| .. _workflows: |
| |
| Operator workflows |
| ================== |
| |
| ``Workflow`` is a term that spilled from the SEBA Reference Design (RD) into VOLTHA. |
| |
| In SEBA a workflow is a collection of subscriber management items like identification, location, |
| and bandwidth profile. In addition each workflows maps to a service type which translates to a technology profile, |
| and an operator desired flow of operations (i.e state-machine). |
| The workflow is implemented by a selection of ONOS apps, XOS services (in SEBA) |
| and a set of configurations (sadis, etcd, netcfg). Those apps paired with the configuration specified by the |
| workflow (e.g. need EAPOL) in turn create low level flows, groups, meters, schedulers, queues etc. |
| A workflow is then triggered by a particular set of APIs, for example the request to add a subscriber. |
| |
| A full description of the different operator's workflows can be |
| `found here <https://drive.google.com/drive/folders/1MfxwoDSvAR_rgFHt6n9Sai7IuiJPrHxF>`_. |
| |
| A big part of the workflow in SEBA is defined within NEM (Network Edge Mediator). |
| Given that NEM is not available in a plain VOLTHA deployment the user has to ensure proper config in the right places, |
| and then triggering of api's themselves. |
| |
| To deploy a specific workflow follow the steps under `deploying-a-different-workflow` in the `voltha-helm-charts |
| README <../voltha-helm-charts/README.md>`_. |
| |
| A workflow in VOLTHA entails different elements: Customer tag allocation, Technology profile, Bandwidth profile, |
| Flow and Group Management |
| |
| Customer tag allocation |
| ----------------------- |
| |
| The vlan tags for a particular subscriber are defined in the ``sadis`` configuration. |
| `Sadis <https://github.com/opencord/sadis>`_ stands for `Subscriber and Device Information Service` |
| and is the ONOS application responsible to store and distribute Subscriber information. |
| |
| Information on different ``sadis`` configurations can be found here: |
| https://docs.google.com/document/d/1JLQ51CZg4jsXsBQcrJn-fc2kVvXH6lw0PYoyIclwmBs |
| |
| Technology profile |
| ------------------ |
| |
| Technology profiles describes technology specific attributes required to implement |
| Subscriber Services on an OpenFlow managed Logical Switch overlaid upon an OLT |
| or other technology specific platform. |
| |
| More information on Technology profiles can be found here: |
| `2018/03/22 VOLTHA TST on Technology profile <https://youtu.be/L0JBJ3R1Mag>`_ |
| `VOLTHA technical notes on Technology profile <https://wiki-archive.opencord.org/attachments/4981667/4981671.docx>`_ |
| `VOLTHA Implementation of Technology profiles <https://wiki-archive.opencord.org/attachments/4981667/4981670.docx>`_ |
| `Technology profile instance example <https://wiki-archive.opencord.org/Technology-Profile-Instance_4982088.html>`_ |
| |
| Technology profiles in VOLTHA are stored in ETCD. If you want to load a custom |
| Technology profile in your stack you can do so by: |
| |
| .. code:: bash |
| |
| ETCD_POD=$(kubectl get pods | grep etcd | awk 'NR==1{print \$1}') |
| kubectl cp <my-tech-profile>.json $ETCD_POD:/tmp/tp.json |
| kubectl exec -it $ETCD_POD -- /bin/sh -c 'cat /tmp/tp.json | ETCDCTL_API=3 etcdctl put service/voltha/technology_profiles/XGS-PON/64' |
| |
| *Note that `XGS-PON` represents the technology of your OLT device and `64` is |
| the default id of the technology profile. If you want to use a technology profile |
| that is not the default for a particular subscriber that needs to be configured |
| in `sadis`.* |
| |
| Bandwidth profile |
| ----------------- |
| |
| Bandwidth profiles control the allocation Bandwidth for a particular subscriber. |
| They are defined in the `sadis` application. |
| VOLTHA supports both the MEF and IETF definition of Bandwidth Profile. |
| More information on the different definitions can be found on the `MEF wiki <https://wiki.mef.net/display/CESG/Bandwidth+Profile>`_. |
| |
| MEF: |
| |
| .. code-block:: json |
| |
| { |
| "id" : "Default", |
| "cir" : 1000000, |
| "cbs" : 1001, |
| "eir" : 1002, |
| "ebs" : 1003, |
| "air" : 1004 |
| } |
| |
| IETF: |
| |
| .. code-block:: json |
| |
| { |
| "id" : "Default", |
| "pir": 1168192, |
| "pbs": 0, |
| "cir": 0, |
| "cbs": 0, |
| "gir": 0 |
| } |
| |
| Each bandwidth profile is then translated into an OpenFlow Meter for configuration on the OLT. |
| |
| Each OpenFlow Meter is then translated to a different TCONT type in the `openolt-adapter`. |
| VOLTHA supports all 5 TCONT types. |
| |
| The translation of Bandwidth profile parameters to TCONT types happens as follows: |
| |
| - | `Type-1`: If CIR > 0, CIR = PIR, additional_bw_eligibility = none --> set guaranteed_bw = maximum_bw = CBR_RT_BW |
| | (or CBR_NRT_BW) = CIR and alloc_type=none. (alloc_type is inferred from the other parameters) |
| - | `Type-2`: If CIR = 0, GIR or AIR > 0, GIR or AIR = PIR, additional_bw_eligibility = none --> set guaranteed_bw = |
| | maximum_bw = AIR, CBR_RT_BW = 0 and CBR_NRT_BW = 0 and alloc_type = NSR (alloc_type is set to NSR by default) |
| - | `Type-3`: If CIR = 0, GIR or AIR > 0, PIR > GIR or AIR, additional_bw_eligibility = non_assured --> |
| | guaranteed_bw = AIR, maximum_bw = PIR, CBR_RT_BW = 0 and CBR_NRT_BW = 0 and alloc_type = NSR and send |
| | these parameters to BAL. (alloc_type is set to NSR by default) |
| - | `Type-4`: if CIR = 0, GIR or AIR = 0, PIR > 0, additional_bw_eligibility = best_effort --> set |
| | guaranteed_bw = 0, maximum_bw = PIR, CBR_RT_BW = 0 and CBR_NRT_BW = 0 and alloc_type = NSR and send |
| | (alloc_type is set to NSR by default) |
| - | `Type-5`: if CIR > 0, PIR >= CIR + GIR or AIR, additional_bw_eligibility = non_assured or |
| | best_effort --> set guaranteed_bw = CIR+AIR, maximum_bw = PIR, CBR_RT_BW = 0 (or CBR_NRT_BW) = CIR |
| | and alloc_type = NSR. (alloc_type is set to NSR by default) |
| |
| Further implementation details can be found in `this document <https://docs.google.com/document/d/1HipmsHD5LEQlOc-Y2tYV7DHD1fn7-_1lehBgp79sRwU/edit#>`_. |
| |
| Flow management |
| --------------- |
| |
| Flows are managed in ONOS by the `olt` application. Through the configuration of |
| this application you can define whether your setup will create: |
| |
| - An `EAPOL` trap flow |
| - A `DHCP` trap flow |
| - An `IGMP` trap flow |
| |
| in addition to the default data plane flows. |
| |
| Group management |
| ---------------- |
| |
| Groups are managed in ONOS by the `mcast` application. Through the configuration of |
| this application you can achieve multicast for services such as IpTV. |