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Understanding TargetRef policies
What is a policy?
A policy is a set of configuration that will be used to generate the proxy configuration. Kong Mesh combines policies with dataplane configuration to generate the Envoy configuration of a proxy.
What do targetRef
policies look like?
There are two parts to a policy:
- The metadata
- The spec
Metadata
Metadata identifies the policies by its name
, type
and what mesh
it’s part of:
Spec
The spec
field contains the actual configuration of the policy.
All specs have a top level targetRef
which identifies which proxies this policy applies to.
In particular, it defines which proxies have their Envoy configuration modified.
Some policies also support further narrowing.
The spec.to[].targetRef
field defines rules that applies to outgoing traffic of proxies selected by spec.targetRef
.
The spec.from[].targetRef
field defines rules that applies to incoming traffic of proxies selected by spec.targetRef
.
The actual configuration is defined in a default
map.
For example:
type: ExamplePolicy
name: my-example
mesh: default
spec:
targetRef:
kind: Mesh
to:
- targetRef:
kind: Mesh
default: # Configuration that applies to outgoing traffic
key: value
from:
- targetRef:
kind: Mesh
default: # Configuration that applies to incoming traffic
key: value
Some policies are not directional and will not have to
and from
.
For example
type: NonDirectionalPolicy
name: my-example
mesh: default
spec:
targetRef:
kind: Mesh
default:
key: value
One of the benefits of
targetRef
policies is that the spec is always the same between Kubernetes and Universal.This means that converting policies between Universal and Kubernetes only means rewriting the metadata.
Writing a targetRef
targetRef
is a concept borrowed from Kubernetes Gateway API its usage is fully defined in MADR 005.
Its goal is to select subsets of proxies with maximum flexibility.
It looks like:
targetRef:
kind: Mesh | MeshSubset | MeshService | MeshServiceSubset | MeshGateway
name: "my-name" # For kinds MeshService, MeshServiceSubset and MeshGateway a name has to be defined
tags:
key: value # For kinds MeshServiceSubset, MeshSubset and MeshGateway a list of matching tags can be used
proxyTypes: ["Sidecar", "Gateway"] # For kinds Mesh and MeshSubset a list of matching Dataplanes types can be used
Here’s an explanation of each kinds and their scope:
- Mesh: applies to all proxies running in the mesh
- MeshSubset: same as Mesh but filters only proxies who have matching
targetRef.tags
- MeshService: all proxies with a tag
kuma.io/service
equal totargetRef.name
- MeshServiceSubset: same as
MeshService
but further refine to proxies that have matchingtargetRef.tags
- MeshGateway: targets proxies matched by the named MeshGateway
- Note that it’s very strongly recommended to target MeshGateway proxies using this kind, as opposed to MeshService/MeshServiceSubset.
In Kong Mesh 2.6.x, the targetRef
field gained the ability to select a specific subset of data plane proxies. To further refine policy enforcement, a new field named proxyTypes
has been introduced. It allows you to target policies to specific types of data plane proxies:
-
Sidecar
: Targets data plane proxies acting as sidecars to applications. -
Gateway
: Applies to data plane proxies operating in Gateway mode. - Empty list: Defaults to targeting all data plane proxies.
Consider the example below:
apiVersion: kuma.io/v1alpha1
kind: MeshAccessLog
metadata:
name: example
namespace: kong-mesh-system
labels:
kuma.io/mesh: default
spec:
targetRef: # top level targetRef
kind: MeshService
name: web-frontend
to:
- targetRef: # to level targetRef
kind: MeshService
name: web-backend
default:
backends:
- file:
format:
plain: '{"start_time": "%START_TIME%"}'
path: "/tmp/logs.txt"
from:
- targetRef: # from level targetRef
kind: Mesh
default:
backends:
- file:
format:
plain: '{"start_time": "%START_TIME%"}'
path: "/tmp/logs.txt"
Using spec.targetRef
, this policy targets all proxies that implement the service web-frontend
.
It defines the scope of this policy as applying to traffic either from or to web-frontend
services.
The spec.to.targetRef
section enables logging for any traffic going to web-backend
.
The spec.from.targetRef
section enables logging for any traffic coming from any service in the Mesh
.
Target resources
Not every policy supports to
and from
levels. Additionally, not every resource can
appear at every supported level. The specified top level resource can also affect which
resources can appear in to
or from
.
To help users, each policy documentation includes tables indicating which targetRef
kinds is supported at each level.
For each type of proxy, sidecar or builtin gateway, the table indicates for each
targetRef
level, which kinds are supported.
Example tables
These are just examples, remember to check the docs specific to your policy!
Sidecar
We see that we can select sidecar proxies via any of the kinds that select
sidecars and we can set both to
and from
.
We can apply policy to:
- all traffic originating at the sidecar to anywhere (
to[].targetRef.kind: Mesh
) - traffic to a specific
kuma.io/service
(to[].targetRef.kind: MeshService
)
We can also apply policy to:
- traffic terminating at the sidecar from anywhere in the mesh (
from[].targetRef.kind: Mesh
)
Builtin gateways
We see that we can select gateway proxies via any of the kinds that select
gateways as well as specific gateway listeners and we can set only to
.
We can only apply policy to:
- all traffic originating at the gateway to anywhere (
to[].targetRef.kind: Mesh
)
Merging configuration
It is necessary to define a policy for merging configuration,
because a proxy can be targeted by multiple targetRef
’s.
We define a total order of policy priority:
- MeshServiceSubset > MeshService > MeshSubset > Mesh (the more a
targetRef
is focused the higher priority it has) - If levels are equal the lexicographic order of policy names is used
For to
and from
policies we concatenate the array for each matching policies.
We then build configuration by merging each level using JSON patch merge.
For example if I have 2 default
ordered this way:
default:
conf: 1
sub:
array: [1, 2, 3]
other: 50
other-array: [3, 4, 5]
---
default:
sub:
array: []
other: null
other-array: [5, 6]
extra: 2
The merge result is:
default:
conf: 1
sub:
array: []
other-array: [5, 6]
extra: 2
Examples
Applying a global default
type: ExamplePolicy
name: example
mesh: default
spec:
targetRef:
kind: Mesh
to:
- targetRef:
kind: Mesh
default:
key: value
All traffic from any proxy (top level targetRef
) going to any proxy (to targetRef
) will have this policy applied with value key=value
.
Recommending to users
type: ExamplePolicy
name: example
mesh: default
spec:
targetRef:
kind: Mesh
to:
- targetRef:
kind: MeshService
name: my-service
default:
key: value
All traffic from any proxy (top level targetRef
) going to the service “my-service” (to targetRef
) will have this policy applied with value key=value
.
This is useful when a service owner wants to suggest a set of configurations to its clients.
Configuring all proxies of a team
type: ExamplePolicy
name: example
mesh: default
spec:
targetRef:
kind: MeshSubset
tags:
team: "my-team"
from:
- targetRef:
kind: Mesh
default:
key: value
All traffic from any proxies (from targetRef
) going to any proxy that has the tag team=my-team
(top level targetRef
) will have this policy applied with value key=value
.
This is a useful way to define coarse grain rules for example.
Configuring all proxies in a zone
type: ExamplePolicy
name: example
mesh: default
spec:
targetRef:
kind: MeshSubset
tags:
kuma.io/zone: "east"
default:
key: value
All proxies in zone east
(top level targetRef
) will have this policy configured with key=value
.
This can be very useful when observability stores are different for each zone for example.
Configuring all gateways in a Mesh
type: ExamplePolicy
name: example
mesh: default
spec:
targetRef:
kind: Mesh
proxyTypes: ["Gateway"]
default:
key: value
All gateway proxies in mesh default
will have this policy configured with key=value
.
This can be very useful when timeout configurations for gateways need to differ from those of other proxies.