aboutsummaryrefslogtreecommitdiffstats
diff options
context:
space:
mode:
-rw-r--r--docs/conf.py2
-rw-r--r--docs/docs_5G_PNF_Software_Upgrade_With_Schema_Update.rst5
-rw-r--r--docs/docs_NFV_Testing_Automatic_Platform_Requirements_User_Guide.rst93
-rw-r--r--docs/docs_Testing_5G_PNF_Software_Upgrade_With_Schema_Update.rst189
-rw-r--r--docs/docs_scaleout.rst148
-rw-r--r--docs/files/softwareUpgrade/serviceModelVersions.pngbin0 -> 374401 bytes
-rw-r--r--docs/files/softwareUpgrade/verifyPNF.pngbin0 -> 348103 bytes
-rw-r--r--docs/files/softwareUpgrade/workflowList.pngbin0 -> 244285 bytes
-rw-r--r--docs/integration-s3p.rst10
9 files changed, 377 insertions, 70 deletions
diff --git a/docs/conf.py b/docs/conf.py
index d042f2ce5..1297b0b33 100644
--- a/docs/conf.py
+++ b/docs/conf.py
@@ -16,11 +16,13 @@ linkcheck_ignore = [
r'http://SINK_IP_ADDRESS:667.*',
r'http.*K8S_HOST:30227.*',
r'http.*K8S_NODE_IP.*',
+ r'http.*REPO_IP.*',
'http://team.onap.eu'
]
intersphinx_mapping = {}
intersphinx_mapping['onap-oom'] = ('{}/onap-oom/en/%s'.format(doc_url) % branch, None)
+intersphinx_mapping['onap-cli'] = ('{}/onap-cli/en/%s'.format(doc_url) % branch, None)
html_last_updated_fmt = '%d-%b-%y %H:%M'
diff --git a/docs/docs_5G_PNF_Software_Upgrade_With_Schema_Update.rst b/docs/docs_5G_PNF_Software_Upgrade_With_Schema_Update.rst
index a95dec772..c844f1f5d 100644
--- a/docs/docs_5G_PNF_Software_Upgrade_With_Schema_Update.rst
+++ b/docs/docs_5G_PNF_Software_Upgrade_With_Schema_Update.rst
@@ -107,3 +107,8 @@ Reference
~~~~~~~~~~~
`PNF Software Upgrade with Schema Update Wiki Page <https://wiki.onap.org/pages/viewpage.action?pageId=81400388#SupportxNFSoftwareUpgradeinassociationtoschemaupdates-DevelopmentStatus>`_
+
+Testing Procedure
+~~~~~~~~~~~~~~~~~~
+
+:ref:`Testing 5G PNF Software Upgrade with Schema Update <docs_Testing_5G_PNF_Software_Upgrade_With_Schema_Update>` \ No newline at end of file
diff --git a/docs/docs_NFV_Testing_Automatic_Platform_Requirements_User_Guide.rst b/docs/docs_NFV_Testing_Automatic_Platform_Requirements_User_Guide.rst
index 30d4a1647..65d0e41a3 100644
--- a/docs/docs_NFV_Testing_Automatic_Platform_Requirements_User_Guide.rst
+++ b/docs/docs_NFV_Testing_Automatic_Platform_Requirements_User_Guide.rst
@@ -1,29 +1,59 @@
-======================================================
+.. nfv_testing_automation_platform_requirements:
+
+:orphan:
+
+=======================================================
NFV Testing Automatic Platform Requirements- User Guide
-======================================================
-.. Overview: this page used to explain how to use NFV testing automatic platform, the relevant requirements include REQ-335(Support for Test Topology Auto Design), REQ-336(Support for Test Environment Auto Deploy),REQ_337(Support for Test Task Auto Execution),REQ-338(Support for Test Result Auto Analysis & Certification).
+=======================================================
+
+.. Overview: this page used to explain how to use NFV testing automatic platform,
+ the relevant requirements include REQ-335(Support for Test Topology
+ Auto Design), REQ-336(Support for Test Environment Auto Deploy),
+ REQ_337(Support for Test Task Auto Execution),REQ-338(Support for
+ Test Result Auto Analysis & Certification).
Description
===========
-There are a large number of cross-department and cross-organization communications during the traditional network element, system or equipment network access test. And the manual errors are inevitable, the knowledge in test field cannot be solidified. The cost of each test is high and the test cycle is always long.
-After introducing NFV, because network element software and hardware equipment are layered decoupled, the introduction of a large number of open source components as well as the frequent upgrade of the software itself, make network access test become more complicated and frequent.
-Testing has become a bottleneck during the introduction and iteration of new technologies. Therefore, it is urgent to introduce automated test tools.
-By introducing testing automatic capabilities including topology auto design, test environment auto deploy, test task auto execution and test result auto analysis & certification, it can solidify domain knowledge, and help reduce labor costs, shorten test cycle, improve test efficiency , optimize test accuracy.
+
+There are a large number of cross-department and cross-organization communications
+during the traditional network element, system or equipment network access test.
+And the manual errors are inevitable, the knowledge in test field cannot be
+solidified. The cost of each test is high and the test cycle is always long.
+After introducing NFV, because network element software and hardware equipment are
+layered decoupled, the introduction of a large number of open source components as
+well as the frequent upgrade of the software itself, make network access test
+become more complicated and frequent.
+
+Testing has become a bottleneck during the introduction and iteration of new
+technologies. Therefore, it is urgent to introduce automated test tools.
+By introducing testing automatic capabilities including topology auto design,
+test environment auto deploy, test task auto execution and test result auto
+analysis & certification, it can solidify domain knowledge, and help reduce labor
+costs, shorten test cycle, improve test efficiency , optimize test accuracy.
Requirement Details
===================
+
Test Topology Auto Design( enhancement in SDC)
----------------------------------------------
-1.Quickly design a test service (topology) composed with tested VNF and test environment (One way is to define abstract testing service (topology) template for each type of VNF);
-2.For the service designed, can be imported into SDC for modification or enhancement, or the test template can be reused for different test environments (the SDC needs to support service import).
+1.Quickly design a test service (topology) composed with tested VNF and test
+ environment (One way is to define abstract testing service (topology) template
+ for each type of VNF);
+
+2.For the service designed, can be imported into SDC for modification or enhancement,
+ or the test template can be reused for different test environments (the SDC needs
+ to support service import).
Test Environment Auto Deploy (enhancement in VF-C)
-------------------------------------------------
-By getting VM/VL/Port/VNF/NS instance information from Openstack via Multi-cloud to VF-C for instance information storage, enable VTP obtaining all the real-time instance information.
+--------------------------------------------------
+
+By getting VM/VL/Port/VNF/NS instance information from Openstack via Multi-cloud
+to VF-C for instance information storage, enable VTP obtaining all the real-time
+instance information.
Test Task Auto Execution(enhancement in VNFSDK, CLI)
----------------------------------------------------
+----------------------------------------------------
1. Test instruments integration:
* Test Case execution;
@@ -51,39 +81,50 @@ Test Task Auto Execution(enhancement in VNFSDK, CLI)
* Enable VTP for result submission into OVP.
New Features and Guide (Guilin Release)
-======================================
+=======================================
+
SDC New features
----------------
+
Service import
>>>>>>>>>>>>>>
+
1. Add a button “IMPORT SERVICE CSAR" to perform service CSAR import.
-2. When clicking the “IMPORT SERVICE CSAR” button on the portal, a window will pop up to select the service CSAR file to be imported.
-3. After selecting the service CSAR file to be imported, it will switch to the general information input page for creating the service.
-4. After filling in all the required fields, you can click the "create" button to create a new service.
+2. When clicking the “IMPORT SERVICE CSAR” button on the portal, a window will
+ pop up to select the service CSAR file to be imported.
+3. After selecting the service CSAR file to be imported, it will switch to the
+ general information input page for creating the service.
+4. After filling in all the required fields, you can click the "create" button
+ to create a new service.
5. Add a new API for the request of importing service CSAR.
-Abstract service template
+Abstract service template
>>>>>>>>>>>>>>>>>>>>>>>>>
-1. On the general page of VF, add a IS_ABSTRACT_RESOURCE selection box, which is false by default. If it is an abstract VNF, select true manually.
+
+1. On the general page of VF, add a IS_ABSTRACT_RESOURCE selection box, which is
+ false by default. If it is an abstract VNF, select true manually.
2. Add three APIs to handle the corresponding requests of abstract service template:
- * 2.1 Return whether the service is a abstract service:GET /v1/catalog/abstract/service/serviceUUID/{uuid}/status
- * 2.2 Copy a new service based on the existing service:POST /v1/catalog/abstract/service/copy
- * 2.3 Replace the abstract VNF in the abstract service template with the actual VNF:PUT /v1/catalog/abstract/service/replaceVNF
+ 2.1 Return whether the service is a abstract service: GET /v1/catalog/abstract/service/serviceUUID/{uuid}/status
+ 2.2 Copy a new service based on the existing service: POST /v1/catalog/abstract/service/copy
+ 2.3 Replace the abstract VNF in the abstract service template with the actual VNF: PUT /v1/catalog/abstract/service/replaceVNF
VTP New features
----------------
1. Added active scenario and profile management support
2. Added integration with Robot CSIT tests
3. Enabled auto discovery of test cases from 3rd party tool integration
-4. Added support for cnf-conformance test support( In order to enable CNF conformacne tool in VTP, please refer the guide here:https://gerrit.onap.org/r/gitweb?p=vnfsdk/validation.git;a=blob;f=cnf-conformance/README.md;h=cda3dee762f4dd2873613341f60f6662880f006a;hb=refs/heads/master)
-5. New VTP API updated: https://wiki.onap.org/display/DW/VTP+REST+API+v1
+4. Added support for cnf-conformance test support( In order to enable CNF
+ conformance tool in VTP, please refer `the guide <https://gerrit.onap.org/r/gitweb?p=vnfsdk/validation.git;a=blob;f=cnf-conformance/README.md;h=cda3dee762f4dd2873613341f60f6662880f006a;hb=refs/heads/master>`_
+5. New VTP API has been updated: see the `VTP API wiki page <https://wiki.onap.org/display/DW/VTP+REST+API+v1>`_
-ClI New features
+CLI New features
----------------
+
1. Enabled auto discover and registration of products functionalities as commands
2. Profile management commands are added
-3. For the VTP Command line usage, please refer https://docs.onap.org/projects/onap-cli/en/guilin/user_guide.html
+3. For the VTP Command line usage, please refer :ref:`CLI User Guide <onap-cli:cli_user_guide>`
Test Status and Plans
=====================
-To see information on the status of the test: https://wiki.onap.org/display/DW/Automatic+Testing+Requirements
+
+See `the status of the test wiki page <https://wiki.onap.org/display/DW/Automatic+Testing+Requirements>`_
diff --git a/docs/docs_Testing_5G_PNF_Software_Upgrade_With_Schema_Update.rst b/docs/docs_Testing_5G_PNF_Software_Upgrade_With_Schema_Update.rst
new file mode 100644
index 000000000..b79d2aa21
--- /dev/null
+++ b/docs/docs_Testing_5G_PNF_Software_Upgrade_With_Schema_Update.rst
@@ -0,0 +1,189 @@
+.. This work is licensed under a Creative Commons Attribution 4.0 International License.
+.. http://creativecommons.org/licenses/by/4.0
+
+.. _docs_testing_5g_pnf_software_upgrade_with_schema_update:
+
+
+:orphan:
+
+Testing xNF Software Upgrade in association to schema updates
+-------------------------------------------------------------
+
+Description
+~~~~~~~~~~~
+This procedure only describes the test instruction to upgrade schema of a service instance with at least one PNF resource based on a new onboarding package.
+
+This procedure can be used to upgrade a service instance with more than one PNF resource.
+
+A. Pre-conditions
+~~~~~~~~~~~~~~~~~
+* A service template with at least one PNF resource has been created in SDC and distributed to run time
+
+* At least one service instance has been instantiated, including PNF registration and configuration, in run time
+
+* This service instance is in health condition
+
+* A new PNF onboarding package, which contains a new software version and new artifacts, is ready for onboarding
+
+* This procedure does not support addition of new PNF resource or deletion of existing PNF resource in the service template.
+
+
+B. Update and re-distribute the service template:
+~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
+ The service template must be updated with updated schema information for the PNF resources, and then redistributed to run time.
+
+ 1. Update an existing PNF resource artifact and attach the same to an existing service template.
+
+ - url to portal: https://portal.api.simpledemo.onap.org:30225/ONAPPORTAL/login.htm
+
+ - password for users: demo123456!
+
+ - Login as cs0008, go to "ONBOARD", where all the available VSPs and Services are listed.
+
+
+ 2. Follow below mentioned procedure to update VSP and Service.
+
+ - `Update VF/PNF <https://docs.onap.org/en/latest/guides/onap-user/design/resource-onboarding/index.html#doc-guide-user-des-res-onb-upd-vsp>`_
+
+ - `Update Service <https://docs.onap.org/en/latest/guides/onap-user/design/service-design/index.html#update-service-optional>`_
+
+
+C. Trigger PNF service level software upgrade with schema update:
+~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
+
+ Schema update procedure can be triggered manually by invoking appropriate rest end points through the postman client.
+
+ 3. Get the service level workflow uuid by fetching all the available workflows from SO:
+
+ - GET http://REPO_IP:SO_PORT/onap/so/infra/workflowSpecifications/v1/workflows
+
+ - From the response, fetch the workflow uuid against the workflow name “ServiceLevelUpgrade”.
+
+ .. image:: files/softwareUpgrade/workflowList.png
+
+
+ 4. Select one service instance which need to be upgraded
+
+ - Retrieve all services instance from AAI using:
+
+ - GET https://REPO_IP:AAI_PORT/business/customers/customer/{global-customer-id}/service-subscriptions/service-subscription/{service-type}/service-instances
+
+ - Select one service instance from the service instance list received from above query.
+
+
+ 5. Get all Service-Model-Version from AAI Using Service-Model-InVariant-UUId:
+
+ - Use the Service-Model-InVariant-UUId from the selected service instance (previous step) as model-invariant-id in this query.
+
+ - GET https://REPO_IP:AAI_PORT/aai/v21/service-design-and-creation/models/model/${model-invariant-id}/model-vers
+
+ - Select one model version Id from the model version list received from above querying. The selected model version Id will be used as the target service model version at upgrade procedure.
+
+ .. image:: files/softwareUpgrade/serviceModelVersions.png
+
+
+ 6. Invoke the service level upgrade workflow to update the schema of xNF resources.
+
+ - Invoke the service level workflow by passing the older version service model id and the service level workflow uuid for “Service Level workflow” fetched in the previous steps.
+
+ - In the body of the POST request, json input needs to be supplied that contains info on the model version to which we are going to trigger the update. (2.0)
+
+ - POST http://REPO_IP:SO_PORT/onap/so/infra/instanceManagement/v1/serviceInstances/${serviceInstanceId}/workflows/${serviceLevel_workflow_uuid}
+
+ - Attaching below a sample request json :
+
+{
+
+ "requestDetails": {
+
+ "subscriberInfo": {
+
+ "globalSubscriberId": "807c7a02-249c-4db8-9fa9-bee973fe08ce"
+
+ },
+
+ "modelInfo": {
+
+ "modelVersion": "2.0",
+
+ "modelVersionId": "8351245d-50da-4695-8756-3a22618377f7",
+
+ "modelInvariantId": "fe41489e-1563-46a3-b90a-1db629e4375b",
+
+ "modelName": "Service_with_pnfs",
+
+ "modelType": "service"
+
+ },
+
+ "requestInfo": {
+
+ "suppressRollback": false,
+
+ "requestorId": "demo",
+
+ "instanceName": "PNF 2",
+
+ "source": "VID"
+
+ },
+
+ "requestParameters": {
+
+ "subscriptionServiceType": "pNF",
+
+ "userParams": [
+
+ {
+
+ "name": "targetSoftwareVersion",
+
+ "value": "pnf_sw_version-4.0.0"
+
+ }
+
+ ],
+
+ "aLaCarte": false,
+
+ "payload": "{\"k1\": \"v1\"}"
+
+ },
+
+ "project": {
+
+ "projectName": "ServiceLevelUpgrade"
+
+ },
+
+ "owningEntity": {
+
+ "owningEntityId": "67f2e84c-734d-4e90-a1e4-d2ffa2e75849",
+
+ "owningEntityName": "OE-Test"
+
+ }
+
+ }
+
+}
+
+Note down the request id for the schema update request that can be used in the subsequent steps to track the progress.
+
+
+ 7. Verify the service level upgrade workflow status
+
+ - GET http://REPO_IP:SO_PORT/onap/so/infra/orchestrationRequests/v7/${requestID}
+
+ - Verify the response status code and message for the request id fetched in the previous step.
+
+ - For successful upgrade completion, the response code must be “200” with appropriate success message.
+
+
+ 8. Verify PNF Configuration for Service Level Upgrade from AAI
+
+ - GET https://REPO_IP:AAI_PORT/aai/v16/network/pnfs/pnf/{PNF_NAME}
+
+ - Verify the software version of the pnf resource updated in AAI.
+
+ .. image:: files/softwareUpgrade/verifyPNF.png
diff --git a/docs/docs_scaleout.rst b/docs/docs_scaleout.rst
index 55becb5c6..42b0eb59b 100644
--- a/docs/docs_scaleout.rst
+++ b/docs/docs_scaleout.rst
@@ -22,6 +22,7 @@ Useful tool
POSTMAN collection that can be used to simulate all inter process queries : https://www.getpostman.com/collections/878061d291f9efe55463
To be able to use this postman collection, you may need to expose some ports that are not exposed in OOM by default.
These commands may help for exposing the ports:
+
::
kubectl port-forward service/cds-blueprints-processor-http --address 0.0.0.0 32749:8080 -n onap &
@@ -32,10 +33,14 @@ OOM Installation
~~~~~~~~~~~~~~~~
Before doing the OOM installation, take care to the following steps:
-- Set the right Openstack values for Robot and SO:
+Set the right Openstack values for Robot and SO
+===============================================
+
The config for robot must be set in an OOM override file before the OOM installation, this will initialize the robot framework & SO with all the required openstack info.
A section like that is required in that override file
+
::
+
robot:
enabled: true
flavor: small
@@ -78,31 +83,48 @@ To know how to encrypt the openstack passwords, please look at these guides:
https://docs.onap.org/en/dublin/submodules/oom.git/docs/oom_quickstart_guide.html
https://docs.onap.org/en/elalto/submodules/oom.git/docs/oom_quickstart_guide.html
-- Initialize the Customer and Owning entities:
-The robot script can be helpful to initialize the customer and owning entity that will be used later to instantiate the VNF (PART 2 - Scale Out Use Case Instantiation)
+Initialize the Customer and Owning entities
+===========================================
+
+The robot script can be helpful to initialize the customer and owning entity that
+will be used later to instantiate the VNF (PART 2 - Scale Out Use Case Instantiation)
+
::
- In the oom_folder/kubernetes/robot/ execute the following command:
-./demo-k8s.sh onap init_customer
+
+ In the oom_folder/kubernetes/robot/ execute the following command:
+ ./demo-k8s.sh onap init_customer
If this command is unsuccessful it means that the parameters provided to the OOM installation were not correct.
- Verify and Get the tenant/owning entity/cloud-regions defined in AAI by Robot script:
-These values will be required by the POSTMAN collection when instantiating the Service/vnf ...
+ These values will be required by the POSTMAN collection when instantiating the Service/vnf ...
+
To get them some POSTMAN collection queries are useful to use:
+
- GET "AAI Owning Entities"
- GET "AAI Cloud-regions"
- GET "AAI Cloud-regions/tenant"
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.
+
+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.
+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:
+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:
::
@@ -142,7 +164,14 @@ The output below means that the vLB has been set up correctly, has forwarded the
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 Frankfurt release supports scale out with manual trigger by directly calling SO APIs and closed-loop-enabled automation from Policy. For Frankfurt, the APPC controller is used to demonstrate post-scaling VNF reconfiguration operations. APPC can handle different VNF types, not only the VNF described in this document.
+
+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 Frankfurt
+release supports scale out with manual trigger by directly calling SO APIs and
+closed-loop-enabled automation from Policy. For Frankfurt, the APPC controller is
+used to demonstrate post-scaling VNF reconfiguration operations. APPC can handle
+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.
@@ -155,27 +184,51 @@ There are four different message flows:
- 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.
+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 of the workflow 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.
+SO first contacts APPC to run VNF health check and proceeds on to the next block
+of the workflow 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 VNF Configuration Modeling and Upload with CDS (Recommended way)
-~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
+~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
+
Since 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. The user interested in running the use case only with manual preload can skip this section and start from Section 1-2. The description of the use case with manual preload is provided in Section5.
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.
@@ -184,22 +237,22 @@ Please look at the CDS documentation for details about how to create configurati
::
-For the current use case you can also follow these steps (Do not use the SDC flow to deploy the CBA when importing a VSP, this is not going to work anymore since Guilin):
-1. You must first bootstrap CDS by using the query in the POSTMAN collection query named POST "CDS Bootstrap"
-2. You must upload the attached CBA by using the POSTMAN collection named POST "CDS Save without Validation", the CBA zip file can be attached in the POSTMAN query
-Controller Blueprint Archive (to use with CDS) : https://git.onap.org/ccsdk/cds/tree/components/model-catalog/blueprint-model/service-blueprint/vLB_CDS_Kotlin?h=guilin
-3. Create a zip file with the HEAT files located here: https://git.onap.org/demo/tree/heat/vLB_CDS?h=guilin
-4. Create the VSP & Service in the SDC onboarding and SDC Catalog + Distribute the service
- To know the right values that must be set in the SDC Service properties assignment you must open the CBA zip and look at the TOSCA-Metadata/TOSCA.meta file
- This file looks like that:
- TOSCA-Meta-File-Version: 1.0.0
- CSAR-Version: 1.0
- Created-By: Seaudi, Abdelmuhaimen <abdelmuhaimen.seaudi@orange.com>
- Entry-Definitions: Definitions/vLB_CDS.json
- Template-Tags: vLB_CDS
- Template-Name: vLB_CDS
- Template-Version: 1.0.0
- Template-Type: DEFAULT
+ For the current use case you can also follow these steps (Do not use the SDC flow to deploy the CBA when importing a VSP, this is not going to work anymore since Guilin):
+ 1. You must first bootstrap CDS by using the query in the POSTMAN collection query named POST "CDS Bootstrap"
+ 2. You must upload the attached CBA by using the POSTMAN collection named POST "CDS Save without Validation", the CBA zip file can be attached in the POSTMAN query
+ Controller Blueprint Archive (to use with CDS) : https://git.onap.org/ccsdk/cds/tree/components/model-catalog/blueprint-model/service-blueprint/vLB_CDS_Kotlin?h=guilin
+ 3. Create a zip file with the HEAT files located here: https://git.onap.org/demo/tree/heat/vLB_CDS?h=guilin
+ 4. Create the VSP & Service in the SDC onboarding and SDC Catalog + Distribute the service
+ To know the right values that must be set in the SDC Service properties assignment you must open the CBA zip and look at the TOSCA-Metadata/TOSCA.meta file
+ This file looks like that:
+ TOSCA-Meta-File-Version: 1.0.0
+ CSAR-Version: 1.0
+ Created-By: Seaudi, Abdelmuhaimen <abdelmuhaimen.seaudi@orange.com>
+ Entry-Definitions: Definitions/vLB_CDS.json
+ Template-Tags: vLB_CDS
+ Template-Name: vLB_CDS
+ Template-Version: 1.0.0
+ Template-Type: DEFAULT
- The sdnc_model_version is the Template-Version
- The sdnc_model_name is the Template-Name
@@ -211,6 +264,7 @@ Controller Blueprint Archive (to use with CDS) : https://git.onap.org/ccsdk/cds/
1-2 VNF Onboarding and Service Creation with SDC
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
+
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:
::
@@ -268,9 +322,9 @@ This VNF only supports scaling the vDNS, so users should select the vDNS module
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 Deploy Naming Policy
~~~~~~~~~~~~~~~~~~~~~~~~
+
This step is only required if CDS is used.
Note that in Guilin, the default naming policy is already deployed in policy so this step is optional
@@ -285,6 +339,7 @@ In order to instantiate the VNF using CDS features, users need to deploy the nam
1-4 Closed Loop Design with CLAMP
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
+
This step is only required if closed loop is used, for manual scaleout this section can be skipped.
Here are Json examples that can be copy pasted in each policy configuration by clicking on the button EDIT JSON, just replace the value "LOOP_test_vLB_CDS" by your loop ID:
@@ -318,7 +373,9 @@ For TCA config:
}
For Drools config:
+
::
+
{
"abatement": false,
"operations": [
@@ -360,7 +417,9 @@ For Drools config:
}
For Frequency Limiter config:
+
::
+
{
"id": "LOOP_test_vLB_CDS",
"actor": "SO",
@@ -474,6 +533,7 @@ At this point, the closed loop is deployed to Policy Engine and DCAE, and a new
1-5 Creating a VNF Template with CDT
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
+
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:
@@ -559,6 +619,7 @@ At this time, CDT doesn't allow users to provide VNF password from the GUI. To u
1-6 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:
@@ -588,6 +649,7 @@ SO has a default entry for VNF type "vLoadBalancerMS/vLoadBalancerMS 0"
1-7 Determining VNF reconfiguration parameters
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
+
The post scale out VNF reconfiguration is VNF-independent but the parameters used for VNF reconfiguration depend on the specific use case. 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. 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). For example, the "configurationParameters" section of the input request to SO during scale out with manual trigger (see Section 4) contains the resolution path to "ip-addr" and "oam-ip-addr" parameters used by the VNF.
::
@@ -1089,8 +1151,9 @@ In future releases, we plan to leverage CDS to model post scaling VNF reconfigur
PART 2 - Scale Out Use Case Instantiation
-----------------------------------------
+
Manual queries with POSTMAN
-~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
+~~~~~~~~~~~~~~~~~~~~~~~~~~~
This step is only required if CDS is used, otherwise you can use VID to instantiate the service and the VNF.
Note that the POSTMAN collection linked at the top of this page, does provide some level of automatic scripting that will automatically get values between requests and provision the following queries
@@ -1112,6 +1175,7 @@ CDS#4 - SO infra Active Request -> Used to get the status of the previous query
Manual queries without POSTMAN
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
+
GET information from SDC catalogdb
::
@@ -1373,6 +1437,7 @@ PART 3 - Post Instantiation Operations
3-1 Post Instantiation VNF configuration
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
+
CDS executes post-instantiation VNF configuration if the "skip-post-instantiation" flag in the SDC service model is set to false, which is the default behavior. Manual post-instantiation configuration is necessary if the "skip-post-instantiation" flag in the service model is set to true or if the VNF is instantiated using the preload approach, which doesn't include CDS. Regardless, this step is NOT required during scale out operations, as VNF reconfiguration will be triggered by SO and executed by APPC.
If VNF post instantiation is executed manually, in order to change the state of the vLB the users should 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:
@@ -1400,6 +1465,7 @@ 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:
::
@@ -1411,10 +1477,12 @@ Note that "vlb_onap_private_ip_0" used in the heatbridge call is the actual para
PART 4 - Triggering Scale Out Manually
--------------------------------------
+
For scale out with manual trigger, VID is not supported at this time.
Manual queries with POSTMAN
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
+
Note that the POSTMAN collection linked at the top of this page, does provide some level of automatic scripting that will automatically get values between requests and provision the following queries
You must enter in the postman config different variables:
@@ -1427,6 +1495,7 @@ CDS#7 - SO ScaleIn -> This will initiate a ScaleIn manually
Manual queries without POSTMAN
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
+
Users can run the use case by directly calling SO APIs:
::
@@ -1981,6 +2050,7 @@ Module-1 Preload
Module-2 Preload
~~~~~~~~~~~~~~~~
+
::
@@ -2297,7 +2367,8 @@ To instantiate VF modules, please refer to this wiki page: https://wiki.onap.org
PART 6 - 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
+
+ 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
@@ -2307,4 +2378,3 @@ Resolution: Change TCA configuration for the old vLB/vDNS use case
- Click "UPDATE" to upload the new TCA configuration
2) During Guilin testing, it has been noticed that there is an issue between SO and APPC for Healthcheck queries, this does not prevent the use case to proceed but limit APPC capabilities
-
diff --git a/docs/files/softwareUpgrade/serviceModelVersions.png b/docs/files/softwareUpgrade/serviceModelVersions.png
new file mode 100644
index 000000000..a918ffa00
--- /dev/null
+++ b/docs/files/softwareUpgrade/serviceModelVersions.png
Binary files differ
diff --git a/docs/files/softwareUpgrade/verifyPNF.png b/docs/files/softwareUpgrade/verifyPNF.png
new file mode 100644
index 000000000..f0aacec9f
--- /dev/null
+++ b/docs/files/softwareUpgrade/verifyPNF.png
Binary files differ
diff --git a/docs/files/softwareUpgrade/workflowList.png b/docs/files/softwareUpgrade/workflowList.png
new file mode 100644
index 000000000..339907ac5
--- /dev/null
+++ b/docs/files/softwareUpgrade/workflowList.png
Binary files differ
diff --git a/docs/integration-s3p.rst b/docs/integration-s3p.rst
index 70294f0d6..38a76f995 100644
--- a/docs/integration-s3p.rst
+++ b/docs/integration-s3p.rst
@@ -67,11 +67,11 @@ kubernetes are expected to be PASS but two tests are expected to fail:
and be valid for the 364 days after the installation. It is still not the case.
However, for the first time, no certificate was expired. Next certificates to
renew are:
- - Music (2021-02-03)
- - VID (2021-03-17)
- - Message-router-external (2021-03-25)
- - CDS-UI (2021-02-18)
- - AAI and AAI-SPARKY-BE (2021-03-17)
+ - Music (2021-02-03)
+ - VID (2021-03-17)
+ - Message-router-external (2021-03-25)
+ - CDS-UI (2021-02-18)
+ - AAI and AAI-SPARKY-BE (2021-03-17)
.. image:: files/s3p/guilin_daily_infrastructure_healthcheck.png
:align: center