed
EOY
# create a persistent volume claim using that storage class
kubectl create -f - <<EOY
kind: PersistentVolumeClaim
apiVersion: v1
metadata:
name: testclaim
spec:
accessModes:
- ReadWriteOnce
resources:
requests:
storage: 100Mi
storageClassName: azure-standard
EOY
# create the busybox pod with a volume using that PVC:
kubectl create -f - <<EOY
apiVersion: v1
kind: Pod
metadata:
name: busybox
namespace: default
spec:
containers:
- image: busybox
command:
- sleep
- "3600"
imagePullPolicy: IfNotPresent
name: busybox
volumeMounts:
- mountPath: "/pv"
name: testvolume
restartPolicy: Always
volumes:
- name: testvolume
persistentVolumeClaim:
claimName: testclaim
EOY
Creating a service with an Azure load-balancer
The following script starts the hello-world pod behind an Azure-backed load-balancer.
kubectl create deployment hello-world --image=gcr.io/google-samples/node-hello:1.0
kubectl scale deployment hello-world --replicas=5
kubectl expose deployment hello-world --type=LoadBalancer --name=hello --port=8080
watch kubectl get svc hello -o wide
Providing load-balancers to other charms
Any charm which supports the loadbalancer
interface can request an Azure-backed
load-balancer. For example, you can use an Azure LB to run Vault in HA mode with this:
applications:
vault:
charm: cs:vault
num_units: 3
azure-integrator:
charm: cs:azure-integrator
num_units: 1
trust: true
relations:
- ["vault:lb-provider", "azure-integrator"]
Configuration
name | type | Default | Description |
---|---|---|---|
credentials | string | See notes | |
extra_packages | string | Space separated list of extra deb packages to install. | |
install_keys | string | See notes | See notes |
install_sources | string | See notes | See notes |
package_status | string | install | The status of service-affecting packages will be set to this value in the dpkg database. Valid values are “install” and “hold”. |
subnetName | string | juju-internal-subnet | Vnet’s subnet to be used by azure cloud-integration. This config must be set at deployment and cannot be changed later. |
vnetName | string | See notes | VnetName to be passed via cloud-integration. This config must be set at deployment and cannot be changed later. |
vnetResourceGroup | string | Vnet’s resource group to be passed via cloud-integration. This config must be set at deployment and cannot be changed later. | |
vnetSecurityGroup | string | juju-internal-nsg | Default network sec group (NSG) to be used by azure cloud integration. This config must be set at deployment and cannot be changed later. |
vnetSecurityGroupResourceGroup | string | Default network sec group (NSG) to be used by azure cloud integration. This config must be set at deployment and cannot be changed later. |
credentials
The base64-encoded JSON credentials data, which must include the ‘application-id’,
‘application-password’, and the ‘subscription-id’. Optionally can include managed-identity (default true)
and tenant-id (default ‘’).
These values can be retrieved from Juju using the ‘credentials’ command and extracting the value of the ‘details’
key for the appropriate credential. For example, using ‘jq’, replace ‘
juju credentials --format=json --show-secrets azure | jq '.["local-credentials"]["azure"]["cloud-credentials"]["<credential-name>"]["details"]'
This can be used from bundles with ‘include-base64://’ (see https://juju.is/docs/sdk/bundles), or from the command-line with ‘juju config aws credentials=”$(base64 /path/to/file)”’.
This option will take precedence over the individual config options, if set.
It is strongly recommended that you use ‘juju trust’ instead, if available. since config values can be read by anyone with read access to the model.
install_keys
- |
-----BEGIN PGP PUBLIC KEY BLOCK-----
Version: GnuPG v1.4.7 (GNU/Linux)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=J6gs
-----END PGP PUBLIC KEY BLOCK-----
List of signing keys for install_sources package sources, per charmhelpers standard format (a yaml list of strings encoded as a string). The keys should be the full ASCII armoured GPG public keys. While GPG key ids are also supported and looked up on a keyserver, operators should be aware that this mechanism is insecure. null can be used if a standard package signing key is used that will already be installed on the machine, and for PPA sources where the package signing key is securely retrieved from Launchpad.
install_sources
- deb https://packages.microsoft.com/repos/azure-cli/ {series} main
List of extra apt sources, per charm-helpers standard format (a yaml list of strings encoded as a string). Each source may be either a line that can be added directly to sources.list(5), or in the form ppa:
vnetName
juju-internal-network