This repository describes how to deploy a 4 node (one control plane and
You must have both Docker and the Go programming language install for this test environment to function. How to get these working is beyond the scope of this document.
export GOPATH=$(pwd) mkdir -p $GOPATH/bin curl -o $GOPATH/bin/kubectl -sSL https://storage.googleapis.com/kubernetes-release/release/$(curl -s https://storage.googleapis.com/kubernetes-release/release/stable.txt)/bin/$(go env GOHOSTOS)/$(go env GOARCH)/kubectl curl -o $GOPATH/bin/kind \ -sSL https://github.com/kubernetes-sigs/kind/releases/download/v0.4.0/kind-$(go env GOHOSTOS)-$(go env GOARCH) curl -o $GOPATH/bin/voltctl \ -sSL https://github.com/ciena/voltctl/releases/download/0.0.5-dev/voltctl-0.0.5_dev-$(go env GOHOSTOS)-$(go env GOARCH) curl -sSL https://git.io/get_helm.sh | USE_SUDO=false HELM_INSTALL_DIR=$(go env GOPATH)/bin bash chmod 755 $GOPATH/bin/kind $GOPATH/bin/voltctl $GOPATH/bin/kubectl export PATH=$(go env GOPATH)/bin:$PATH
This files contained in this repository can be used to deploy either a minimal or full voltha deployment. The difference is characterized in the following table:
RESOURCE | MINIMAL | FULL |
---|---|---|
K8s Control Plane Nodes | 1 | 1 |
K8s Workers | 2 | 3 |
EtcdOperator Components | Operator only | Operator, Backup, Restore |
EtcdCluster | 1 Member | 3 Members |
Throughout this README.md
file deployment and configuration files are referenced in the form $TYPE-cluster.cfg and $TYPE-values.yaml. Depending on which type of deloyment you wish to install replace $TYPE with either minimal or full. If you set the environment variable to the desired deployment type, example below, then the commands can be executed via a simply copy and paste to your command line.
export TYPE=minimal
OK, if you really don't care how it starts and you just wanted started. After cloning the repository and making sure you have Go and Docker available, just execute ./voltha up
and the minimal cluster should start.
To remove voltha use ./voltha down
NOTE: Shown significantly sped up (20x), actual install was about 8 minutes.
voltha up
Configuration OptionsThis options should be set using environment variables, thus to start VOLTHA with the BBSIM POD you could use the following command:
WITH_BBSIM=yes voltha up
OPTION | DEFAULT | DESCRIPTION |
---|---|---|
TYPE | minimal | minimal or full and determines number of cluster nodes and etcd cluster members |
NAME | TYPE | Name of the KinD Cluster to be created |
DEPLOY_K8S | yes | Should the KinD Kubernetes cluster be deployed? |
JUST_K8S | no | Should just the KinD Kubernetes cluster be depoyed? (i.e. no VOLTHA) |
WITH_BBSIM | no | Should the BBSIM POD be deployed? |
WITH_ONOS | yes | Should ONOS service be deployed? |
WITH_RADIUS | no | Should freeradius service be deployed? |
WITH_TP | yes | Install the ONOS image that support Tech Profiles |
WITH_TIMINGS | no | Outputs duration of various steps of the install |
INSTALL_ONOS_APPS | no | Replaces/installs ONOS OAR files in onos-files/onos-apps |
SKIP_RESTART_API | no | Should the VOLTHA API service be restarted after install to avoid known bug? |
INSTALL_KUBECTL | yes | Should a copy of kubectl be installed locally? |
INSTALL_HELM | yes | Should a copy of helm be installed locallly? |
USE_GO | yes | Should the Go[lang] version of the OpenOLT adapter be used? |
ONOS_TAG | Used to override the default image tag for the ONOS docker image | |
VOLTHA_LOG_LEVEL | WARN | Log level to set for VOLTHA core processes |
VOLTHA_CHART | onf/voltha | Helm chart to used to install voltha |
VOLTHA_ADAPTER_SIM_CHART | onf/voltha-adapter-simulated | Helm chart to use to install simulated device adapter |
VOLTHA_ADAPTER_OPEN_OLT_CHART | onf/voltha-adapter-openolt | Helm chart to use to install OpenOlt adapter |
VOLTHA_ADAPTER_OPEN_ONU_CHART | onf/voltha-adapter-openonu | Helm chart to use to install OpenOnu adapter |
Kind provides a command line control tool to easily create Kubernetes clusters using just a basic Docker envionrment. The following commands will create the desired deployment of Kubernetes and then configure your local copy of kubectl
to connect to this cluster.
kind create cluster --name=voltha-$TYPE --config $TYPE-cluster.cfg export KUBECONFIG="$(kind get kubeconfig-path --name="voltha-$TYPE")" kubectl cluster-info
Helm provide a capabilty to install and manage Kubernetes applications. VOLTHA's default deployment mechanism utilized Helm. Before Helm can be used to deploy VOLTHA it must be initialized and the repositories that container the artifacts required to deploy VOLTHA must be added to Helm.
# Initialize Helm and add the required chart repositories helm init helm repo add incubator https://kubernetes-charts-incubator.storage.googleapis.com helm repo add stable https://kubernetes-charts.storage.googleapis.com helm repo add onf https://charts.opencord.org helm repo update # Create and k8s service account so that Helm can create pods kubectl create serviceaccount --namespace kube-system tiller kubectl create clusterrolebinding tiller-cluster-rule --clusterrole=cluster-admin --serviceaccount=kube-system:tiller kubectl patch deploy --namespace kube-system tiller-deploy -p '{"spec":{"template":{"spec":{"serviceAccount":"tiller"}}}}'
ETCD Operator is a utility that allows applications to create and manage ETCD key/value clusters as Kubernetes resources. VOLTHA utilizes this utility to create its key/value store. NOTE: it is not required that VOLTHA create its own datastore as VOLTHA can utilize and existing datastore, but for this example VOLTHA will creates its own datastore
helm install -f $TYPE-values.yaml --namespace voltha --name etcd-operator stable/etcd-operator
Before continuing the Kubernetes pods associated with ETCD Operator must be in the Running
state.
kubectl get -n voltha pod
Once all the pods are in the Running
state the output, for a full deployment should be similar to the output below. For a minimal deployment there will only be a single pod, the etcd-operator-etcd-operator-etcd-operator
pod.
NAME READY STATUS RESTARTS AGE etcd-operator-etcd-operator-etcd-backup-operator-7897665cfq75w2 1/1 Running 0 2m etcd-operator-etcd-operator-etcd-operator-7d579799f7-bjdnj 1/1 Running 0 2m etcd-operator-etcd-operator-etcd-restore-operator-7d77d878wwcn7 1/1 Running 0 2m
To demonstrate the capability of VOLTHA other partner applications are required, such as ONOS. The followins sections describe how to install and configure these partner applications.
NOTE: It is important to start ONOS before VOLTHA as if they are started in the reverse order ofagent sometimes does not connect to the SDN controller VOL-1764.
VOLTHA exposes an OLT and its connected ONUs as an OpenFlow switch. To control that virtual OpenFlow switch an OpenFlow controller is required. For most VOLTHA deployments that controller is ONOS with a set of ONOS applications installed. To install ONOS use the following Helm command:
helm install -f $TYPE-values.yaml --name onos onf/onos
screen -dmS onos-ui kubectl port-forward service/onos-ui 8181:8181 screen -dmS onos-ssh kubectl port-forward service/onos-ssh 8101:8101
A script has been included, install-onos-applications.sh
, that can be used to download and install the required applications into ONOS.
./onos-files/install-onos-applications.sh
VOLTHA has two main parts: core and adapters. The core provides the main logic for the VOLTHA application and the adapters contain logic to adapter vendor neutral operations to vendor specific devices.
Before any adapters can be deployed the VOLTHA core must be installed and in the Running
state. The following Helm command installs the core components of VOLTHA based on the desired deployment type.
helm install -f $TYPE-values.yaml --namespace voltha --name voltha onf/voltha
During the install of the core VOLTHA components some containers may "crash" or restart. This is normal as there are dependencies, such as the read/write cores cannot start until the ETCD cluster is established and so they crash until the ETCD cluster is operational. Eventually all the containers should be in a Running
state as queried by the command:
kubectl get -n voltha pod
The output should be similar to the following with a different number of etcd-operator
and voltha-etcd-cluster
pods depending on the deployment type.
NAME READY STATUS RESTARTS AGE etcd-operator-etcd-operator-etcd-operator-7d579799f7-xq6f2 1/1 Running 0 19m ofagent-8ccb7f5fb-hwgfn 1/1 Running 0 4m ro-core-564f5cdcc7-2pch8 1/1 Running 0 4m rw-core1-7fbb878cdd-6npvr 1/1 Running 2 4m rw-core2-7fbb878cdd-k7w9j 1/1 Running 3 4m voltha-api-server-5f7c8b5b77-k6mrg 2/2 Running 0 4m voltha-cli-server-5df4c95b7f-kcpdl 1/1 Running 0 4m voltha-etcd-cluster-4rsqcvpwr4 1/1 Running 0 4m voltha-kafka-0 1/1 Running 0 4m voltha-zookeeper-0 1/1 Running 0 4m
The following commands install both the simulated OLT and ONU adapters as well as the adapters for an OpenOLT and OpenONU device.
helm install -f $TYPE-values.yaml --namespace voltha --name sim onf/voltha-adapter-simulated helm install -f $TYPE-values.yaml --namespace voltha --name open-olt onf/voltha-adapter-openolt helm install -f $TYPE-values.yaml --namespace voltha --name open-onu onf/voltha-adapter-openonu
At this point VOLTHA is deployed and from within the Kubernetes cluster the VOLTHA services can be reached. However, from outside the Kubernetes cluster the services cannot be reached.
screen -dmS voltha-api kubectl port-forward -n voltha service/voltha-api 55555:55555 screen -dmS voltha-ssh kubectl port-forward -n voltha service/voltha-cli 5022:5022
voltctl
to Connect to VOLTHAIn order for voltctl
to connect to the VOLTHA instance deplpoyed in the Kubernetes cluster it must know which IP address and port to use. This configuration can be persisted to a local config file using the following commands.
mkdir -p $HOME/.volt voltctl -a v2 -s localhost:55555 config > $HOME/.volt/config
To test the connectivity you can query the version of the VOLTHA client and server.
voltctl version
The output should be similar to the following
Client: Version unknown-version Go version: unknown-goversion Vcs reference: unknown-vcsref Vcs dirty: unknown-vcsdirty Built: unknown-buildtime OS/Arch: unknown-os/unknown-arch Cluster: Version 2.1.0-dev Go version: 1.12.6 Vcs feference: 28f120f1f4751284cadccf73f2f559ce838dd0a5 Vcs dirty: false Built: 2019-06-26T16:58:22Z OS/Arch: linux/amd64
Once all the containers are up and running, a simulated device to "test" the system can be created using the following command.
voltctl device create
NOTE: If the device fails to create and an error message is displayed you may have hit an existing bug in onos VOL-1661 . To work around this, use the restart-api.sh
included in the repository. After running this script you will have to quit and restart the screen sesssion associated with the voltha-api.
The output of the command will be the device ID. All the known devices can be listed with the following command.
voltctl device list
The output should be similar to the following
ID TYPE ROOT PARENTID SERIALNUMBER VLAN ADMINSTATE OPERSTATUS CONNECTSTATUS 1d5382581e2198ded3b9bcd8 simulated_olt true 0 PREPROVISIONED UNKNOWN UNKNOWN
To enable a device, specify the the device ID
voltctl device enable 1d5382581e2198ded3b9bcd8
When a device is enabled VOLTHA communicates with the device to discover the ONUs associated with the devices. Using the device and logicaldevice sub-commands, list
and ports
the information VOLTHA discovered can be displayed.
$ voltctl device list ID TYPE ROOT PARENTID SERIALNUMBER VLAN ADMINSTATE OPERSTATUS CONNECTSTATUS 1d5382581e2198ded3b9bcd8 simulated_olt true 4F35373B6528 44.141.111.238:7941 0 ENABLED ACTIVE REACHABLE 5660880ea2b602081b8203fd simulated_onu false 1d5382581e2198ded3b9bcd8 82.24.38.124:9913 101 ENABLED ACTIVE REACHABLE 7ff85b36a13fdf98450b9d13 simulated_onu false 1d5382581e2198ded3b9bcd8 204.200.47.166:9758 103 ENABLED ACTIVE REACHABLE bda9d3442e4cf93f9a58b1f2 simulated_onu false 1d5382581e2198ded3b9bcd8 66.130.155.136:1448 100 ENABLED ACTIVE REACHABLE f546b18b101c287601d5a9dd simulated_onu false 1d5382581e2198ded3b9bcd8 72.157.213.155:5174 102 ENABLED ACTIVE REACHABLE $ voltctl device ports 1d5382581e2198ded3b9bcd8 PORTNO LABEL TYPE ADMINSTATE OPERSTATUS DEVICEID PEERS 2 nni-2 ETHERNET_NNI ENABLED ACTIVE [] 1 pon-1 PON_OLT ENABLED ACTIVE [{7ff85b36a13fdf98450b9d13 1} {bda9d3442e4cf93f9a58b1f2 1} {5660880ea2b602081b8203fd 1} {f546b18b101c287601d5a9dd 1}] $ voltctl logicaldevice list ID DATAPATHID ROOTDEVICEID SERIALNUMBER FEATURES.NBUFFERS FEATURES.NTABLES FEATURES.CAPABILITIES 4F35373B6528 00004f35373b6528 1d5382581e2198ded3b9bcd8 44.141.111.238:7941 256 2 0x0000000f $ voltctl logicaldevice ports 4F35373B6528 ID DEVICEID DEVICEPORTNO ROOTPORT OPENFLOW.PORTNO OPENFLOW.HWADDR OPENFLOW.NAME OPENFLOW.STATE OPENFLOW.FEATURES.CURRENT OPENFLOW.BITRATE.CURRENT nni-2 1d5382581e2198ded3b9bcd8 2 true 2 4f:35:37:3b:65:28 nni-2 0x00000004 0x00001020 32 uni-103 7ff85b36a13fdf98450b9d13 103 false 103 0b:23:05:64:46:2b 0x00000004 0x00001020 32 uni-100 bda9d3442e4cf93f9a58b1f2 100 false 100 68:05:4a:56:28:5b 0x00000004 0x00001020 32 uni-101 5660880ea2b602081b8203fd 101 false 101 21:57:68:39:44:55 0x00000004 0x00001020 32 uni-102 f546b18b101c287601d5a9dd 102 false 102 01:02:03:04:05:06 0x00000004 0x00001020 32
When a device is enabled VOLTHA also presents that devices as a virtual OpenFlow switch to ONOS. This can be seen in ONOS via the CLI and UI. ONOS, in turn, pushes flows down to the virual OpenFlow device, which can then be displayed via the voltctl
command. Seeing flows in voltctl
demonstrates that VOLTHA has successfully presented the OLT/ONUs as an virtual OpenFlow switch to ONOS and ONOS has been able to enfluence the OLT/ONU configuraton by assigning flows.
$ ssh -p 8101 karaf@localhost Password: Welcome to Open Network Operating System (ONOS)! ____ _ ______ ____ / __ \/ |/ / __ \/ __/ / /_/ / / /_/ /\ \ \____/_/|_/\____/___/ Documentation: wiki.onosproject.org Tutorials: tutorials.onosproject.org Mailing lists: lists.onosproject.org Come help out! Find out how at: contribute.onosproject.org Hit '<tab>' for a list of available commands and '[cmd] --help' for help on a specific command. Hit '<ctrl-d>' or type 'system:shutdown' or 'logout' to shutdown ONOS. onos> devices id=of:00004f35373b6528, available=true, local-status=connected 6m51s ago, role=MASTER, type=SWITCH, mfr=, hw=simulated_pon, sw=simulated_pon, serial=44.141.111.238:7941, chassis=4f35373b6528, driver=default, channelId=10.244.1.16:56302, managementAddress=10.244.1.16, protocol=OF_13 onos> ^D onos> Connection to localhost closed.
$ voltctl device flows 1d5382581e2198ded3b9bcd8 ID TABLEID PRIORITY COOKIE INPORT VLANID VLANPCP ETHTYPE METADATA TUNNELID SETVLANID POPVLAN PUSHVLANID OUTPUT 7504ed89e9db100f 0 40000 ~deb05c25 1 103 0x888e 103 4000 0x8100 CONTROLLER 2d0d9951533d886c 0 40000 0 2 4000 0 0x0000000000000067 103 yes 1 fa6b175a31b29ab2 0 40000 ~deb05c25 1 100 0x888e 100 4000 0x8100 CONTROLLER 211e554ad8933810 0 40000 0 2 4000 0 0x0000000000000064 100 yes 1 3c61b06b7140f699 0 40000 ~deb05c25 1 101 0x888e 101 4000 0x8100 CONTROLLER faf13be01f7220fe 0 40000 0 2 4000 0 0x0000000000000065 101 yes 1 f0002ab45e5d9c0a 0 40000 ~deb05c25 1 102 0x888e 102 4000 0x8100 CONTROLLER cb6506ce6cd5f815 0 40000 0 2 4000 0 0x0000000000000066 102 yes 1 1ba03e16bcc071eb 0 40000 ~2ab3e948 1 103 0x0806 103 4000 0x8100 2 18d6c34108732730 0 40000 ~2ab3e948 1 100 0x0806 100 4000 0x8100 2 c6a21ac1bc742efd 0 40000 ~2ab3e948 1 101 0x0806 101 4000 0x8100 2 a8346901fe5c6547 0 40000 ~2ab3e948 1 102 0x0806 102 4000 0x8100 2 $ voltctl logicaldevice flows 4F35373B6528 ID TABLEID PRIORITY COOKIE ETHTYPE OUTPUT CLEARACTIONS 85df95ba0c6fbff3 0 40000 ~2ab3e948 0x0806 CONTROLLER [] dd6707b7a6ff74cf 0 40000 ~deb05c25 0x888e CONTROLLER []
To remove the cluster simply use the kind
command:
kind delete cluster --name=voltha-$TYPE
helm install -f $TYPE-values.yaml --namespace voltha --name bbsim onf/bbsim
voltctl device create -t openolt -H $(kubectl get -n voltha service/bbsim -o go-template='{{.spec.clusterIP}}'):50060
voltctl device enable $(voltctl device list --filter Type~openolt -q)