Following is the example of multus config file, in /etc/cni/net.d/
.
("Note1"
and "Note2"
are just comments, so you can remove them at your configuration)
{
"cniVersion": "0.3.1",
"name": "node-cni-network",
"type": "multus",
"kubeconfig": "/etc/kubernetes/node-kubeconfig.yaml",
"confDir": "/etc/cni/multus/net.d",
"cniDir": "/var/lib/cni/multus",
"binDir": "/opt/cni/bin",
"logFile": "/var/log/multus.log",
"logLevel": "debug",
"logOptions": {
"maxAge": 5,
"maxSize": 100,
"maxBackups": 5,
"compress": true
},
"capabilities": {
"portMappings": true
},
"readinessindicatorfile": "",
"namespaceIsolation": false,
"Note1":"NOTE: you can set clusterNetwork+defaultNetworks OR delegates!!",
"clusterNetwork": "defaultCRD",
"defaultNetworks": ["sidecarCRD", "flannel"],
"systemNamespaces": ["kube-system", "admin"],
"multusNamespace": "kube-system",
"Note2":"NOTE: If you use clusterNetwork/defaultNetworks, delegates is ignored",
"delegates": [{
"type": "weave-net",
"hairpinMode": true
}, {
"type": "macvlan",
... (snip)
}]
}
name
(string, required): the name of the networktype
(string, required): "multus"confDir
(string, optional): directory for CNI config file that multus reads. default/etc/cni/multus/net.d
cniDir
(string, optional): Multus CNI data directory, default/var/lib/cni/multus
binDir
(string, optional): additional directory for CNI plugins which multus calls, in addition to the default (the default is typically set to/opt/cni/bin
)kubeconfig
(string, optional): kubeconfig file for the out of cluster communication with kube-apiserver. See the example kubeconfig. If you would like to use CRD (i.e. network attachment definition), this is requiredlogToStderr
(bool, optional): Enable or disable logging toSTDERR
. Defaults to true.logFile
(string, optional): file path for log file. multus puts log in given filelogLevel
(string, optional): logging level ("debug", "error", "verbose", or "panic")logOptions
(object, optional): logging option, More detailed log configurationnamespaceIsolation
(boolean, optional): Enables a security feature where pods are only allowed to accessNetworkAttachmentDefinitions
in the namespace where the pod resides. Defaults to false.capabilities
({}list, optional): capabilities supported by at least one of the delegates. (NOTE: Multus only supports portMappings/Bandwidth capability for cluster networks).readinessindicatorfile
: The path to a file whose existence denotes that the default network is ready
User should chose following parameters combination (clusterNetwork
+defaultNetworks
or delegates
):
clusterNetwork
(string, required): default CNI network for pods, used in kubernetes cluster (Pod IP and so on): name of network-attachment-definition, CNI json file name (without extension, .conf/.conflist) or directory for CNI config filedefaultNetworks
([]string, required): default CNI network attachment: name of network-attachment-definition, CNI json file name (without extension, .conf/.conflist) or directory for CNI config filesystemNamespaces
([]string, optional): list of namespaces for Kubernetes system (namespaces listed here will not havedefaultNetworks
added)multusNamespace
(string, optional): namespace forclusterNetwork
/defaultNetworks
delegates
([]map,required): number of delegate details in the Multus
Multus will find network for clusterNetwork/defaultNetworks as following sequences:
- CRD object for given network name, in 'kube-system' namespace
- CNI json config file in
confDir
. Given name should be without extension, like .conf/.conflist. (e.g. "test" for "test.conf"). The given name forclusterNetwork
should match the value forname
key in the config file (e.g."name": "test"
in "test.conf" when"clusterNetwork": "test"
) - Directory for CNI json config file. Multus will find alphabetically first file for the network
- Multus failed to find network. Multus raise error message
You may wish for your "default network" (that is, the CNI plugin & its configuration you specify as your default delegate) to become ready before you attach networks with Multus. This is disabled by default and not used unless you add the readiness check option(s) to your CNI configuration file.
For example, if you use Flannel as a default network, the recommended method for Flannel to be installed is via a daemonset that also drops a configuration file in /etc/cni/net.d/
. This may apply to other plugins that place that configuration file upon their readiness, hence, Multus uses their configuration filename as a semaphore and optionally waits to attach networks to pods until that file exists.
In this manner, you may prevent pods from crash looping, and instead wait for that default network to be ready.
Only one option is necessary to configure this functionality:
readinessindicatorfile
: The path to a file whose existence denotes that the default network is ready.
NOTE: If readinessindicatorfile
is unset, or is an empty string, this functionality will be disabled, and is disabled by default.
You may wish to enable some enhanced logging for Multus, especially during the process where you're configuring Multus and need to understand what is or isn't working with your particular configuration.
By default, Multus will log via STDERR
, which is the standard method by which CNI plugins communicate errors, and these errors are logged by the Kubelet.
Optionally, you may disable this method by setting the logToStderr
option in your CNI configuration:
"logToStderr": false,
Optionally, you may have Multus log to a file on the filesystem. This file will be written locally on each node where Multus is executed. You may configure this via the LogFile
option in the CNI configuration. By default this additional logging to a flat file is disabled.
For example in your CNI configuration, you may set:
"logFile": "/var/log/multus.log",
The default logging level is set as panic
-- this will log only the most critical errors, and is the least verbose logging level.
The available logging level values, in decreasing order of verbosity are:
debug
verbose
error
panic
You may configure the logging level by using the LogLevel
option in your CNI configuration. For example:
"logLevel": "debug",
If you want a more detailed configuration of the logging, This includes the following parameters:
maxAge
the maximum number of days to retain old log files in their filenamemaxSize
the maximum size in megabytes of the log file before it gets rotatedmaxBackups
the maximum number of days to retain old log files in their filenamecompress
compress determines if the rotated log files should be compressed using gzip
For example in your CNI configuration, you may set:
"logOptions": {
"maxAge": 5,
"maxSize": 100,
"maxBackups": 5,
"compress": true
}
The functionality provided by the namespaceIsolation
configuration option enables a mode where Multus only allows pods to access custom resources (the NetworkAttachmentDefinitions
) within the namespace where that pod resides. In other words, the NetworkAttachmentDefinitions
are isolated to usage within the namespace in which they're created.
NOTE: The default namespace is special in this scenario. Even with namespace isolation enabled, any pod, in any namespace is allowed to refer to NetworkAttachmentDefinitions
in the default namespace. This allows you to create commonly used unprivileged NetworkAttachmentDefinitions
without having to put them in all namespaces. For example, if you had a NetworkAttachmentDefinition
named foo
the default namespace, you may reference it in an annotation with: default/foo
.
NOTE: You can also add additional namespaces which can be referred to globally using the global-namespaces
option (see next section).
For example, if a pod is created in the namespace called development
, Multus will not allow networks to be attached when defined by custom resources created in a different namespace, say in the default
network.
Consider the situation where you have a system that has users of different privilege levels -- as an example, a platform which has two administrators: a Senior Administrator and a Junior Administrator. The Senior Administrator may have access to all namespaces, and some network configurations as used by Multus are considered to be privileged in that they allow access to some protected resources available on the network. However, the Junior Administrator has access to only a subset of namespaces, and therefore it should be assumed that the Junior Administrator cannot create pods in their limited subset of namespaces. The namespaceIsolation
feature provides for this isolation, allowing pods created in given namespaces to only access custom resources in the same namespace as the pod.
Namespace Isolation is disabled by default.
"namespaceIsolation": true,
Let's setup an example where we:
- Create a custom resource in a namespace called
privileged
- Create a pod in a namespace called
development
, and have annotations that reference a custom resource in theprivileged
namespace. The creation of this pod should be disallowed by Multus (as we'll have the use of the custom resources limited only to those custom resources created within the same namespace as the pod).
Given the above scenario with a Junior & Senior Administrator. You may assume that the Senior Administrator has access to all namespaces, whereas the Junior Administrator has access only to the development
namespace.
Firstly, we show that we have a number of namespaces available:
# List the available namespaces
[user@kube-master ~]$ kubectl get namespaces
NAME STATUS AGE
default Active 7h27m
development Active 3h
kube-public Active 7h27m
kube-system Active 7h27m
privileged Active 4s
We'll create a NetworkAttachmentDefinition
in the privileged
namespace.
# Show the network attachment definition we're creating.
[user@kube-master ~]$ cat cr.yml
apiVersion: "k8s.cni.cncf.io/v1"
kind: NetworkAttachmentDefinition
metadata:
name: macvlan-conf
spec:
config: '{
"cniVersion": "0.3.0",
"type": "macvlan",
"master": "eth0",
"mode": "bridge",
"ipam": {
"type": "host-local",
"subnet": "192.168.1.0/24",
"rangeStart": "192.168.1.200",
"rangeEnd": "192.168.1.216",
"routes": [
{ "dst": "0.0.0.0/0" }
],
"gateway": "192.168.1.1"
}
}'
# Create that network attachment definition in the privileged namespace
[user@kube-master ~]$ kubectl create -f cr.yml -n privileged
networkattachmentdefinition.k8s.cni.cncf.io/macvlan-conf created
# List the available network attachment definitions in the privileged namespace.
[user@kube-master ~]$ kubectl get networkattachmentdefinition.k8s.cni.cncf.io -n privileged
NAME AGE
macvlan-conf 11s
Next, we'll create a pod with an annotation that references the privileged namespace. Pay particular attention to the annotation that reads k8s.v1.cni.cncf.io/networks: privileged/macvlan-conf
-- where it contains a reference to a namespace/configuration-name
formatted network attachment name. In this case referring to the macvlan-conf
in the namespace called privileged
.
# Show the yaml for a pod.
[user@kube-master ~]$ cat example.pod.yml
apiVersion: v1
kind: Pod
metadata:
name: samplepod
annotations:
k8s.v1.cni.cncf.io/networks: privileged/macvlan-conf
spec:
containers:
- name: samplepod
command: ["/bin/bash", "-c", "sleep 2000000000000"]
image: dougbtv/centos-network
# Create that pod.
[user@kube-master ~]$ kubectl create -f example.pod.yml -n development
pod/samplepod created
You'll note that pod fails to spawn successfully. If you check the Multus logs, you'll see an entry such as:
2018-12-18T21:41:32Z [error] GetNetworkDelegates: namespace isolation enabled, annotation violates permission, pod is in namespace development but refers to target namespace privileged
This error expresses that the pod resides in the namespace named development
but refers to a NetworkAttachmentDefinition
outside of that namespace, in this case, the namespace named privileged
.
In a positive example, you'd instead create the NetworkAttachmentDefinition
in the development
namespace, and you'd have an annotation that either A. does not reference a namespace, or B. refers to the same annotation.
A positive example may be:
# Create the same NetworkAttachmentDefinition as above, however in the development namespace
[user@kube-master ~]$ kubectl create -f cr.yml -n development
networkattachmentdefinition.k8s.cni.cncf.io/macvlan-conf created
# Show the yaml for a sample pod which references macvlan-conf without a namspace/ format
[user@kube-master ~]$ cat positive.example.pod
apiVersion: v1
kind: Pod
metadata:
name: samplepod
annotations:
k8s.v1.cni.cncf.io/networks: macvlan-conf
spec:
containers:
- name: samplepod
command: ["/bin/bash", "-c", "sleep 2000000000000"]
image: dougbtv/centos-network
# Create that pod.
[user@kube-master ~]$ kubectl create -f positive.example.pod -n development
pod/samplepod created
# We can see that this pod has been launched successfully.
[user@kube-master ~]$ kubectl get pods -n development
NAME READY STATUS RESTARTS AGE
samplepod 1/1 Running 0 31s
The globalNamespaces
configuration option is only used when namespaceIsolation
is set to true. globalNamespaces
specifies a comma-delimited list of namespaces which can be referred to from outside of any given namespace in which a pod resides.
"globalNamespaces": "default,namespace-a,namespace-b",
Note that when using globalNamespaces
the default
namespace must be specified in the list if you wish to use that namespace, when globalNamespaces
is not set, the default
namespace is implied to be used across namespaces.
Users may also specify the default network for any given pod (via annotation), for cases where there are multiple cluster networks available within a Kubernetes cluster.
Example use cases may include:
- During a migration from one default network to another (e.g. from Flannel to Calico), it may be practical if both network solutions are able to operate in parallel. Users can then control which network a pod should attach to during the transition period.
- Some users may deploy multiple cluster networks for the sake of their security considerations, and may desire to specify the default network for individual pods.
Follow these steps to specify the default network on a pod-by-pod basis:
-
First, you need to define all your cluster networks as network-attachment-definition objects.
-
Next, you can specify the network you want in pods with the
v1.multus-cni.io/default-network
annotation. Pods which do not specify this annotation will keep using the CNI as defined in the Multus config file.
apiVersion: v1
kind: Pod
metadata:
name: pod-example
annotations:
v1.multus-cni.io/default-network: calico-conf
...