Multi-network Mesh Expansion
- Prerequisites
- Installation steps
  - Customized installation of Istio on the Cluster
  - Setup DNS
  - Setting up the VM
- Added Istio resources
- Expose service running on cluster to VMs
- Send requests from VM to Kubernetes services
- Running services on a mesh expansion machine
- Cleanup
- 相关内容

Multi-network Mesh Expansion

This example provides instructions to integrate VMs and bare metal hosts intoan Istio mesh deployed on Kubernetes with gateways. No VPN connectivity nor direct network access between workloads inVMs, bare metals and clusters is required.

Prerequisites

One or more Kubernetes clusters with versions: 1.13, 1.14, 1.15.
Mesh expansion machines must have IP connectivity to the Ingress gateways in the mesh.
Install the Helm client. Helm is needed to enable mesh expansion.

Installation steps

Setup consists of preparing the mesh for expansion and installing and configuring each VM.

Customized installation of Istio on the Cluster

The first step when adding non-Kubernetes services to an Istio mesh is to configure the Istio installation itself, andgenerate the configuration files that let mesh expansion VMs connect to the mesh. To prepare thecluster for mesh expansion, run the following commands on a machine with cluster admin privileges:

Generate a meshexpansion-gateways Istio configuration file using helm:

$ helm template install/kubernetes/helm/istio --name istio --namespace istio-system \
    -f https://github.com/irisdingbj/meshExpansion/blob/master/values-istio-meshexpansion-gateways.yaml \ > $HOME/istio-mesh-expansion-gatways.yaml

For further details and customization options, refer to theInstallation with Helm instructions.

Deploy Istio control plane into the cluster

$ kubectl create namespace istio-system
$ helm template  install/kubernetes/helm/istio-init --name istio-init --namespace istio-system  | kubectl apply -f -
$ kubectl apply -f $HOME/istio-mesh-expansion-gatways.yaml

Verify Istio is installed successfully

$ istioctl verify-install -f $HOME/istio-mesh-expansion-gatways.yaml

Create vm namespace for the VM services.

$ kubectl create ns vm

Define the namespace the VM joins. This example uses the SERVICE_NAMESPACE environment variable to store the namespace. The value of this variable must match the namespace you use in the configuration files later on.

$ export SERVICE_NAMESPACE="vm"

Extract the initial keys the service account needs to use on the VMs.

$ kubectl -n $SERVICE_NAMESPACE get secret istio.default  \
    -o jsonpath='{.data.root-cert\.pem}' | base64 --decode > root-cert.pem
$ kubectl -n $SERVICE_NAMESPACE get secret istio.default  \
    -o jsonpath='{.data.key\.pem}' | base64 --decode > key.pem
$ kubectl -n $SERVICE_NAMESPACE get secret istio.default  \
      -o jsonpath='{.data.cert-chain\.pem}' | base64 --decode > cert-chain.pem

Determine and store the IP address of the Istio ingress gateway since the mesh expansion machines access Citadel and Pilot and workloads on cluster through this IP address.

$ export GWIP=$(kubectl get -n istio-system service istio-ingressgateway -o jsonpath='{.status.loadBalancer.ingress[0].ip}')
$ echo $GWIP
35.232.112.158

Generate a cluster.env configuration to deploy in the VMs. This file contains the Kubernetes cluster IP address rangesto intercept and redirect via Envoy.

$ echo -e "ISTIO_CP_AUTH=MUTUAL_TLS\nISTIO_SERVICE_CIDR=$ISTIO_SERVICE_CIDR\n" > cluster.env

Check the contents of the generated cluster.env file. It should be similar to the following example:

$ cat cluster.env
ISTIO_CP_AUTH=MUTUAL_TLS
ISTIO_SERVICE_CIDR=172.21.0.0/16

Setup DNS

Providing DNS resolution to allow services running on VM can access theservices running in the cluster. Istio itself does not use the DNS forrouting requests between services. Services local to a cluster share acommon DNS suffix(e.g., svc.cluster.local). Kubernetes DNS providesDNS resolution for these services.

To provide a similar setup to allow services accessible from VMs, you nameservices in the clusters in the format<name>.<namespace>.global. Istio also ships with a CoreDNS server thatwill provide DNS resolution for these services. In order to utilize thisDNS, Kubernetes’ DNS must be configured to stub a domain for .global.

Some cloud providers have different specific DNS domain stub capabilitiesand procedures for their Kubernetes services. Reference the cloud provider’sdocumentation to determine how to stub DNS domains for each uniqueenvironment. The objective of this bash is to stub a domain for .global onport 53 to reference or proxy the istiocoredns service in Istio’s servicenamespace.

Create one of the following ConfigMaps, or update an existing one, in eachcluster that will be calling services in remote clusters(every cluster in the general case):

For clusters that use kube-dns:

$ kubectl apply -f - <<EOF
apiVersion: v1
kind: ConfigMap
metadata:
  name: kube-dns
  namespace: kube-system
data:
  stubDomains: |
    {"global": ["$(kubectl get svc -n istio-system istiocoredns -o jsonpath={.spec.clusterIP})"]}
EOF

For clusters that use CoreDNS:

$ kubectl apply -f - <<EOF
apiVersion: v1
kind: ConfigMap
metadata:
  name: coredns
  namespace: kube-system
data:
  Corefile: |
    .:53 {
        errors
        health
        kubernetes cluster.local in-addr.arpa ip6.arpa {
           pods insecure
           upstream
           fallthrough in-addr.arpa ip6.arpa
        }
        prometheus :9153
        proxy . /etc/resolv.conf
        cache 30
        loop
        reload
        loadbalance
    }
    global:53 {
        errors
        cache 30
        proxy . $(kubectl get svc -n istio-system istiocoredns -o jsonpath={.spec.clusterIP})
    }
EOF

Setting up the VM

Next, run the following commands on each machine that you want to add to the mesh:

Copy the previously created cluster.env and *.pem files to the VM.
Install the Debian package with the Envoy sidecar.

$ curl -L https://storage.googleapis.com/istio-release/releases/1.4.0/deb/istio-sidecar.deb > istio-sidecar.deb
$ sudo dpkg -i istio-sidecar.deb

Add the IP address of the Istio gateway to /etc/hosts. Revisit the Customized installation of Istio on the Cluster section to learn how to obtain the IP address.The following example updates the /etc/hosts file with the Istio gateway address:

$ echo "35.232.112.158 istio-citadel istio-pilot istio-pilot.istio-system" | sudo tee -a /etc/hosts

Install root-cert.pem, key.pem and cert-chain.pem under /etc/certs/.

$ sudo mkdir -p /etc/certs
$ sudo cp {root-cert.pem,cert-chain.pem,key.pem} /etc/certs

Install cluster.env under /var/lib/istio/envoy/.

$ sudo cp cluster.env /var/lib/istio/envoy

Transfer ownership of the files in /etc/certs/ and /var/lib/istio/envoy/ to the Istio proxy.

$ sudo chown -R istio-proxy /etc/certs /var/lib/istio/envoy

Verify the node agent works:

$ sudo node_agent
....
CSR is approved successfully. Will renew cert in 1079h59m59.84568493s

Start Istio using systemctl.

$ sudo systemctl start istio-auth-node-agent
$ sudo systemctl start istio

Added Istio resources

Below Istio resources are added to support Mesh Expansion with gateways. This released the flat network requirement between the VM and cluster.

Resource Kind	Resource Name	Function
`configmap`	`coredns`	Send .global request to `istiocordns` service
`service`	`istiocoredns`	Resolve .global to Istio Ingress gateway
`gateway.networking.istio.io`	`meshexpansion-gateway`	Open port for Pilot, Citadel and Mixer
`gateway.networking.istio.io`	`istio-multicluster-egressgateway`	Open port 15443 for outbound .global traffic
`gateway.networking.istio.io`	`istio-multicluster-ingressgateway`	Open port 15443 for inbound .global traffic
`envoyfilter.networking.istio.io`	`istio-multicluster-ingressgateway`	Transform `.global` to `. svc.cluster.local`
`destinationrule.networking.istio.io`	`istio-multicluster-destinationrule`	Set traffic policy for 15443 traffic
`destinationrule.networking.istio.io`	`meshexpansion-dr-pilot`	Set traffic policy for `istio-pilot`
`destinationrule.networking.istio.io`	`istio-policy`	Set traffic policy for `istio-policy`
`destinationrule.networking.istio.io`	`istio-telemetry`	Set traffic policy for `istio-telemetry`
`virtualservice.networking.istio.io`	`meshexpansion-vs-pilot`	Set route info for `istio-pilot`
`virtualservice.networking.istio.io`	`meshexpansion-vs-citadel`	Set route info for `istio-citadel`

Expose service running on cluster to VMs

Every service in the cluster that needs to be accessed from the VM requires a service entry configuration in the cluster. The host used in the service entry should be of the form <name>.<namespace>.global where name and namespace correspond to the service’s name and namespace respectively.

To demonstrate access from VM to cluster services, configure thethe httpbin servicein the cluster.

Deploy the httpbin service in the cluster

Zip

$ kubectl create namespace bar
$ kubectl label namespace bar istio-injection=enabled
$ kubectl apply -n bar -f @samples/httpbin/httpbin.yaml@

Create a service entry for the httpbin service in the cluster.

To allow services in VM to access httpbin in the cluster, we need to createa service entry for it. The host name of the service entry should be of the form<name>.<namespace>.global where name and namespace correspond to theremote service’s name and namespace respectively.

For DNS resolution for services under the *.global domain, you need to assign theseservices an IP address.

Each service (in the .global DNS domain) must have a unique IP within the cluster.

If the global services have actual VIPs, you can use those, but otherwise we suggestusing IPs from the loopback range 127.0.0.0/8 that are not already allocated.These IPs are non-routable outside of a pod.In this example we’ll use IPs in 127.255.0.0/16 which avoids conflicting withwell known IPs such as 127.0.0.1 (localhost).Application traffic for these IPs will be captured by the sidecar and routed to theappropriate remote service.

$ kubectl apply  -n bar -f - <<EOF
apiVersion: networking.istio.io/v1alpha3
kind: ServiceEntry
metadata:
  name: httpbin.bar.forvms
spec:
  hosts:
  # must be of form name.namespace.global
  - httpbin.bar.global
  location: MESH_INTERNAL
  ports:
  - name: http1
    number: 8000
    protocol: http
  resolution: DNS
  addresses:
  # the IP address to which httpbin.bar.global will resolve to
  # must be unique for each service, within a given cluster.
  # This address need not be routable. Traffic for this IP will be captured
  # by the sidecar and routed appropriately.
  # This address will also be added into VM's /etc/hosts
  - 127.255.0.3
  endpoints:
  # This is the routable address of the ingress gateway in the cluster.
  # Traffic from the VMs will be
  # routed to this address.
  - address: ${CLUSTER_GW_ADDR}
    ports:
      http1: 15443 # Do not change this port value
EOF

The configurations above will result in all traffic from VMs forhttpbin.bar.global on any port to be routed to the endpoint<IPofClusterIngressGateway>:15443 over a mutual TLS connection.

The gateway for port 15443 is a special SNI-aware Envoypreconfigured and installed as part of the meshexpansion with gateway Istio installation stepin the Customized installation of Istio on the Cluster section. Traffic entering port 15443 will beload balanced among pods of the appropriate internal service of the targetcluster (in this case, httpbin.bar in the cluster).

Do not create a Gateway configuration for port 15443.

Send requests from VM to Kubernetes services

After setup, the machine can access services running in the Kubernetes cluster.

The following example shows accessing a service running in the Kubernetes cluster from a mesh expansion VM using/etc/hosts/, in this case using a service from the httpbin service.

On the mesh expansion machine, add the service name and address to its /etc/hosts file. You can then connect tothe cluster service from the VM, as in the example below:

$ echo "127.255.0.3 httpbin.bar.global" | sudo tee -a /etc/hosts
$ curl -v httpbin.bar.global:8000
< HTTP/1.1 200 OK
< server: envoy
< content-type: text/html; charset=utf-8
< content-length: 9593
... html content ...

The server: envoy header indicates that the sidecar intercepted the traffic.

Running services on a mesh expansion machine

Setup an HTTP server on the VM instance to serve HTTP traffic on port 8888:

$ python -m SimpleHTTPServer 8888

Determine the VM instance’s IP address.
Configure a service entry to enable service discovery for the VM. You can add VM services to the mesh using aservice entry. Service entries let you manually addadditional services to Pilot’s abstract model of the mesh. Once VM services are part of the mesh’s abstract model,other services can find and direct traffic to them. Each service entry configuration contains the IP addresses, ports,and appropriate labels of all VMs exposing a particular service, for example:

$ kubectl -n ${SERVICE_NAMESPACE} apply -f - <<EOF
apiVersion: networking.istio.io/v1alpha3
kind: ServiceEntry
metadata:
  name: vmhttp
spec:
  hosts:
  - vmhttp.${SERVICE_NAMESPACE}.svc.cluster.local
  ports:
  - number: 8888
    name: http
    protocol: HTTP
  resolution: STATIC
  endpoints:
  - address: ${VM_IP}
    ports:
      http: 8888
    labels:
      app: vmhttp
      version: "v1"
EOF

The workloads in a Kubernetes cluster need a DNS mapping to resolve the domain names of VM services. Tointegrate the mapping with your own DNS system, use istioctl register and creates a Kubernetes selector-lessservice, for example:

$ istioctl  register -n ${SERVICE_NAMESPACE} vmhttp ${VM_IP} 8888

Ensure you have added the istioctl client to your path, as described in the download page.

Deploy a pod running the sleep service in the Kubernetes cluster, and wait until it is ready:

Zip

$ kubectl apply -f @samples/sleep/sleep.yaml@
$ kubectl get pod
NAME                             READY     STATUS    RESTARTS   AGE
productpage-v1-8fcdcb496-xgkwg   2/2       Running   0          1d
sleep-88ddbcfdd-rm42k            2/2       Running   0          1s
...

Send a request from the sleep service on the pod to the VM’s HTTP service:

$ kubectl exec -it sleep-88ddbcfdd-rm42k -c sleep -- curl vmhttp.${SERVICE_NAMESPACE}.svc.cluster.local:8888

If configured properly, you will see something similar to the output below.

<!DOCTYPE html PUBLIC "-//W3C//DTD HTML 3.2 Final//EN"><html>
<title>Directory listing for /</title>
<body>
<h2>Directory listing for /</h2>
<hr>
<ul>
<li><a href=".bashrc">.bashrc</a></li>
<li><a href=".ssh/">.ssh/</a></li>
...
</body>

Congratulations! You successfully configured a service running in a pod within the cluster tosend traffic to a service running on a VM outside of the cluster and tested thatthe configuration worked.

Cleanup

Run the following commands to remove the expansion VM from the mesh’s abstractmodel.

$ istioctl deregister -n ${SERVICE_NAMESPACE} vmhttp ${VM_IP}
2019-02-21T22:12:22.023775Z     info    Deregistered service successfull
$ kubectl delete ServiceEntry vmhttp -n ${SERVICE_NAMESPACE}
serviceentry.networking.istio.io "vmhttp" deleted

Multi-network Mesh Expansion

Multi-network Mesh Expansion

Prerequisites

Installation steps

Customized installation of Istio on the Cluster

Setup DNS

Setting up the VM

Added Istio resources

Expose service running on cluster to VMs

Send requests from VM to Kubernetes services

Running services on a mesh expansion machine

Cleanup

相关内容