This repo has been merged into istio.io/istio/cni. Please go to that repo to make any changes to CNI. The only exception is bug backports to branches <= 1.6, which should be submitted here. The text below is preserved for reference but is no longer maintained at this location.
For application pods in the Istio service mesh, all traffic to/from the pods needs to go through the
sidecar proxies (istio-proxy containers). This istio-cni
Container Network Interface (CNI) plugin will
set up the pods' networking to fulfill this requirement in place of the current Istio injected pod initContainers
istio-init
approach.
This is currently accomplished (for IPv4) via configuring the iptables rules in the netns for the pods.
The CNI handling the netns setup replaces the current Istio approach using a NET_ADMIN
privileged
initContainers
container, istio-init
, injected in the pods along with istio-proxy
sidecars. This
removes the need for a privileged, NET_ADMIN
container in the Istio users' application pods.
A complete set of instructions on how to use and install the Istio CNI is available on the Istio documentation site under Install Istio with the Istio CNI plugin. Only a summary is provided here. The steps are:
-
Install Kubernetes and
kubelet
in a manner that can support the CNI -
Install Kubernetes with the ServiceAccount admission controller enabled
-
Install the Istio CNI components. A specific example assuming locally built CNI images would be:
$ CNI_HUB=docker.io/my_userid $ CNI_TAG=mytag # run from the ${GOPATH}/src/istio.io/cni dir (repo where istio/cni was cloned) $ helm template --name=istio-cni --namespace=kube-system --set "excludeNamespaces={}" --set hub=${CNI_HUB} --set tag=${CNI_TAG} --set pullPolicy=IfNotPresent --set logLevel=debug deployments/kubernetes/install/helm/istio-cni > istio-cni_install.yaml $ kubectl apply -f istio-cni_install.yaml
-
Create and apply Istio manifests with the Istio CNI plugin enabled using the
--set istio_cni.enabled=true
Helm variable
For most Kubernetes environments the istio-cni
helm parameters' defaults will configure the Istio CNI plugin in a manner compatible with the Kubernetes installation. Refer to
the Hosted Kubernetes Usage section for Kubernetes environment specific procedures.
Helm chart parameters:
Option | Values | Default | Description |
---|---|---|---|
hub | The container registry to pull the install-cni image. |
||
tag | The container tag to use to pull the install-cni image. |
||
logLevel | panic , fatal , error , warn , info , debug |
warn |
Logging level for CNI binary |
excludeNamespaces | []string |
[ istio-system ] |
List of namespaces to exclude from Istio pod check |
cniBinDir | /opt/cni/bin |
Must be the same as the environment's --cni-bin-dir setting (kubelet param) |
|
cniConfDir | /etc/cni/net.d |
Must be the same as the environment's --cni-conf-dir setting (kubelet param) |
|
cniConfFileName | None | Leave unset to auto-find the first file in the cni-conf-dir (as kubelet does). Primarily used for testing install-cni plugin config. If set, install-cni will inject the plugin config into this file in the cni-conf-dir |
|
psp_cluster_role | A ClusterRole that sets the according use of PodSecurityPolicy for the ServiceAccount |
||
chained | true or false |
true |
Whether to deploy the config file as a plugin chain or as a standalone file in the conf dir. Some k8s flavors (e.g. OpenShift) do not support the chain approach, set to false if this is the case. |
Not all hosted Kubernetes clusters are created with the kubelet
configured to use the CNI plugin so
compatibility with this istio-cni
solution is not ubiquitous. The istio-cni
plugin is expected
to work with any hosted kubernetes leveraging CNI plugins. The below table indicates the known CNI status
of hosted Kubernetes environments and whether istio-cni
has been trialed in the cluster type.
Hosted Cluster Type | Uses CNI | istio-cni tested? |
---|---|---|
GKE 1.9.7-gke.6 default | N | N |
GKE 1.9.7-gke.6 w/ network-policy | Y | Y |
IKS (IBM cloud) | Y | Y (on k8s 1.10) |
EKS (AWS) | Y | N |
AKS (Azure) | Y | N |
Red Hat OpenShift 3.10 | Y | Y |
-
Enable network-policy in your cluster. NOTE: for existing clusters this redeploys the nodes.
-
Make sure your kubectl user (service-account) has a ClusterRoleBinding to the
cluster-admin
role. This is also a typical pre-requisite for installing Istio on GKE.kubectl create clusterrolebinding cni-cluster-admin-binding --clusterrole=cluster-admin [email protected]
- User
[email protected]
is an admin user associated with the gcloud GKE cluster
- User
-
Create the Istio CNI manifests with this Helm chart option
--set cniBinDir=/home/kubernetes/bin
No special set up is required for IKS, as it currently uses the default cni-conf-dir
and cni-bin-dir
.
Add the following section into istio-cni.yaml
to run the install-cni
DaemonSet container as privileged so that it has proper write permission in the host filesystem:
securityContext:
privileged: true
- Grant privileged permission to
istio-cni
service account:
$ oc adm policy add-scc-to-user privileged -z istio-cni -n kube-system
First, clone this repository under $GOPATH/src/istio.io/
.
For linux targets:
$ GOOS=linux make build
You can also build the project from a non-standard location like so:
$ ISTIO_CNI_RELPATH=github.com/some/cni GOOS=linux make build
To push the Docker image:
$ export HUB=docker.io/myuser
$ export TAG=dev
$ GOOS=linux make docker.push
NOTE: Set HUB and TAG per your docker registry.
The Helm package tarfile can be created via
$ helm package $GOPATH/src/istio.io/cni/deployments/kubernetes/install/helm/istio-cni
An example for hosting a test repo for the Helm istio-cni package:
-
Create package tarfile with
helm package $GOPATH/src/istio.io/cni/deployments/kubernetes/install/helm/istio-cni
-
Copy tarfile to dir to serve the repo from
-
Run
helm serve --repo-path <dir where helm tarfile is> &
- The repo URL will be output (
http://127.0.0.1:8879
) - (optional) Use the
--address <IP>:<port>
option to bind the server to a specific address/port
- The repo URL will be output (
To use this repo via helm install
:
$ helm repo add local_istio http://127.0.0.1:8879
$ helm repo update
At this point the istio-cni
chart is ready for use by helm install
.
To make use of the istio-cni
chart from another chart:
-
Add the following to the other chart's
requirements.yaml
:- name: istio-cni version: ">=0.0.1" repository: http://127.0.0.1:8879 condition: istio-cni.enabled
-
Run
helm dependency update <chart>
on the chart that needs to depend on istio-cni.- NOTE: for istio/istio the charts
need to be reorganized to make
helm dependency update
work. The child charts (pilot, galley, etc) need to be made independent charts in the directorkefiy at the same level as the mainistio
chart (istio/istio#9306).
- NOTE: for istio/istio the charts
need to be reorganized to make
The Istio CNI testing strategy and execution details are explained here.
-
Collect your pod's container id using kubectl.
$ ns=test-istio $ podnm=reviews-v1-6b7f6db5c5-59jhf $ container_id=$(kubectl get pod -n ${ns} ${podnm} -o jsonpath="{.status.containerStatuses[?(@.name=='istio-proxy')].containerID}" | sed -n 's/docker:\/\/\(.*\)/\1/p')
-
SSH into the Kubernetes worker node that runs your pod.
-
Use
nsenter
to view the iptables.$ cpid=$(docker inspect --format '{{ .State.Pid }}' $container_id) $ nsenter -t $cpid -n iptables -L -t nat -n -v --line-numbers -x
The CNI plugins are executed by threads in the kubelet
process. The CNI plugins logs end up the syslog
under the kubelet
process. On systems with journalctl
the following is an example command line
to view the last 1000 kubelet
logs via the less
utility to allow for vi
-style searching:
$ journalctl -t kubelet -n 1000 | less
Each GKE cluster's will have many categories of logs collected by Stackdriver. Logs can be monitored via
the project's log viewer and/or the gcloud logging read
capability.
The following example grabs the last 10 kubelet
logs containing the string "cmdAdd" in the log message.
$ gcloud logging read "resource.type=gce_instance AND jsonPayload.SYSLOG_IDENTIFIER=kubelet AND jsonPayload.MESSAGE:cmdAdd" --limit 10 --format json
-
- Helm chart manifest for deploying
install-cni
container as daemonset istio-cni-config
configmap with CNI plugin config to add to CNI plugin chained config- creates service-account
istio-cni
withClusterRoleBinding
to allow gets on pods' info
- Helm chart manifest for deploying
-
install-cni
container- copies
istio-cni
binary andistio-iptables.sh
to/opt/cni/bin
- creates kubeconfig for the service account the pod is run under
- injects the CNI plugin config to the config file pointed to by CNI_CONF_NAME env var
- example:
CNI_CONF_NAME: 10-calico.conflist
jq
is used to insertCNI_NETWORK_CONFIG
into theplugins
list in/etc/cni/net.d/${CNI_CONF_NAME}
- example:
- copies
-
istio-cni
- CNI plugin executable copied to
/opt/cni/bin
- currently implemented for k8s only
- on pod add, determines whether pod should have netns setup to redirect to Istio proxy
- if so, calls
istio-iptables.sh
with params to setup pod netns
- if so, calls
- CNI plugin executable copied to
-
- sets up iptables to redirect a list of ports to the port envoy will listen
The framework for this implementation of the CNI plugin is based on the containernetworking sample plugin.
The Istio makefiles and container build logic was leveraged heavily/lifted for this repo.
Specifically:
- golang build logic
- multi-arch target logic
- k8s lib versions (Gopkg.toml)
- docker container build logic
- setup staging dir for docker build
- grab built executables from target dir and cp to staging dir for docker build
- tagging and push logic
The details for the deployment & installation of this plugin were pretty much lifted directly from the Calico CNI plugin.
Specifically:
- CNI installation script
- This does the following
- sets up CNI conf in /host/etc/cni/net.d/*
- copies calico CNI binaries to /host/opt/cni/bin
- builds kubeconfig for CNI plugin from service-account info mounted in the pod: https://github.com/projectcalico/cni-plugin/blob/master/k8s-install/scripts/install-cni.sh#L142
- reference: https://kubernetes.io/docs/reference/access-authn-authz/service-accounts-admin/
- This does the following
- The CNI installation script is containerized and deployed as a daemonset in k8s. The relevant
calico k8s manifests were used as the model for the istio-cni plugin's manifest:
- daemonset and configmap
- search for the
calico-node
Daemonset and itsinstall-cni
container deployment
- search for the
- RBAC
- this creates the service account the CNI plugin is configured to use to access the kube-api-server
- daemonset and configmap
The installation script install-cni.sh
injects the istio-cni
plugin config at the end of the CNI plugin chain
config. It creates or modifies the file from the configmap created by the Kubernetes manifest.
Workflow:
-
Check k8s pod namespace against exclusion list (plugin config)
- Config must exclude namespace that Istio control-plane is installed in
- If excluded, ignore the pod and return prevResult
-
Setup redirect rules for the pods:
- Get the port list from pods definition
- Setup iptables with required port list:
nsenter --net=<k8s pod netns> /opt/cni/bin/istio-iptables.sh ...
Following conditions will prevent the redirect rules to be setup in the pods:
1. Pods only have 1 container(no sidecar proxy injected) 2. Pods have annotation `sidecar.istio.io/inject` set to `false` or has no key `sidecar.istio.io/status` in annotations 3. Pod has `istio-init` initContainer 4. Pods are in one of the namespaces specified in the `exclude_namespaces` parameter of the `istio-cni` plugin config
-
Return prevResult
TBD istioctl / auto-sidecar-inject logic for handling things like specific include/exclude IPs and any other features.
- Watch configmaps or CRDs and update the
istio-cni
plugin's config with these options.
Anything needed? The netns is destroyed by kubelet
so ideally this is a NOOP.
The plugin leverages logrus
& directly utilizes some Calico logging lib util functions.
The proposed Istio pod network controller has the problem of synchronizing the netns setup with the rest of the pod init. This approach requires implementing custom synchronization between the controller and pod initialization.
Kubernetes has already solved this problem by not starting any containers in new pods until the full CNI plugin chain has completed successfully. Also, architecturally, the CNI plugins are the components responsible for network setup for container runtimes.