blob: 7010055d7e223f5329a20afa947f8dd8385758ac [file] [log] [blame]
.. _docs_scaleout:
VF Module Scale Out Use Case
----------------------------
Source files
~~~~~~~~~~~~
- Heat templates directory: https://git.onap.org/demo/tree/heat/vLB_CDS?h=dublin
Additional files
~~~~~~~~~~~~~~~~
- DCAE blueprint: https://git.onap.org/integration/tree/docs/files/scaleout/k8s-tca-clamp-policy-05162019.yaml
- TOSCA model template: https://git.onap.org/integration/tree/docs/files/scaleout/service-Vloadbalancercds-template.yml
- Naming policy script: https://git.onap.org/integration/tree/docs/files/scaleout/push_naming_policy.sh
Description
~~~~~~~~~~~
The scale out use case uses a VNF composed of three virtual functions. A traffic generator (vPacketGen), a load balancer (vLB), and a DNS (vDNS). Communication between the vPacketGen and the vLB, and the vLB and the vDNS occurs via two separate private networks. In addition, all virtual functions have an interface to the ONAP OAM private network, as shown in the topology below.
.. figure:: files/scaleout/topology.png
:align: center
The vPacketGen issues DNS lookup queries that reach the DNS server via the vLB. vDNS replies reach the packet generator via the vLB as well. The vLB reports the average amount of traffic per vDNS instances over a given time interval (e.g. 10 seconds) to the DCAE collector via the ONAP OAM private network.
To run the use case, make sure that the security group in OpenStack has ingress/egress entries for protocol 47 (GRE). Users can test the VNF by running DNS queries from the vPakcketGen:
::
dig @vLoadBalancer_IP host1.dnsdemo.onap.org
The output below means that the vLB has been set up correctly, has forwarded the DNS queries to a vDNS instance, and the vPacketGen has received the vDNS reply message.
::
; <<>> DiG 9.10.3-P4-Ubuntu <<>> @192.168.9.111 host1.dnsdemo.onap.org
; (1 server found)
;; global options: +cmd
;; Got answer:
;; ->>HEADER<<- opcode: QUERY, status: NOERROR, id: 31892
;; flags: qr aa rd; QUERY: 1, ANSWER: 1, AUTHORITY: 1, ADDITIONAL: 2
;; WARNING: recursion requested but not available
;; OPT PSEUDOSECTION:
; EDNS: version: 0, flags:; udp: 4096
;; QUESTION SECTION:
;host1.dnsdemo.onap.org. IN A
;; ANSWER SECTION:
host1.dnsdemo.onap.org. 604800 IN A 10.0.100.101
;; AUTHORITY SECTION:
dnsdemo.onap.org. 604800 IN NS dnsdemo.onap.org.
;; ADDITIONAL SECTION:
dnsdemo.onap.org. 604800 IN A 10.0.100.100
;; Query time: 0 msec
;; SERVER: 192.168.9.111#53(192.168.9.111)
;; WHEN: Fri Nov 10 17:39:12 UTC 2017
;; MSG SIZE rcvd: 97
The Scale Out Use Case
~~~~~~~~~~~~~~~~~~~~~~
The Scale Out use case shows how users/network operators can add Virtual Network Function Components (VNFCs) as part of a VF Module that has been instantiated in the Service model, in order to increase capacity of the network. ONAP Dublin release supports scale out with manual trigger by directly calling SO APIs and closed-loop-enabled automation from Policy. For Dublin, the APPC controller is used to demonstrate accepting request from SO to execute the Scale Out operation. APPC can be used to scale different VNF types, not only the VNF described in this document.
The figure below shows all the interactions that take place during scale out operations.
.. figure:: files/scaleout/scaleout.png
:align: center
There are four different message flows:
- Gray: This is communication that happens internally to the VNF and it is described in the section above.
- Green: Scale out with manual trigger.
- Red: Closed-loop enabled scale out.
- Black: Orchestration and VNF lifecycle management (LCM) operations.
The numbers in the figure represent the sequence of steps within a given flow. Note that interactions between the components in the picture and AAI, SDNC, and DMaaP are not shown for clarity's sake.
Scale out with manual trigger (green flow) and closed-loop enabled scale out (red flow) are mutually exclusive. When the manual trigger is used, VID directly triggers the appropriate workflow in SO (step 1 of the green flow in the figure above). See Section 4 for more details.
When closed-loop enabled scale out is used, Policy triggers the SO workflow. The closed loop starts with the vLB periodically reporting telemetry about traffic patterns to the VES collector in DCAE (step 1 of the red flow). When the amount of traffic exceeds a given threshold (which the user defines during closed loop creation in CLAMP - see Section 1-4), DCAE notifies Policy (step 2), which in turn triggers the appropriate action. For this use case, the action is contacting SO to augment resource capacity in the network (step 3).
At high level, once SO receives a call for scale out actions, it first creates a new VF module (step 1 of the black flow), then calls APPC to trigger some LCM actions (step 2). APPC runs VNF health check and configuration scale out as part of LCM actions (step 3). At this time, the VNF health check only reports the health status of the vLB, while the configuration scale out operation adds a new vDNS instance to the vLB internal state. As a result of configuration scale out, the vLB opens a connection towards the new vDNS instance.
At deeper level, the SO workflow works as depicted below:
.. figure:: files/scaleout/so-blocks.png
:align: center
SO first contacts APPC to run VNF health check and proceeds on to the next block only if the vLB is healthy (not shown in the previous figure for simplicity's sake). Then, SO assigns resources, instantiates, and activates the new VF module. Finally, SO calls APPC again for configuration scale out and VNF health check. The VNF health check at the end of the workflow validates that the vLB health status hasn't been negatively affected by the scale out operation.
PART 1 - Service Definition and Onboarding
------------------------------------------
This use-case requires operations on several ONAP components to perform service definition and onboarding.
1-1 Using CDS : VNF Configuration Modeling and Upload
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
For Dublin, the scale out use case integrates with the Controller Design Studio (CDS) ONAP component to automate the generation of cloud configuration at VNF instantiation time. Users can model this configuration at VNF design time and onboard the blueprint to CDS via the CDS GUI. The blueprint includes naming policies and network configuration details (e.g. IP address families, network names, etc.) that CDS will use during VNF instantiation to generate resource names and assign network configuration to VMs through the cloud orchestrator.
Please look at the CDS documentation for details about how to create configuration models, blueprints, and use the CDS tool: https://wiki.onap.org/display/DW/Modeling+Concepts. For running the use case, users can use the standard model package that CDS provides out of the box, which can be found here: https://wiki.onap.org/pages/viewpage.action?pageId=64007442
1-2 Using SDC : VNF Onboarding and Service Creation
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
Once the configuration blueprint is uploaded to CDS, users can define and onboard a service using SDC. SDC requires users to onboard a VNF descriptor that contains the definition of all the resources (private networks, compute nodes, keys, etc.) with their parameters that compose a VNF. The VNF used to demonstrate the scale out use case supports Heat templates as VNF descriptor, and hence requires OpenStack as cloud layer. Users can use the Heat templates linked at the top of the page to create a zip file that can be uploaded to SDC during service creation. To create a zip file, the user must be in the same folder that contains the Heat templates and the Manifest file that describes the content of the package. To create a zip file from command line, type:
::
zip ../vLB.zip *
For a complete description of service design and creation, please refer to the SDC wiki page: https://wiki.onap.org/display/DW/Design
During the creation of the service in SDC, there are a few extra steps that need to be executed to make the VNF ready for scale out. These require users to login to the SDC Portal as service designer user (username: cs0008, password: demo123456!).
After importing the Vendor Software Package (VSP), as described in the SDC wiki page, users need to set property values in the Property Assignment window, as shown below:
.. figure:: files/scaleout/9.png
:align: center
These properties include parameters in the Heat template (which will be overridden by CDS and then don't need to be changed) and other parameters that describe the VNF type or are used to link the service to the configuration in the CDS package.
Users can search for parameter names starting with "nf" to assign values that describe the VNF type, such as nf_type, nf_function, and nf_role. Users are free to choose the values they like. Users should also set "skip_post_instantiation" to "TRUE", as for Dublin CDS is not used for post-instantiation configuration.
.. figure:: files/scaleout/10.png
:align: center
For CDS parameters, users can search for names starting with "sdnc". These parameters have to match the configuration blueprint in CDS. To use the standard blueprint shipped with CDS, please set the parameters as below. For further details, please refer to the CDS documentation.
.. figure:: files/scaleout/11.png
:align: center
After importing the VSP, users need to onboard the DCAE blueprint and the Policy Model used to design closed loops in CLAMP. From the "Composition" tab in the service menu, select the artifact icon on the right, as shown below:
.. figure:: files/scaleout/1.png
:align: center
Upload the DCAE blueprint linked at the top of the page using the pop-up window.
.. figure:: files/scaleout/2.png
:align: center
The blueprint will appear in the artifacts section on the right.
.. figure:: files/scaleout/3.png
:align: center
To attach a Policy Model to the service, open the Policy drop-down list on left.
.. figure:: files/scaleout/4.png
:align: center
Then, add the TCA Policy.
.. figure:: files/scaleout/5.png
:align: center
The Policy will be attached to the service defined in SDC
.. figure:: files/scaleout/6.png
:align: center
Finally, users need to provide the maximum number of VNF instances that ONAP is allowed to create as part of the scale out use case by setting up deployment properties.
.. figure:: files/scaleout/7.png
:align: center
This VNF only supports scaling the vDNS, so users should select the vDNS module from the right panel and then click the "max_vf_module_instance" link. The maximum number of VNF instances to scale can be set to an arbitrary number higher than zero.
.. figure:: files/scaleout/8.png
:align: center
At this point, users can complete the service creation in SDC by testing, accepting, and distributing the Service Models as described in the SDC user manual.
1-3 Using a Shell Script : Deploy Naming Policy
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
In order to instantiate the VNF using CDS features, users need to deploy the naming policy that CDS uses for resource name generation to the Policy Engine. User can copy and run the script at the top of the page from any ONAP pod, for example Robot or Drools. The script uses the Policy endpoint defined in the Kubernetes domain, so the execution has to be triggered from some pod in the Kubernetes space.
::
kubectl exec -it dev-policy-drools-0
./push_naming_policy.sh
1-4 Using CLAMP : Closed Loop Design
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
Once the service model is distributed, users can design the closed loop from CLAMP, using the GUI at https://clamp.api.simpledemo.onap.org:30258/designer/index.html
Use the "Closed Loop" link to open a distributed model.
.. figure:: files/scaleout/12.png
:align: center
Select the closed loop associated to the distributed service model.
.. figure:: files/scaleout/13.png
:align: center
The closed loop main page for TCA microservices is shown below.
.. figure:: files/scaleout/14.png
:align: center
Click on the TCA box to create a configuration policy. From the pop-up window, users need to click "Add item" to create a new policy and fill it in with specific information, as shown below.
.. figure:: files/scaleout/15.png
:align: center
For this use case, the control loop schema type is "VM", while the event name has to match the event name reported in the VNF telemetry, which is "vLoadBalancer".
Once the policy item has been created, users can define a threshold that will be used at runtime to evaluate telemetry reported by the vLB. When the specified threshold is crossed, DCAE generates an ONSET event that will tell Policy Engine which closed loop to activate.
.. figure:: files/scaleout/16.png
:align: center
After the configuration policy is created, users need to create the operational policy, which the Policy Engine uses to determine which actions and parameters should be used during closed loop.
.. figure:: files/scaleout/17.png
:align: center
Select "VF Module Create" recipe and "SO" actor. The payload section is:
::
requestParameters: '{"usePreload":false,"userParams":[]}'
configurationParameters: '[{"ip-addr":"$.vf-module-topology.vf-module-parameters.param[17].value","oam-ip-addr":"$.vf-module-topology.vf-module-parameters.param[31].value"}]'
Policy Engine passes the payload to SO, which will then use it during VF module instantiation to resolve configuration parameters. The JSON path
::
"ip-addr":"$.vf-module-topology.vf-module-parameters.param[17].value"
indicates that resolution for parameter "ip-addr" is available at "$.vf-module-topology.vf-module-parameters.param[17].value" in the JSON object linked by the VF module self-link in AAI. For the vPacketGen/vLB/vDNS VNF, use the JSON paths provided in the example above.
The target type to select is VF module, as we are scaling a VF module. Please select the vDNS module as target resource ID.
.. figure:: files/scaleout/18.png
:align: center
For what regards guard policies, either "Frequency Limiter", or "MinMax", or both can be used for the scale out use case. The example below shows the definition of a "Frequency Limiter" guard policy. Irrespective of the guard policy type, the policy name should be x.y.scaleout.
Once the operational policy design is completed, users can submit and then deploy the closed loop clicking the "Submit" and "Deploy" buttons, respectively, as shown below.
.. figure:: files/scaleout/20.png
:align: center
At this point, the closed loop is deployed to Policy Engine and DCAE, and a new microservice will be deployed to the DCAE platform.
1-5 Using CDT : Creating a VNF Template
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
Before running scale out use case, the users need to create a VNF template using the Controller Design Tool (CDT), a design-time tool that allows users to create and on-board VNF templates into APPC. The template describes which control operation can be executed against the VNF (e.g. scale out, health check, modify configuration, etc.), the protocols that the VNF supports, port numbers, VNF APIs, and credentials for authentication. Being VNF agnostic, APPC uses these templates to "learn" about specific VNFs and the supported operations.
CDT requires two input:
1) the list of parameters that APPC will receive (ip-addr, oam-ip-addr, enabled in the example above);
2) the VNF API that APPC will use to reconfigure the VNF.
Below is an example of the parameters file (yaml format), which we call parameters.yaml:
::
version: V1
vnf-parameter-list:
- name: ip-addr
type: null
description: null
required: "true"
default: null
source: Manual
rule-type: null
request-keys: null
response-keys: null
- name: oam-ip-addr
type: null
description: null
required: "true"
default: null
source: Manual
rule-type: null
request-keys: null
response-keys: null
- name: enabled
type: null
description: null
required: "false"
default: null
source: Manual
rule-type: null
request-keys: null
response-keys: null
Here is an example of API for the vLB VNF used for this use case. We name the file after the vnf-type contained in SDNC (i.e. Vloadbalancerms..vdns..module-3):
::
<vlb-business-vnf-onap-plugin xmlns="urn:opendaylight:params:xml:ns:yang:vlb-business-vnf-onap-plugin">
<vdns-instances>
<vdns-instance>
<ip-addr>${ip-addr}</ip-addr>
<oam-ip-addr>${oam-ip-addr}</oam-ip-addr>
<enabled>true</enabled>
</vdns-instance>
</vdns-instances>
</vlb-business-vnf-onap-plugin>
To create the VNF template in CDT, the following steps are required:
- Connect to the CDT GUI: http://ANY-K8S-IP:30289
- Click "My VNF" Tab. Create your user ID, if necessary
- Click "Create new VNF" entering the VNF type as reported in VID or AAI, e.g. vLoadBalancerMS/vLoadBalancerMS 0
- Select "ConfigScaleOut" action
- Create a new template identifier using the VNF type name in service model as template name, e.g. Vloadbalancerms..vdns..module-3
- Select protocol (Netconf-XML), VNF username (admin), and VNF port number (2831 for NETCONF)
- Click "Parameter Definition" Tab and upload the parameters (.yaml) file
- Click "Template Tab" and upload API template (.yaml) file
- Click "Reference Data" Tab
- Click "Save All to APPC"
For health check operation, we just need to specify the protocol, the port number and username of the VNF (REST, 8183, and "admin" respectively, in the case of vLB/vDNS) and the API. For the vLB/vDNS, the API is:
::
restconf/operational/health-vnf-onap-plugin:health-vnf-onap-plugin-state/health-check
Note that we don't need to create a VNF template for health check, so the "Template" flag can be set to "N". Again, the user has to click "Save All to APPC" to update the APPC database.
At this time, CDT doesn't allow users to provide VNF password from the GUI. To update the VNF password we need to log into the APPC Maria DB container and change the password manually:
::
mysql -u sdnctl -p (type "gamma" when password is prompted)
use sdnctl;
UPDATE DEVICE_AUTHENTICATION SET PASSWORD='admin' WHERE
VNF_TYPE='vLoadBalancerMS/vLoadBalancerMS 0'; (use your VNF type)
1-6 Using SO : Setting the Controller Type in SO Database
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
Users need to specify which controller to use for the scale out use case. For Dublin, the supported controller is APPC. Users need to create an association between the controller and the VNF type in the SO database.
To do so:
- Connect to one of the replicas of the MariaDB database
- Type
::
mysql -ucataloguser -pcatalog123
- Use catalogdb databalse
::
use catalogdb;
- Create an association between APPC and the VNF type, for example:
::
INSERT INTO controller_selection_reference (`VNF_TYPE`, `CONTROLLER_NAME`, `ACTION_CATEGORY`) VALUES ('<VNF Type>', 'APPC', 'ConfigScaleOut');
INSERT INTO controller_selection_reference (`VNF_TYPE`, `CONTROLLER_NAME`, `ACTION_CATEGORY`) VALUES ('<VNF Type>', 'APPC', 'HealthCheck');
SO has a default entry for VNF type "vLoadBalancerMS/vLoadBalancerMS 0"
PART 2 - Scale Out Use Case Instantiation
-----------------------------------------
GET information from SDC catalogdb
::
curl -X GET \
'https://{{k8s}}:30204/sdc/v1/catalog/services' \
-H 'Authorization: Basic dmlkOktwOGJKNFNYc3pNMFdYbGhhazNlSGxjc2UyZ0F3ODR2YW9HR21KdlV5MlU=' \
-H 'X-ECOMP-InstanceID: VID' \
-H 'cache-control: no-cache'
In the response you should find values for:
* service-uuid
* service-invariantUUID
* service-name
GET informations from SO catalogdb
::
curl -X GET \
'http://{{k8s}}:30744/ecomp/mso/catalog/v2/serviceVnfs?serviceModelName={{service-name}}' \
-H 'Authorization: Basic YnBlbDpwYXNzd29yZDEk' \
-H 'cache-control: no-cache'
In the response you should find values for:
* vnf-modelinfo-modelname
* vnf-modelinfo-modeluuid
* vnf-modelinfo-modelinvariantuuid
* vnf-modelinfo-modelcustomizationuuid
* vnf-modelinfo-modelinstancename
* vnf-vfmodule-0-modelinfo-modelname
* vnf-vfmodule-0-modelinfo-modeluuid
* vnf-vfmodule-0-modelinfo-modelinvariantuuid
* vnf-vfmodule-0-modelinfo-modelcustomizationuuid
* vnf-vfmodule-1-modelinfo-modelname
* vnf-vfmodule-1-modelinfo-modeluuid
* vnf-vfmodule-1-modelinfo-modelinvariantuuid
* vnf-vfmodule-1-modelinfo-modelcustomizationuuid
* vnf-vfmodule-2-modelinfo-modelname
* vnf-vfmodule-2-modelinfo-modeluuid
* vnf-vfmodule-2-modelinfo-modelinvariantuuid
* vnf-vfmodule-2-modelinfo-modelcustomizationuuid
* vnf-vfmodule-3-modelinfo-modelname
* vnf-vfmodule-3-modelinfo-modeluuid
* vnf-vfmodule-3-modelinfo-modelinvariantuuid
* vnf-vfmodule-3-modelinfo-modelcustomizationuuid
Note : all those informations are also available in the TOSCA service template in the SDC
You need after:
* the SSH public key value that will allow you to connect to the VM.
* the cloudSite name and TenantId where to deploy the service
* the name of the security group that will be used in the tenant for your service
* the name of the network that will be used to connect your VM
* the name of your OpenStack image
* the name of your OpenStack VM flavor
We supposed here that we are using some already declared informations:
* customer named "Demonstration"
* subscriptionServiceType named "vLB"
* projectName named "Project-Demonstration"
* owningEntityName named "OE-Demonstration"
* platformName named "test"
* lineOfBusinessName named "someValue"
Having all those information, you are now able to build the SO request
that will instantiate Service, VNF, VF modules and Heat stacks:
::
curl -X POST \
'http://{{k8s}}:30277/onap/so/infra/serviceInstantiation/v7/serviceInstances' \
-H 'Content-Type: application/json' \
-H 'cache-control: no-cache' \
-d '{
"requestDetails": {
"subscriberInfo": {
"globalSubscriberId": "Demonstration"
},
"requestInfo": {
"suppressRollback": false,
"productFamilyId": "a9a77d5a-123e-4ca2-9eb9-0b015d2ee0fb",
"requestorId": "VID",
"instanceName": "{{service-instance-name}}",
"source": "VID"
},
"cloudConfiguration": {
"lcpCloudRegionId": "{{cloud-region}}",
"tenantId": "{{tenantId}}"
},
"requestParameters": {
"subscriptionServiceType": "vLB",
"userParams": [
{
"Homing_Solution": "none"
},
{
"service": {
"instanceParams": [
],
"instanceName": "{{service-instance-name}}",
"resources": {
"vnfs": [
{
"modelInfo": {
"modelName": "{{vnf-modelinfo-modelname}}",
"modelVersionId": "{{vnf-modelinfo-modeluuid}}",
"modelInvariantUuid": "{{vnf-modelinfo-modelinvariantuuid}}",
"modelVersion": "1.0",
"modelCustomizationId": "{{vnf-modelinfo-modelcustomizationuuid}}",
"modelInstanceName": "{{vnf-modelinfo-modelinstancename}}"
},
"cloudConfiguration": {
"lcpCloudRegionId": "{{CloudSite-name}}",
"tenantId": "{{tenantId}}"
},
"platform": {
"platformName": "test"
},
"lineOfBusiness": {
"lineOfBusinessName": "someValue"
},
"productFamilyId": "a9a77d5a-123e-4ca2-9eb9-0b015d2ee0fb",
"instanceName": "{{vnf-modelinfo-modelinstancename}}",
"instanceParams": [
{
"onap_private_net_id": "olc-private",
"onap_private_subnet_id": "olc-private",
"pub_key": "{{Your SSH public key value}}",
"image_name": "{{my_image_name}}",
"flavor_name":"{{my_VM_flavor_name}}"
}
],
"vfModules": [
{
"modelInfo": {
"modelName": "{{vnf-vfmodule-0-modelinfo-modelname}}",
"modelVersionId": "{{vnf-vfmodule-0-modelinfo-modeluuid}}",
"modelInvariantUuid": "{{vnf-vfmodule-0-modelinfo-modelinvariantuuid}}",
"modelVersion": "1",
"modelCustomizationId": "{{vnf-vfmodule-0-modelinfo-modelcustomizationuuid}}"
},
"instanceName": "{{vnf-vfmodule-0-modelinfo-modelname}}",
"instanceParams": [
{
"sec_group": "{{your_security_group_name}}",
"public_net_id": "{{your_public_network_name}}"
}
]
},
{
"modelInfo": {
"modelName": "{{vnf-vfmodule-1-modelinfo-modelname}}",
"modelVersionId": "{{vnf-vfmodule-1-modelinfo-modeluuid}}",
"modelInvariantUuid": "{{vnf-vfmodule-1-modelinfo-modelinvariantuuid}}",
"modelVersion": "1",
"modelCustomizationId": "{{vnf-vfmodule-1-modelinfo-modelcustomizationuuid}}"
},
"instanceName": "{{vnf-vfmodule-1-modelinfo-modelname}}",
"instanceParams": [
{
"sec_group": "{{your_security_group_name}}",
"public_net_id": "{{your_public_network_name}}"
}
]
},
{
"modelInfo": {
"modelName": "{{vnf-vfmodule-2-modelinfo-modelname}}",
"modelVersionId": "{{vnf-vfmodule-2-modelinfo-modeluuid}}",
"modelInvariantUuid": "{{vnf-vfmodule-2-modelinfo-modelinvariantuuid}}",
"modelVersion": "1",
"modelCustomizationId": "{{vnf-vfmodule-2-modelinfo-modelcustomizationuuid}}"
},
"instanceName": "{{vnf-vfmodule-2-modelinfo-modelname}}",
"instanceParams": [
{
"sec_group": "{{your_security_group_name}}",
"public_net_id": "{{your_public_network_name}}"
}
]
},
{
"modelInfo": {
"modelName": "{{vnf-vfmodule-3-modelinfo-modelname}}",
"modelVersionId": "{{vnf-vfmodule-3-modelinfo-modeluuid}}",
"modelInvariantUuid": "{{vnf-vfmodule-3-modelinfo-modelinvariantuuid}}",
"modelVersion": "1",
"modelCustomizationId": "{{vnf-vfmodule-3-modelinfo-modelcustomizationuuid}}"
},
"instanceName": "{{vnf-vfmodule-3-modelinfo-modelname}}",
"instanceParams": [
{
"sec_group": "{{your_security_group_name}}",
"public_net_id": "{{your_public_network_name}}"
}
]
}
]
}
]
},
"modelInfo": {
"modelVersion": "1.0",
"modelVersionId": "{{service-uuid}}",
"modelInvariantId": "{{service-invariantUUID}}",
"modelName": "{{service-name}}",
"modelType": "service"
}
}
}
],
"aLaCarte": false
},
"project": {
"projectName": "Project-Demonstration"
},
"owningEntity": {
"owningEntityId": "24ef5425-bec4-4fa3-ab03-c0ecf4eaac96",
"owningEntityName": "OE-Demonstration"
},
"modelInfo": {
"modelVersion": "1.0",
"modelVersionId": "{{service-uuid}}",
"modelInvariantId": "{{service-invariantUUID}}",
"modelName": "{{service-name}}",
"modelType": "service"
}
}
}'
In the response, you will obtain a requestId that will be usefull
to follow the instantiation request status in the ONAP SO:
::
curl -X GET \
'http://{{k8s}}:30086/infraActiveRequests/{{requestid}}' \
-H 'cache-control: no-cache'
PART 3 - Post Instantiation Operations
--------------------------------------
3-1 Using the VNF : vLB Manual Configuration
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
After the VNF has been instantiated using the CDS configuration blueprint, user should manually configure the vLB to open a connection towards the vDNS. At this time, the use case doesn't support automated post-instantiation configuration with CDS. Note that this step is NOT required during scale out operations, as VNF reconfiguration will be triggered by SO and executed by APPC. To change the state of the vLB, the users can run the following REST call, replacing the IP addresses in the VNF endpoint and JSON object to match the private IP addresses of their vDNS instance:
::
curl -X PUT \
http://10.12.5.78:8183/restconf/config/vlb-business-vnf-onap-plugin:vlb-business-vnf-onap-plugin/vdns-instances/vdns-instance/192.168.10.59 \
-H 'Accept: application/json' \
-H 'Content-Type: application/json' \
-H 'Postman-Token: a708b064-adb1-4804-89a7-ee604f5fe76f' \
-H 'cache-control: no-cache' \
-d '{
"vdns-instance": [
{
"ip-addr": "192.168.10.59",
"oam-ip-addr": "10.0.101.49",
"enabled": true
}
]
}'
At this point, the VNF is fully set up.
3-2 Updating AAI with VNF resources
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
To allow automated scale out via closed loop, the users need to inventory the VNF resources in AAI. This is done by running the heatbridge python script in /root/oom/kubernetes/robot in the Rancher VM in the Kubernetes cluster:
::
./demo-k8s.sh onap heatbridge <vLB stack_name in OpenStack> <service_instance_id> vLB vlb_onap_private_ip_0
Heatbridge is needed for control loops because DCAE and Policy runs queries against AAI using vServer names as key.
PART 4 - Triggering Scale Out Manually
--------------------------------------
For scale out with manual trigger, VID is not supported at this time. Users can run the use case by directly calling SO APIs:
::
curl -X POST \
http://<Any_K8S_Node_IP_Address>:30277/onap/so/infra/serviceInstantiation/v7/serviceInstances/7d3ca782-c486-44b3-9fe5-39f322d8ee80/vnfs/9d33cf2d-d6aa-4b9e-a311-460a6be5a7de/vfModules/scaleOut \
-H 'Accept: application/json' \
-H 'Authorization: Basic SW5mcmFQb3J0YWxDbGllbnQ6cGFzc3dvcmQxJA==' \
-H 'Cache-Control: no-cache' \
-H 'Connection: keep-alive' \
-H 'Content-Type: application/json' \
-H 'Postman-Token: 12f2601a-4eb2-402c-a51a-f29502359501,9befda68-b2c9-4e7a-90ca-1be9c24ef664' \
-H 'User-Agent: PostmanRuntime/7.15.0' \
-H 'accept-encoding: gzip, deflate' \
-H 'cache-control: no-cache' \
-H 'content-length: 2422' \
-H 'cookie: JSESSIONID=B3BA24216367F9D39E3DF5E8CBA4BC64' \
-b JSESSIONID=B3BA24216367F9D39E3DF5E8CBA4BC64 \
-d '{
"requestDetails": {
"modelInfo": {
"modelCustomizationName": "VdnsloadbalancerCds..vdns..module-3",
"modelCustomizationId": "ded42059-2f35-42d4-848b-16e1ab1ad197",
"modelInvariantId": "2815d321-c6b4-4f21-b7f7-fa5adf8ed7d9",
"modelVersionId": "524e34ed-9789-453e-ab73-8eff30eafef3",
"modelName": "VdnsloadbalancerCds..vdns..module-3",
"modelType": "vfModule",
"modelVersion": "1"
},
"cloudConfiguration": {
"lcpCloudRegionId": "RegionOne",
"tenantId": "d570c718cbc545029f40e50b75eb13df",
"cloudOwner": "CloudOwner"
},
"requestInfo": {
"instanceName": "vDNS-VM-02",
"source": "VID",
"suppressRollback": false,
"requestorId": "demo"
},
"requestParameters": {
"userParams": []
},
"relatedInstanceList": [
{
"relatedInstance": {
"instanceId": "7d3ca782-c486-44b3-9fe5-39f322d8ee80",
"modelInfo": {
"modelType": "service",
"modelInvariantId": "dfabdcae-cf50-4801-9885-9a3a9cc07e6f",
"modelVersionId": "ee55b537-7be5-4377-93c1-5d92931b6a78",
"modelName": "vLoadBalancerCDS",
"modelVersion": "1.0"
}
}
},
{
"relatedInstance": {
"instanceId": "9d33cf2d-d6aa-4b9e-a311-460a6be5a7de",
"modelInfo": {
"modelType": "vnf",
"modelInvariantId": "a77f9280-5c02-46cd-b1fc-855975db9df9",
"modelVersionId": "ff0e99ce-a521-44b5-b11b-da7e07ac83fc",
"modelName": "vLoadBalancerCDS",
"modelVersion": "1.0",
"modelCustomizationId": "b8b8a25d-19de-4581-bb63-f2dc8c0d79a7"
}
}
}
],
"configurationParameters": [
{
"ip-addr": "$.vf-module-topology.vf-module-parameters.param[17].value",
"oam-ip-addr": "$.vf-module-topology.vf-module-parameters.param[31].value"
}
]
}
}'
To fill in the JSON object, users need to download the Service Model TOSCA template from the SDC Portal using one of the standard SDC users (for example user: cs0008, password: demo123456!). After logging to SDC, the user should select from the catalog the vLB service that they created, click the "TOSCA Artifacts" link on the left, and finally the download button on the right, as shown in the figure below:
.. figure:: files/scaleout/tosca_template_fig.png
:align: center
For the example described below, users can refer to the TOSCA template linked at the top of the page. The template contains all the model (invariant/version/customization) IDs of service, VNF, and VF modules that the input request to SO needs.
The values of modelInvariantId, modelVersionId, and modelName in the relatedInstance item identified by "modelType": "service" in the JSON request to SO have to match invariantUUID, UUID, and name, respectively, in the TOSCA template:
::
{
"relatedInstance": {
"instanceId": "7d3ca782-c486-44b3-9fe5-39f322d8ee80",
"modelInfo": {
"modelType": "service",
"modelInvariantId": "dfabdcae-cf50-4801-9885-9a3a9cc07e6f",
"modelVersionId": "ee55b537-7be5-4377-93c1-5d92931b6a78",
"modelName": "vLoadBalancerCDS",
"modelVersion": "1.0"
}
}
}
.. figure:: files/scaleout/service.png
:align: center
The values of modelInvariantId, modelVersionId, modelName, and modelVersion in the relatedInstance item identified by "modelType": "vnf" in the JSON request to SO have to match invariantUUID, UUID, name, and version, respectively, in the TOSCA template:
::
{
"relatedInstance": {
"instanceId": "9d33cf2d-d6aa-4b9e-a311-460a6be5a7de",
"modelInfo": {
"modelType": "vnf",
"modelInvariantId": "a77f9280-5c02-46cd-b1fc-855975db9df9",
"modelVersionId": "ff0e99ce-a521-44b5-b11b-da7e07ac83fc",
"modelName": "vLoadBalancerCDS",
"modelVersion": "1.0",
"modelCustomizationId": "b8b8a25d-19de-4581-bb63-f2dc8c0d79a7"
}
}
}
.. figure:: files/scaleout/vnf.png
:align: center
The modelCustomizationId, modelInvariantId, modelVersionId, modelName, and modelVersion in the modelInfo item identified by "modelType": "vfModule" in the JSON request to SO have to match vfModuleModelCustomizationUUID, vfModuleModelInvariantUUID, vfModuleModelUUID, vfModuleModelName, and vfModuleModelVersion, respectively, in the TOSCA template. The modelCustomizationName parameter in the SO object can be set as the modelName parameter in the same JSON object:
::
"modelInfo": {
"modelCustomizationName": "Vloadbalancercds..vdns..module-3",
"modelCustomizationId": "ded42059-2f35-42d4-848b-16e1ab1ad197",
"modelInvariantId": "2815d321-c6b4-4f21-b7f7-fa5adf8ed7d9",
"modelVersionId": "524e34ed-9789-453e-ab73-8eff30eafef3",
"modelName": "Vloadbalancercds..vdns..module-3",
"modelType": "vfModule",
"modelVersion": "1"
}
The vLB-vDNS-vPacketGenerator VNF that we use to describe the scale out use case supports the scaling of the vDNS VF module only. As such, in the TOSCA template users should refer to the section identified by "vfModuleModelName": "Vloadbalancercds..vdns..module-3", as highlighted below:
.. figure:: files/scaleout/service.png
:align: center
Note that both Service and VNF related instances have a field called "instanceId" that represent the Service and VNF instance ID, respectively. These IDs are assigned at Service and VNF instantiation time and can be retrieved from AAI, querying for generic VNF objects:
::
curl -k -X GET \
https://<Any_K8S_Node_IP_Address>:30233/aai/v16/network/generic-vnfs \
-H 'Accept: application/json' \
-H 'Authorization: Basic QUFJOkFBSQ==' \
-H 'Content-Type: application/json' \
-H 'X-FromAppId: AAI' \
-H 'X-TransactionId: get_aai_subscr'
From the list of VNFs reported by AAI, search for the name of the VNF that was previously instantiated, for example "vLB_VNF_01" in the example below:
::
{
"vnf-id": "9d33cf2d-d6aa-4b9e-a311-460a6be5a7de",
"vnf-name": "vLB_VNF_01",
"vnf-type": "vLoadBalancer/vLoadBalancer 0",
"prov-status": "ACTIVE",
"equipment-role": "",
"orchestration-status": "Active",
"ipv4-oam-address": "10.0.220.10",
"in-maint": true,
"is-closed-loop-disabled": false,
"resource-version": "1565817789379",
"model-invariant-id": "a77f9280-5c02-46cd-b1fc-855975db9df9",
"model-version-id": "ff0e99ce-a521-44b5-b11b-da7e07ac83fc",
"model-customization-id": "b8b8a25d-19de-4581-bb63-f2dc8c0d79a7",
"selflink": "restconf/config/GENERIC-RESOURCE-API:services/service/7d3ca782-c486-44b3-9fe5-39f322d8ee80/service-data/vnfs/vnf/9d33cf2d-d6aa-4b9e-a311-460a6be5a7de/vnf-data/vnf-topology/",
"relationship-list": {
"relationship": [
{
"related-to": "service-instance",
"relationship-label": "org.onap.relationships.inventory.ComposedOf",
"related-link": "/aai/v16/business/customers/customer/Demonstration/service-subscriptions/service-subscription/vRAR/service-instances/service-instance/7d3ca782-c486-44b3-9fe5-39f322d8ee80",
"relationship-data": [
{
"relationship-key": "customer.global-customer-id",
"relationship-value": "Demonstration"
},
{
"relationship-key": "service-subscription.service-type",
"relationship-value": "vLB"
},
{
"relationship-key": "service-instance.service-instance-id",
"relationship-value": "7d3ca782-c486-44b3-9fe5-39f322d8ee80"
}
],
"related-to-property": [
{
"property-key": "service-instance.service-instance-name",
"property-value": "vLB-Service-0814-1"
}
]
}
...
}
To identify the VNF ID, look for the "vnf-id" parameter at the top of the JSON object, while to determine the Service ID, look for the "relationship-value" parameter corresponding to the "relationship-key": "service-instance.service-instance-id" item in the "relationship-data" list. In the example above, the Service instance ID is 7d3ca782-c486-44b3-9fe5-39f322d8ee80, while the VNF ID is 9d33cf2d-d6aa-4b9e-a311-460a6be5a7de.
These IDs are also used in the URL request to SO:
::
http://<Any_K8S_Node_IP_Address>:30277/onap/so/infra/serviceInstantiation/v7/serviceInstances/7d3ca782-c486-44b3-9fe5-39f322d8ee80/vnfs/9d33cf2d-d6aa-4b9e-a311-460a6be5a7de/vfModules/scaleOut
Finally, the "configurationParameters" section in the JSON request to SO contains the parameters that will be used to reconfigure the VNF after scaling. This is use-case specific and depends on the VNF in use. For example, the vLB-vDNS-vPacketGenerator VNF described in this documentation use the vLB as "anchor" point. The vLB maintains the state of the VNF, which, for this use case is the list of active vDNS instances. After creating a new vDNS instance, the vLB needs to know the IP addresses (of the internal private network and management network) of the new vDNS. The reconfiguration action is executed by APPC, which receives those IP addresses from SO during the scale out workflow execution. Note that different VNFs may have different reconfiguration actions. The "configurationParameters" section describes how to resolve the parameters used for VNF reconfiguration. A parameter resolution is expressed as JSON path to the SDNC VF module topology parameter array. For each reconfiguration parameter, the user has to specify the array location that contains the corresponding value (IP address in the specific case).
::
"configurationParameters": [
{
"ip-addr": "$.vf-module-topology.vf-module-parameters.param[17].value",
"oam-ip-addr": "$.vf-module-topology.vf-module-parameters.param[31].value"
}
]
Users can determine the correct location by querying the SDNC topology object. The URL can be obtained from the generic AAI object shown above ("selflink"), plus the path to the specific VF module object:
::
vf-modules/vf-module/6c24d10b-ece8-4d02-ab98-be283b17cdd3/vf-module-data/vf-module-topology/
The complete URL becomes:
::
http://<Any_K8S_Node_IP_Address>:30202/restconf/config/GENERIC-RESOURCE-API:services/service/eb6defa7-d679-4e03-a348-5f78ac9464e9/service-data/vnfs/vnf/0dd8658a-3791-454e-a35a-691f227faa86/vnf-data/vnf-topology/vf-modules/vf-module/6c24d10b-ece8-4d02-ab98-be283b17cdd3/vf-module-data/vf-module-topology/
In future releases, we plan to leverage CDS for reconfiguration actions, so as to remove the dependency from JSON paths and simplify the process.
PART 5 - Running the Scale Out Use Case with Configuration Preload
------------------------------------------------------------------
While Dublin release introduces CDS to model and automate the generation of cloud configuration for VNF instantiation, the manual preload approach is still supported for scale out with manual trigger (no closed loop).
The procedure is similar to one described above, with some minor changes:
1) **Service Design and Creation**: The heat template used to create a vendor software product in SDC is the same. However, during property assignment (Section 1-2) "sdnc_artifact_name", "sdnc_model_version", "sdnc_model_name" **must be** left blank, as they are used for CDS only.
2) As closed loop with preload is not supported for scale out, DCAE blueprint and Policy onboarding (Section 1-2), deployment of naming policy (Section 1-3), and closed loop design and deployment from CLAMP (Section 1-4) are not necessary.
3) **Creation of VNF template with CDT** works as described in Section 1-5.
4) **Controller type selection** in SO works as described in Section 1-6.
5) **VNF instantiation from VID**: users can use VID to create the service, the VNF, and instantiate the VF modules. Based on the Heat template structure, there are four VF modules:
* module-0: base module that contains resources, such as internal private networks and public key, shared across the VNF elements
* module-1: vLB resource descriptor
* module-2: vPacketGen resource descriptor
* module-3: vDNS resource descriptor
These VF modules have to be installed in the following order, so as to satisfy heat dependencies: module-0, module-1, module-2, module-3. The parameters defined in the Heat environment files can be overridden by loading cloud configuration to SDNC before the VF modules are instantiated. See example of preloads below. They need to be customized based on the OpenStack cloud and execution environment in which the VF modules are going to be instantiated.
Module-0 Preload
~~~~~~~~~~~~~~~~
::
curl -X POST \
http://<Any_K8S_Node_IP_Address>:30202/restconf/operations/GENERIC-RESOURCE-API:preload-vf-module-topology-operation \
-H 'Content-Type: application/json' \
-H 'Postman-Token: 0a7abc62-9d8f-4f63-8b05-db7cc4c3e28b' \
-H 'cache-control: no-cache' \
-d '{
"input": {
"preload-vf-module-topology-information": {
"vf-module-topology": {
"vf-module-topology-identifier": {
"vf-module-name": "vNetworks-0211-1"
},
"vf-module-parameters": {
"param": [
{
"name": "vlb_private_net_id",
"value": "vLBMS_zdfw1lb01_private_ms"
},
{
"name": "pktgen_private_net_id",
"value": "vLBMS_zdfw1pktgen01_private_ms"
},
{
"name": "vlb_private_net_cidr",
"value": "192.168.10.0/24"
},
{
"name": "pktgen_private_net_cidr",
"value": "192.168.9.0/24"
},
{
"name": "vlb_0_int_pktgen_private_port_0_mac",
"value": "fa:16:3e:00:01:10"
},
{
"name": "vpg_0_int_pktgen_private_port_0_mac",
"value": "fa:16:3e:00:01:20"
},
{
"name": "vnf_id",
"value": "vLoadBalancerMS"
},
{
"name": "vnf_name",
"value": "vLBMS"
},
{
"name": "key_name",
"value": "vlb_key"
},
{
"name": "pub_key",
"value": "ssh-rsa AAAAB3NzaC1yc2EAAAADAQABAAABAQDQXYJYYi3/OUZXUiCYWdtc7K0m5C0dJKVxPG0eI8EWZrEHYdfYe6WoTSDJCww+1qlBSpA5ac/Ba4Wn9vh+lR1vtUKkyIC/nrYb90ReUd385Glkgzrfh5HdR5y5S2cL/Frh86lAn9r6b3iWTJD8wBwXFyoe1S2nMTOIuG4RPNvfmyCTYVh8XTCCE8HPvh3xv2r4egawG1P4Q4UDwk+hDBXThY2KS8M5/8EMyxHV0ImpLbpYCTBA6KYDIRtqmgS6iKyy8v2D1aSY5mc9J0T5t9S2Gv+VZQNWQDDKNFnxqYaAo1uEoq/i1q63XC5AD3ckXb2VT6dp23BQMdDfbHyUWfJN"
}
]
}
},
"vnf-topology-identifier-structure": {
"vnf-name": "vLoadBalancer-Vnf-0211-1",
"vnf-type": "vLoadBalancer/vLoadBalancer 0"
},
"vnf-resource-assignments": {
"availability-zones": {
"availability-zone": [
"nova"
],
"max-count": 1
},
"vnf-networks": {
"vnf-network": []
}
}
},
"request-information": {
"request-id": "robot12",
"order-version": "1",
"notification-url": "openecomp.org",
"order-number": "1",
"request-action": "PreloadVfModuleRequest"
},
"sdnc-request-header": {
"svc-request-id": "robot12",
"svc-notification-url": "http://openecomp.org:8080/adapters/rest/SDNCNotify",
"svc-action": "reserve"
}
}
}'
Module-1 Preload
~~~~~~~~~~~~~~~~
::
curl -X POST \
http://<Any_K8S_Node_IP_Address>:30202/restconf/operations/GENERIC-RESOURCE-API:preload-vf-module-topology-operation \
-H 'Content-Type: application/json' \
-H 'Postman-Token: 662914ac-29fc-414d-8823-1691fb2c718a' \
-H 'cache-control: no-cache' \
-d '{
"input": {
"preload-vf-module-topology-information": {
"vf-module-topology": {
"vf-module-topology-identifier": {
"vf-module-name": "vLoadBalancer-0211-1"
},
"vf-module-parameters": {
"param": [
{
"name": "vlb_image_name",
"value": "ubuntu-16-04-cloud-amd64"
},
{
"name": "vlb_flavor_name",
"value": "m1.medium"
},
{
"name": "public_net_id",
"value": "public"
},
{
"name": "int_private_net_id",
"value": "vLBMS_zdfw1lb01_private_ms"
},
{
"name": "int_private_subnet_id",
"value": "vLBMS_zdfw1lb01_private_sub_ms"
},
{
"name": "int_pktgen_private_net_id",
"value": "vLBMS_zdfw1pktgen01_private_ms"
},
{
"name": "int_pktgen_private_subnet_id",
"value": "vLBMS_zdfw1pktgen01_private_sub_ms"
},
{
"name": "onap_private_net_id",
"value": "oam_onap_vnf_test"
},
{
"name": "onap_private_subnet_id",
"value": "oam_onap_vnf_test"
},
{
"name": "vlb_private_net_cidr",
"value": "192.168.10.0/24"
},
{
"name": "pktgen_private_net_cidr",
"value": "192.168.9.0/24"
},
{
"name": "onap_private_net_cidr",
"value": "10.0.0.0/16"
},
{
"name": "vlb_int_private_ip_0",
"value": "192.168.10.111"
},
{
"name": "vlb_onap_private_ip_0",
"value": "10.0.150.1"
},
{
"name": "vlb_int_pktgen_private_ip_0",
"value": "192.168.9.111"
},
{
"name": "vdns_int_private_ip_0",
"value": "192.168.10.211"
},
{
"name": "vdns_onap_private_ip_0",
"value": "10.0.150.3"
},
{
"name": "vpg_int_pktgen_private_ip_0",
"value": "192.168.9.110"
},
{
"name": "vpg_onap_private_ip_0",
"value": "10.0.150.2"
},
{
"name": "vlb_name_0",
"value": "vlb-0211-1"
},
{
"name": "vlb_0_mac_address",
"value": "fa:16:3e:00:01:10"
},
{
"name": "vpg_0_mac_address",
"value": "fa:16:3e:00:01:20"
},
{
"name": "vip",
"value": "192.168.9.112"
},
{
"name": "gre_ipaddr",
"value": "192.168.10.112"
},
{
"name": "vnf_id",
"value": "vLoadBalancerMS"
},
{
"name": "vf_module_id",
"value": "vLoadBalancerMS"
},
{
"name": "vnf_name",
"value": "vLBMS"
},
{
"name": "dcae_collector_ip",
"value": "10.12.5.20"
},
{
"name": "dcae_collector_port",
"value": "30235"
},
{
"name": "demo_artifacts_version",
"value": "1.6.0-SNAPSHOT"
},
{
"name": "install_script_version",
"value": "1.6.0-SNAPSHOT"
},
{
"name": "nb_api_version",
"value": "1.2.0"
},
{
"name": "keypair",
"value": "vlb_key"
},
{
"name": "cloud_env",
"value": "openstack"
},
{
"name": "nexus_artifact_repo",
"value": "https://nexus.onap.org"
},
{
"name": "sec_group",
"value": "default"
}
]
}
},
"vnf-topology-identifier-structure": {
"vnf-name": "vLoadBalancer-Vnf-0211-1",
"vnf-type": "vLoadBalancer/vLoadBalancer 0"
},
"vnf-resource-assignments": {
"availability-zones": {
"availability-zone": [
"nova"
],
"max-count": 1
},
"vnf-networks": {
"vnf-network": []
}
}
},
"request-information": {
"request-id": "robot12",
"order-version": "1",
"notification-url": "openecomp.org",
"order-number": "1",
"request-action": "PreloadVfModuleRequest"
},
"sdnc-request-header": {
"svc-request-id": "robot12",
"svc-notification-url": "http://openecomp.org:8080/adapters/rest/SDNCNotify",
"svc-action": "reserve"
}
}
}'
Module-2 Preload
~~~~~~~~~~~~~~~~
::
curl -X POST \
http://<Any_K8S_Node_IP_Address>:30202/restconf/operations/GENERIC-RESOURCE-API:preload-vf-module-topology-operation \
-H 'Content-Type: application/json' \
-H 'Postman-Token: 5f2490b3-6e4a-4512-9a0d-0aa6f6fa0ea8' \
-H 'cache-control: no-cache' \
-d '{
"input": {
"preload-vf-module-topology-information": {
"vf-module-topology": {
"vf-module-topology-identifier": {
"vf-module-name": "vPacketGen-0211-1"
},
"vf-module-parameters": {
"param": [
{
"name": "vpg_image_name",
"value": "ubuntu-16-04-cloud-amd64"
},
{
"name": "vpg_flavor_name",
"value": "m1.medium"
},
{
"name": "public_net_id",
"value": "public"
},
{
"name": "int_pktgen_private_net_id",
"value": "vLBMS_zdfw1pktgen01_private_ms"
},
{
"name": "int_pktgen_private_subnet_id",
"value": "vLBMS_zdfw1pktgen01_private_sub_ms"
},
{
"name": "onap_private_net_id",
"value": "oam_onap_vnf_test"
},
{
"name": "onap_private_subnet_id",
"value": "oam_onap_vnf_test"
},
{
"name": "pktgen_private_net_cidr",
"value": "192.168.9.0/24"
},
{
"name": "onap_private_net_cidr",
"value": "10.0.0.0/16"
},
{
"name": "vlb_int_pktgen_private_ip_0",
"value": "192.168.9.111"
},
{
"name": "vpg_int_pktgen_private_ip_0",
"value": "192.168.9.110"
},
{
"name": "vpg_onap_private_ip_0",
"value": "10.0.150.2"
},
{
"name": "vpg_name_0",
"value": "vpg-0211-1"
},
{
"name": "vlb_0_mac_address",
"value": "fa:16:3e:00:01:10"
},
{
"name": "vpg_0_mac_address",
"value": "fa:16:3e:00:01:20"
},
{
"name": "pg_int",
"value": "192.168.9.109"
},
{
"name": "vnf_id",
"value": "vLoadBalancerMS"
},
{
"name": "vf_module_id",
"value": "vLoadBalancerMS"
},
{
"name": "vnf_name",
"value": "vLBMS"
},
{
"name": "demo_artifacts_version",
"value": "1.6.0-SNAPSHOT"
},
{
"name": "install_script_version",
"value": "1.6.0-SNAPSHOT"
},
{
"name": "nb_api_version",
"value": "1.2.0"
},
{
"name": "keypair",
"value": "vlb_key"
},
{
"name": "cloud_env",
"value": "openstack"
},
{
"name": "nexus_artifact_repo",
"value": "https://nexus.onap.org"
},
{
"name": "sec_group",
"value": "default"
}
]
}
},
"vnf-topology-identifier-structure": {
"vnf-name": "vLoadBalancer-Vnf-0211-1",
"vnf-type": "vLoadBalancer/vLoadBalancer 0"
},
"vnf-resource-assignments": {
"availability-zones": {
"availability-zone": [
"nova"
],
"max-count": 1
},
"vnf-networks": {
"vnf-network": []
}
}
},
"request-information": {
"request-id": "robot12",
"order-version": "1",
"notification-url": "openecomp.org",
"order-number": "1",
"request-action": "PreloadVfModuleRequest"
},
"sdnc-request-header": {
"svc-request-id": "robot12",
"svc-notification-url": "http://openecomp.org:8080/adapters/rest/SDNCNotify",
"svc-action": "reserve"
}
}
}'
Module-3 Preload
~~~~~~~~~~~~~~~~
::
curl -X POST \
http://<Any_K8S_Node_IP_Address>:30202/restconf/operations/GENERIC-RESOURCE-API:preload-vf-module-topology-operation \
-H 'Content-Type: application/json' \
-H 'Postman-Token: fd0a4706-f955-490a-875e-08ddd8fe002e' \
-H 'cache-control: no-cache' \
-d '{
"input": {
"preload-vf-module-topology-information": {
"vf-module-topology": {
"vf-module-topology-identifier": {
"vf-module-name": "vDNS-0125-1"
},
"vf-module-parameters": {
"param": [
{
"name": "vdns_image_name",
"value": "ubuntu-16-04-cloud-amd64"
},
{
"name": "vdns_flavor_name",
"value": "m1.medium"
},
{
"name": "public_net_id",
"value": "public"
},
{
"name": "int_private_net_id",
"value": "vLBMS_zdfw1lb01_private"
},
{
"name": "int_private_subnet_id",
"value": "vLBMS_zdfw1lb01_private_sub_ms"
},
{
"name": "onap_private_net_id",
"value": "oam_onap_vnf_test"
},
{
"name": "onap_private_subnet_id",
"value": "oam_onap_vnf_test"
},
{
"name": "vlb_private_net_cidr",
"value": "192.168.10.0/24"
},
{
"name": "onap_private_net_cidr",
"value": "10.0.0.0/16"
},
{
"name": "vlb_int_private_ip_0",
"value": "192.168.10.111"
},
{
"name": "vlb_onap_private_ip_0",
"value": "10.0.150.1"
},
{
"name": "vlb_int_pktgen_private_ip_0",
"value": "192.168.9.111"
},
{
"name": "vdns_int_private_ip_0",
"value": "192.168.10.212"
},
{
"name": "vdns_onap_private_ip_0",
"value": "10.0.150.4"
},
{
"name": "vdns_name_0",
"value": "vdns-0211-1"
},
{
"name": "vnf_id",
"value": "vLoadBalancerMS"
},
{
"name": "vf_module_id",
"value": "vLoadBalancerMS"
},
{
"name": "vnf_name",
"value": "vLBMS"
},
{
"name": "install_script_version",
"value": "1.6.0-SNAPSHOT"
},
{
"name": "nb_api_version",
"value": "1.2.0"
},
{
"name": "keypair",
"value": "vlb_key"
},
{
"name": "cloud_env",
"value": "openstack"
},
{
"name": "sec_group",
"value": "default"
},
{
"name": "nexus_artifact_repo",
"value": "https://nexus.onap.org"
}
]
}
},
"vnf-topology-identifier-structure": {
"vnf-name": "vLoadBalancer-Vnf-0125-1",
"vnf-type": "vLoadBalancer/vLoadBalancer 0"
},
"vnf-resource-assignments": {
"availability-zones": {
"availability-zone": [
"nova"
],
"max-count": 1
},
"vnf-networks": {
"vnf-network": []
}
}
},
"request-information": {
"request-id": "robot12",
"order-version": "1",
"notification-url": "openecomp.org",
"order-number": "1",
"request-action": "PreloadVfModuleRequest"
},
"sdnc-request-header": {
"svc-request-id": "robot12",
"svc-notification-url": "http://openecomp.org:8080/adapters/rest/SDNCNotify",
"svc-action": "reserve"
}
}
}'
The Heat environment files already set many parameters used for VF module instantiation. Those parameters can be reused in the SDNC preload too, while placeholders like "PUT THE IP ADDRESS HERE" or "PUT THE PUBLIC KEY HERE" must be overridden.
To instantiate VF modules, please refer to this wiki page: https://wiki.onap.org/display/DW/Tutorial+vIMS%3A+VID+Instantiate+the+VNF using vLB as ServiceType.
6) **Post Instantiation Actions**: Please refer to Sections 3-1 for vLB configuration and Section 3-2 for resource orchestration with heatbridge.
7) **Triggering Scale Out Manually**: Please refer to Section 4 to trigger scale out manually with direct API call to SO.
PART 6 - Test Status and Plans
------------------------------
Dublin Scale Out test cases can be found here: https://wiki.onap.org/pages/viewpage.action?pageId=59966105
PART 7 - Known Issues and Resolutions
-------------------------------------
1) When running closed loop-enabled scale out, the closed loop designed in CLAMP conflicts with the default closed loop defined for the old vLB/vDNS use case
Resolution: Change TCA configuration for the old vLB/vDNS use case
- Connect to Consul: http://<ANY K8S VM IP ADDRESS>:30270 and click on "Key/Value" → "dcae-tca-analytics"
- Change "eventName" in the vLB default policy to something different, for example "vLB" instead of the default value "vLoadBalancer"
- Change "subscriberConsumerGroup" in the TCA configuration to something different, for example "OpenDCAE-c13" instead of the default value "OpenDCAE-c12"
- Click "UPDATE" to upload the new TCA configuration