See first: Juju | Secret
See also: Secret events
This feature is available starting with ops 2.0.0, but only when using Juju 3.0.2 or greater.
This document shows how to use secrets in a charm – both when the charm is the secret owner as well as when it is merely an observer.
Secret owner charm
By its nature, the content in this section only applies to charm secrets.
Add and grant access to a secret
Before secrets, the owner charm might have looked as below:
class MyDatabaseCharm(ops.CharmBase):
def __init__(self, *args, **kwargs):
... # other setup
self.framework.observe(self.on.database_relation_joined,
self._on_database_relation_joined)
... # other methods and event handlers
def _on_database_relation_joined(self, event: ops.RelationJoinedEvent):
event.relation.data[self.app]['username'] = 'admin'
event.relation.data[self.app]['password'] = 'admin' # don't do this at home
With secrets, this can be rewritten as:
class MyDatabaseCharm(ops.CharmBase):
def __init__(self, *args, **kwargs):
... # other setup
self.framework.observe(self.on.database_relation_joined,
self._on_database_relation_joined)
... # other methods and event handlers
def _on_database_relation_joined(self, event: ops.RelationJoinedEvent):
content = {
'username': 'admin',
'password': 'admin',
}
secret = self.app.add_secret(content)
secret.grant(event.relation)
event.relation.data[self.app]['secret-id'] = secret.id
Note that:
- We call
add_secretonself.app(the application). That is because we want the secret to be owned by this application, not by this unit. If we wanted to create a secret owned by the unit, we’d callself.unit.add_secretinstead. - The only data shared in plain text is the secret ID (a locator URI). The secret ID can be publicly shared. Juju will ensure that only remote apps/units to which the secret has explicitly been granted by the owner will be able to fetch the actual secret payload from that ID.
- The secret needs to be granted to a remote entity (app or unit), and that always goes via a relation instance. By passing a relation to
grant(in this case the event’s relation), we are explicitly declaring the scope of the secret – its lifetime will be bound to that of this relation instance.
See more:
ops.Application.add_secret(),
Create a new secret revision
To create a new secret revision, the owner charm must call secret.set_content() and pass in the new payload:
class MyDatabaseCharm(ops.CharmBase):
... # as before
def _rotate_webserver_secret(self, secret):
content = secret.get_content()
secret.set_content({
'username': content['username'], # keep the same username
'password': _generate_new_secure_password(), # something stronger than 'admin'
})
This will inform Juju that a new revision is available, and Juju will inform all observers tracking older revisions that a new one is available, by means of a secret-changed hook.
Change the rotation policy or the expiration date of a secret
Typically you want to rotate a secret periodically to contain the damage from a leak, or to avoid giving hackers too much time to break the encryption.
A charm can configure a secret, at creation time, to have one or both of:
- A rotation policy (weekly, monthly, daily, and so on).
- An expiration date (for example, in two months from now).
Here is what the code would look like:
class MyDatabaseCharm(ops.CharmBase):
def __init__(self, *args, **kwargs):
... # other setup
self.framework.observe(self.on.secret_rotate,
self._on_secret_rotate)
... # as before
def _on_database_relation_joined(self, event: ops.RelationJoinedEvent):
content = {
'username': 'admin',
'password': 'admin',
}
secret = self.app.add_secret(content,
label='secret-for-webserver-app',
rotate=SecretRotate.DAILY)
def _on_secret_rotate(self, event: ops.SecretRotateEvent):
# this will be called once per day.
if event.secret.label == 'secret-for-webserver-app':
self._rotate_webserver_secret(event.secret)
Or, for secret expiration:
class MyDatabaseCharm(ops.CharmBase):
def __init__(self, *args, **kwargs):
... # other setup
self.framework.observe(self.on.secret_expired,
self._on_secret_expired)
... # as before
def _on_database_relation_joined(self, event: ops.RelationJoinedEvent):
content = {
'username': 'admin',
'password': 'admin',
}
secret = self.app.add_secret(content,
label='secret-for-webserver-app',
expire=datetime.timedelta(days=42)) # this can also be an absolute datetime
def _on_secret_expired(self, event: ops.SecretExpiredEvent):
# this will be called only once, 42 days after the relation-joined event.
if event.secret.label == 'secret-for-webserver-app':
self._rotate_webserver_secret(event.secret)
Remove a secret
To remove a secret (effectively destroying it for good), the owner needs to call secret.remove_all_revisions. Regardless of the logic leading to the decision of when to remove a secret, the code will look like some variation of the following:
class MyDatabaseCharm(ops.CharmBase):
...
# called from an event handler
def _remove_webserver_secret(self):
secret = self.model.get_secret(label='secret-for-webserver-app')
secret.remove_all_revisions()
After this is called, the observer charm will get a ModelError whenever it attempts to get the secret. In general, the presumption is that the observer charm will take the absence of the relation as indication that the secret is gone as well, and so will not attempt to get it.
Remove a single secret revision
Removing a single secret revision is a more common (and less drastic!) operation than removing all revisions.
Typically, the owner will remove a secret revision when it receives a secret-remove event – that is, when that specific revision is no longer tracked by any observer. If a secret owner did remove a revision while it was still being tracked by observers, they would get a ModelError when they tried to get the secret.
A typical implementation of the secret-remove event would look like:
class MyDatabaseCharm(ops.CharmBase):
... # as before
def __init__(self, *args, **kwargs):
... # other setup
self.framework.observe(self.on.secret_remove,
self._on_secret_remove)
def _on_secret_remove(self, event: ops.SecretRemoveEvent):
# all observers are done with this revision, remove it
event.secret.remove_revision(event.revision)
Revoke a secret
For whatever reason, the owner of a secret can decide to revoke access to the secret to a remote entity. That is done by calling secret.revoke, and is the inverse of secret.grant.
An example of usage might look like:
class MyDatabaseCharm(ops.CharmBase):
... # as before
# called from an event handler
def _revoke_webserver_secret_access(self, relation):
secret = self.model.get_secret(label='secret-for-webserver-app')
secret.revoke(relation)
Just like when the owner granted the secret, we need to pass a relation to the revoke call, making it clear what scope this action is to be applied to.
Secret observer charm
This applies to both charm and user secrets, though for user secrets the story starts with the charm defining a configuration option of type
secret, and the secret is not acquired through relation data but rather by the configuration option being set to the secret’s URI.A secret owner charm is also an observer of the secret, so this applies to it too.
Start tracking the latest secret revision
Before secrets, the code in the secret observer charm may have looked something like this:
class MyWebserverCharm(ops.CharmBase):
def __init__(self, *args, **kwargs):
... # other setup
self.framework.observe(self.on.database_relation_changed,
self._on_database_relation_changed)
... # other methods and event handlers
def _on_database_relation_changed(self, event: ops.RelationChangedEvent):
username = event.relation.data[event.app]['username']
password = event.relation.data[event.app]['password']
self._configure_db_credentials(username, password)
With secrets, the code would become:
class MyWebserverCharm(ops.CharmBase):
def __init__(self, *args, **kwargs):
... # other setup
self.framework.observe(self.on.database_relation_changed,
self._on_database_relation_changed)
... # other methods and event handlers
def _on_database_relation_changed(self, event: ops.RelationChangedEvent):
secret_id = event.relation.data[event.app]['secret-id']
secret = self.model.get_secret(id=secret_id)
content = secret.get_content()
self._configure_db_credentials(content['username'], content['password'])
Note that:
- The observer charm gets a secret via the model (not its app/unit). Because it’s the owner who decides who the secret is granted to, the ownership of a secret is not an observer concern. The observer code can rightfully assume that, so long as a secret ID is shared with it, the owner has taken care to grant and scope the secret in such a way that the observer has the rights to inspect its contents.
- The charm first gets the secret object from the model, then gets the secret’s content (a dict) and accesses individual attributes via the dict’s items.
See more:
ops.Secret.get_content()
Label the secrets you’re observing
Sometimes a charm will observe multiple secrets. In the secret-changed event handler above, you might ask yourself: How do I know which secret has changed?
The answer lies with secret labels: a label is a charm-local name that you can assign to a secret. Let’s go through the following code:
class MyWebserverCharm(ops.CharmBase):
... # as before
def _on_database_relation_changed(self, event: ops.RelationChangedEvent):
secret_id = event.relation.data[event.app]['secret-id']
secret = self.model.get_secret(id=secret_id, label='database-secret')
content = secret.get_content()
self._configure_db_credentials(content['username'], content['password'])
def _on_secret_changed(self, event: ops.SecretChangedEvent):
if event.secret.label == 'database-secret':
content = event.secret.get_content(refresh=True)
self._configure_db_credentials(content['username'], content['password'])
elif event.secret.label == 'my-other-secret':
self._handle_other_secret_changed(event.secret)
else:
pass # ignore other labels (or log a warning)
As shown above, when the web server charm calls get_secret it can specify an observer-specific label for that secret; Juju will attach this label to the secret at that point. Normally get_secret is called for the first time in a relation-changed event; the label is applied then, and subsequently used in a secret-changed event.
Labels are unique to the charm (the observer in this case): if you attempt to attach a label to two different secrets from the same application (whether it’s the on the observer side or the owner side) and give them the same label, the framework will raise a ModelError.
Whenever a charm receives an event concerning a secret for which it has set a label, the label will be present on the secret object exposed by the framework.
The owner of the secret can do the same. When a secret is added, you can specify a label for the newly-created secret:
class MyDatabaseCharm(ops.CharmBase):
... # as before
def _on_database_relation_joined(self, event: ops.RelationJoinedEvent):
content = {
'username': 'admin',
'password': 'admin',
}
secret = self.app.add_secret(content, label='secret-for-webserver-app')
secret.grant(event.relation)
event.relation.data[event.unit]['secret-id'] = secret.id
If a secret has been labelled in this way, the charm can retrieve the secret object at any time by calling get_secret with the “label” argument. This way, a charm can perform any secret management operation even if all it knows is the label. The secret ID is normally only used to exchange a reference to the secret between applications. Within a single application, all you need is the secret label.
So, having labelled the secret on creation, the database charm could add a new revision as follows:
def _rotate_webserver_secret(self):
secret = self.model.get_secret(label='secret-for-webserver-app')
secret.set_content(...) # pass a new revision payload, as before
See more:
ops.Model.get_secret()
When to use labels
When should you use labels? A label is basically the secret’s name (local to the charm), so whenever a charm has, or is observing, multiple secrets you should label them. This allows you to distinguish between secrets, for example, in the SecretChangedEvent shown above.
Most charms that use secrets have a fixed number of secrets each with a specific meaning, so the charm author should give them meaningful labels like database-credential, tls-cert, and so on. Think of these as “pets” with names.
In rare cases, however, a charm will have a set of secrets all with the same meaning: for example, a set of TLS certificates that are all equally valid. In this case it doesn’t make sense to label them – think of them as “cattle”. To distinguish between secrets of this kind, you can use the Secret.unique_identifier property, added in ops 2.6.0.
Note that Secret.id, despite the name, is not really a unique ID, but a locator URI. We call this the “secret ID” throughout Juju and in the original secrets specification – it probably should have been called “uri”, but the name stuck.
Peek at a new secret revision
Sometimes, before reconfiguring to use a new credential revision, the observer charm may want to peek at its contents (for example, to ensure that they are valid). Use peek_content for that:
def _on_secret_changed(self, event: ops.SecretChangedEvent):
content = event.secret.peek_content()
if not self._valid_password(content.get('password')):
logger.warning('Invalid credentials! Not updating to new revision.')
return
content = event.secret.get_content(refresh=True)
...
See more:
ops.Secret.peek_content()
Start tracking a different secret revision
To update to a new revision, the web server charm will typically subscribe to the secret-changed event and call get_content with the “refresh” argument set (refresh asks Juju to start tracking the latest revision for this observer).
class MyWebserverCharm(ops.CharmBase):
def __init__(self, *args, **kwargs):
... # other setup
self.framework.observe(self.on.secret_changed,
self._on_secret_changed)
... # as before
def _on_secret_changed(self, event: ops.SecretChangedEvent):
content = event.secret.get_content(refresh=True)
self._configure_db_credentials(content['username'], content['password'])
See more:
ops.Secret.get_content()
Contributors: @ppasotti, @tmihoc, @tony-meyer, @wallyworld