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|
.. This work is licensed under a Creative Commons Attribution 4.0 International License.
.. http://creativecommons.org/licenses/by/4.0
.. Copyright 2017 AT&T Intellectual Property. All rights reserved.
**ONAP Management Requirements**
=====================================
The ONAP platform is the part of the larger Network Function
Virtualization/Software Defined Network (NFV/SDN) ecosystem that
is responsible for the efficient control, operation and management
of Virtual Network Function (VNF) capabilities and functions. It
specifies standardized abstractions and interfaces that enable
efficient interoperation of the NVF/SDN ecosystem components. It
enables product/service independent capabilities for design, creation
and runtime lifecycle management (includes all aspects of installation,
change management, assurance, and retirement) of resources in NFV/SDN
environment (see ECOMP white paper ). These capabilities are provided
using two major architectural frameworks: (1) a Design Time Framework
to design, define and program the platform (uniform onboarding), and
(2) a Runtime Execution Framework to execute the logic programmed in
the design environment (uniform delivery and runtime lifecycle
management). The platform delivers an integrated information model
based on the VNF package to express the characteristics and behavior
of these resources in the Design Time Framework. The information model
is utilized by Runtime Execution Framework to manage the runtime
lifecycle of the VNFs. The management processes are orchestrated
across various modules of ONAP to instantiate, configure, scale,
monitor, and reconfigure the VNFs using a set of standard APIs
provided by the VNF developers.
Although the guidelines and requirements specified in this document
were originally driven by the need to standardize and automate the
management of the virtualized environments (with VNFs) operated by
Service Providers, we believe that most of the requirements are equally
applicable to the operation of the physical network functions (PNFs),
those network functions provided by traditional physical network
elements (e.g. whitebox switches) or customized peripherals (e.g. a
video rendering engine for augmented reality). The primary area of
difference will be in how the network function is orchestrated into
place – VNFs can be much more dynamically created & placed by ONAP
to support varying geographic, availability and scalability needs,
whereas the PNFs have to be deployed a priori in specific locations
based on planning and engineering – their availability and scalability
will be determined by the capabilities offered by the PNFs.
**PNF** is a vendor-provided Network Function(s) implemented using a
bundled set of hardware and software while VNFs utilize cloud resources
to provide Network Functions through virtualized software modules. PNF
can be supplied by a vendor as a Black BOX (provides no knowledge of its
internal characteristics, logic, and software design/architecture) or as
a White Box (provides detailed knowledge and access of its internal
components and logic) or as a Grey Box (provides limited knowledge and
access to its internal components).
* Requirements that equally apply to both VNFs and PNFs are defined as
"The xNF MUST/SHOULD/..."
* Requirements that only apply to VNFs are defined as "The VNF MUST/SHOULD/..."
* Requirements that only apply to PNFs are defined as "The PNF MUST/SHOULD/..."
Service Design
------------------------------------
This section, Service Design, has been left intentionally blank. It
is out-of-scope for the VNF Requirements project for the Amsterdam
release and no numbered requirements are expected. Content may be
added in future updates of this document.
VNF On-boarding and package management
-----------------------------------------------------------------------------
Design Definition
^^^^^^^^^^^^^^^^^^
The ONAP Design Time Framework provides the ability to design NFV
resources including VNFs, Services, and products. The VNF provider must
provide VNF packages that include a rich set of recipes, management and
functional interfaces, policies, configuration parameters, and
infrastructure requirements that can be utilized by the ONAP Design
module to onboard and catalog these resources. Initially this
information may be provided in documents, but in the near future a
method will be developed to automate as much of the transfer of data as
possible to satisfy its long term requirements.
The current VNF Package Requirement is based on a subset of the
Requirements contained in the ETSI Document: ETSI GS NFV-MAN 001 v1.1.1
and GS NFV IFA011 V0.3.0 (2015-10) - Network Functions Virtualization
(NFV), Management and Orchestration, VNF Packaging Specification.
Resource Description
^^^^^^^^^^^^^^^^^^^^^^
* R-77707 The VNF provider **MUST** include a Manifest File that
contains a list of all the components in the VNF package.
* R-66070 The xNF Package **MUST** include xNF Identification Data to
uniquely identify the resource for a given xNF provider. The identification
data must include: an identifier for the xNF, the name of the xNF as was
given by the xNF provider, xNF description, xNF provider, and version.
* R-69565 The xNF Package **MUST** include documentation describing
xNF Management APIs. The document must include information and
tools for:
- ONAP to deploy and configure (initially and ongoing) the xNF
application(s) (e.g., NETCONF APIs). Includes description of
configurable parameters for the xNF and whether the parameters
can be configured after xNF instantiation.
- ONAP to monitor the health of the xNF (conditions that require
healing and/or scaling responses). Includes a description of:
- Parameters that can be monitored for the xNF and event records
(status, fault, flow, session, call, control plane, etc.) generated
by the xNF after instantiation.
- Runtime lifecycle events and related actions (e.g., control
responses, tests) which can be performed for the xNF.
* R-84366 The xNF Package **MUST** include documentation describing
xNF Functional APIs that are utilized to build network and
application services. This document describes the externally exposed
functional inputs and outputs for the xNF, including interface
format and protocols supported.
* R-36280 The xNF provider **MUST** provide documentation describing
xNF Functional Capabilities that are utilized to operationalize the
xNF and compose complex services.
* R-98617 The xNF provider **MUST** provide information regarding any
dependency (e.g., affinity, anti-affinity) with other xNFs and resources.
Resource Configuration
^^^^^^^^^^^^^^^^^^^^^^^
* R-89571 The xNF **MUST** support and provide artifacts for
configuration management using at least one of the following
technologies:
- Netconf/YANG
- Chef
- Ansible
Note: The requirements for Netconf/YANG, Chef, and Ansible protocols
are provided separately and must be supported only if the corresponding
protocol option is provided by the xNF providor.
Configuration Management via Netconf/YANG
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
* R-30278 The xNF provider **MUST** provide a Resource/Device YANG model
as a foundation for creating the YANG model for configuration. This will
include xNF attributes/parameters and valid values/attributes configurable
by policy.
Configuration Management via Chef
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
* R-13390 The xNF provider **MUST** provide cookbooks to be loaded
on the appropriate Chef Server.
* R-18525 The xNF provider **MUST** provide a JSON file for each
supported action for the xNF. The JSON file must contain key value
pairs with all relevant values populated with sample data that illustrates
its usage. The fields and their description are defined in Appendix A.
Note: Chef support in ONAP is not currently available and planned for 4Q 2017.
Configuration Management via Ansible
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
* R-75608 The xNF provider **MUST** provide playbooks to be loaded
on the appropriate Ansible Server.
* R-16777 The xNF provider **MUST** provide a JSON file for each
supported action for the xNF. The JSON file must contain key value
pairs with all relevant values populated with sample data that illustrates
its usage. The fields and their description are defined in Appendix B.
* R-46567 The xNF Package **MUST** include configuration scripts
for boot sequence and configuration.
* R-16065 The xNF provider **MUST** provide configurable parameters
(if unable to conform to YANG model) including xNF attributes/parameters
and valid values, dynamic attributes and cross parameter dependencies
(e.g., customer provisioning data).
Resource Control Loop
^^^^^^^^^^^^^^^^^^^^^^^
* R-22888 The xNF provider **MUST** provide documentation for the xNF
Policy Description to manage the xNF runtime lifecycle. The document
must include a description of how the policies (conditions and actions)
are implemented in the xNF.
* R-01556 The xNF Package **MUST** include documentation describing the
fault, performance, capacity events/alarms and other event records that
are made available by the xNF. The document must include:
- A unique identification string for the specific xNF, a description
of the problem that caused the error, and steps or procedures to
perform Root Cause Analysis and resolve the issue.
- All events, severity level (e.g., informational, warning, error)
and descriptions including causes/fixes if applicable for the event.
- All events (fault, measurement for xNF Scaling, Syslogs, State Change and Mobile Flow), that need to be collected at each VM, VNFC (defined in `VNF Guidelines <http://onap.readthedocs.io/en/latest/submodules/vnfrqts/guidelines.git/docs/vnf_guidelines/vnf_guidelines.html#a-glossary>`__ ) and for the overall xNF.
* R-27711 The xNF provider **MUST** provide an XML file that contains a
list of xNF error codes, descriptions of the error, and possible
causes/corrective action.
* R-01478 The xNF Package **MUST** include documentation describing all
parameters that are available to monitor the xNF after instantiation
(includes all counters, OIDs, PM data, KPIs, etc.) that must be collected
for reporting purposes. The documentation must include a list of:
- Monitoring parameters/counters exposed for virtual resource
management and xNF application management.
- KPIs and metrics that need to be collected at each VM for capacity
planning and performance management purposes.
- The monitoring parameters must include latencies, success rates,
retry rates, load and quality (e.g., DPM) for the key
transactions/functions supported by the xNF and those that must
be exercised by the xNF in order to perform its function.
- For each KPI, provide lower and upper limits.
- When relevant, provide a threshold crossing alert point for
each KPI and describe the significance of the threshold crossing.
- For each KPI, identify the suggested actions that need to be
performed when a threshold crossing alert event is recorded.
- Describe any requirements for the monitoring component of tools
for Network Cloud automation and management to provide these records
to components of the xNF.
- When applicable, provide calculators needed to convert raw data
into appropriate reporting artifacts.
* R-56815 The xNF Package **MUST** include documentation describing
supported xNF scaling capabilities and capacity limits (e.g., number
of users, bandwidth, throughput, concurrent calls).
* R-48596 The xNF Package **MUST** include documentation describing
the characteristics for the xNF reliability and high availability.
* R-74763 The xNF provider **MUST** provide an artifact per xNF that contains
all of the xNF Event Records supported. The artifact should include
reference to the specific release of the xNF Event Stream Common Event
Data Model document it is based on. (e.g.,
`VES Event Listener <https://github.com/att/evel-test-collector/tree/master/docs/att_interface_definition>`__)
Compute, Network, and Storage Requirements
^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
* R-35851 The xNF Package **MUST** include xNF topology that describes
basic network and application connectivity internal and external to the
xNF including Link type, KPIs, Bandwidth, latency, jitter, QoS (if
applicable) for each interface.
* R-97102 The VNF Package **MUST** include VM requirements via a Heat
template that provides the necessary data for:
- VM specifications for all VNF components - for hypervisor, CPU,
memory, storage.
- Network connections, interface connections, internal and external to VNF.
- High availability redundancy model.
- Scaling/growth VM specifications.
Note: Must comply with the *Heat requirements in 5.b*.
* R-26881 The xNF provider **MUST** provide the binaries and images
needed to instantiate the xNF (xNF and VNFC images).
* R-96634 The VNF provider **MUST** describe scaling capabilities
to manage scaling characteristics of the VNF.
Testing
^^^^^^^^^^
* R-43958 The xNF Package **MUST** include documentation describing
the tests that were conducted by the xNF providor and the test results.
* R-04298 The xNF provider **MUST** provide their testing scripts to
support testing.
* R-58775 The xNF provider **MUST** provide software components that
can be packaged with/near the xNF, if needed, to simulate any functions
or systems that connect to the xNF system under test. This component is
necessary only if the existing testing environment does not have the
necessary simulators.
Licensing Requirements
^^^^^^^^^^^^^^^^^^^^^^^
* R-85653 The xNF **MUST** provide metrics (e.g., number of sessions,
number of subscribers, number of seats, etc.) to ONAP for tracking
every license.
* R-44125 The xNF provider **MUST** agree to the process that can
be met by Service Provider reporting infrastructure. The Contract
shall define the reporting process and the available reporting tools.
* R-40827 The xNF provider **MUST** enumerate all of the open
source licenses their xNF(s) incorporate.
* R-97293 The xNF provider **MUST NOT** require audits of
Service Provider’s business.
* R-44569 The xNF provider **MUST NOT** require additional
infrastructure such as a xNF provider license server for xNF provider
functions and metrics.
* R-13613 The VNF **MUST** provide clear measurements for licensing
purposes to allow automated scale up/down by the management system.
* R-27511 The VNF provider **MUST** provide the ability to scale
up a VNF provider supplied product during growth and scale down a
VNF provider supplied product during decline without “real-time”
restrictions based upon VNF provider permissions.
* R-85991 The xNF provider **MUST** provide a universal license key
per xNF to be used as needed by services (i.e., not tied to a VM
instance) as the recommended solution. The xNF provider may provide
pools of Unique xNF License Keys, where there is a unique key for
each xNF instance as an alternate solution. Licensing issues should
be resolved without interrupting in-service xNFs.
* R-47849 The xNF provider **MUST** support the metadata about
licenses (and their applicable entitlements) as defined in this
document for xNF software, and any license keys required to authorize
use of the xNF software. This metadata will be used to facilitate
onboarding the xNF into the ONAP environment and automating processes
for putting the licenses into use and managing the full lifecycle of
the licenses. The details of this license model are described in
Appendix C. Note: License metadata support in ONAP is not currently
available and planned for 1Q 2018.
Configuration Management
---------------------------------------------------
ONAP interacts directly with VNFs through its Network and Application
Adapters to perform configuration activities within NFV environment.
These activities include service and resource
configuration/reconfiguration, automated scaling of resources, service
and resource removal to support runtime lifecycle management of VNFs and
services. The Adapters employ a model driven approach along with
standardized APIs provided by the VNF developers to configure resources
and manage their runtime lifecycle.
Additional details can be found in the `ONAP Application Controller (APPC) API Guide <http://onap.readthedocs.io/en/latest/submodules/appc.git/docs/APPC%20API%20Guide/APPC%20API%20Guide.html>`_, `ONAP VF-C project <http://onap.readthedocs.io/en/latest/submodules/vfc/nfvo/lcm.git/docs/index.html>`_ and the `ONAP SDNC project <http://onap.readthedocs.io/en/latest/submodules/sdnc/northbound.git/docs/index.html>`_.
NETCONF Standards and Capabilities
^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
ONAP Controllers and their Adapters utilize device YANG model and
NETCONF APIs to make the required changes in the VNF state and
configuration. The VNF providers must provide the Device YANG model and
NETCONF server supporting NETCONF APIs to comply with target ONAP and
industry standards.
VNF Configuration via NETCONF Requirements
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
Configuration Management
+++++++++++++++++++++++++++
* R-88026 The xNF **MUST** include a NETCONF server enabling
runtime configuration and lifecycle management capabilities.
* R-95950 The xNF **MUST** provide a NETCONF interface fully defined
by supplied YANG models for the embedded NETCONF server.
NETCONF Server Requirements
++++++++++++++++++++++++++++++
* R-73468 The xNF **MUST** allow the NETCONF server connection
parameters to be configurable during virtual machine instantiation
through Heat templates where SSH keys, usernames, passwords, SSH
service and SSH port numbers are Heat template parameters.
* R-90007 The xNF **MUST** implement the protocol operation:
**close-session()**- Gracefully close the current session.
* R-70496 The xNF **MUST** implement the protocol operation:
**commit(confirmed, confirm-timeout)** - Commit candidate
configuration datastore to the running configuration.
* R-18733 The xNF **MUST** implement the protocol operation:
**discard-changes()** - Revert the candidate configuration
datastore to the running configuration.
* R-44281 The xNF **MUST** implement the protocol operation:
**edit-config(target, default-operation, test-option, error-option,
config)** - Edit the target configuration datastore by merging,
replacing, creating, or deleting new config elements.
* R-60106 The xNF **MUST** implement the protocol operation:
**get(filter)** - Retrieve (a filtered subset of) the running
configuration and device state information. This should include
the list of xNF supported schemas.
* R-29488 The xNF **MUST** implement the protocol operation:
**get-config(source, filter)** - Retrieve a (filtered subset of
a) configuration from the configuration datastore source.
* R-11235 The xNF **MUST** implement the protocol operation:
**kill-session(session)** - Force the termination of **session**.
* R-02597 The xNF **MUST** implement the protocol operation:
**lock(target)** - Lock the configuration datastore target.
* R-96554 The xNF **MUST** implement the protocol operation:
**unlock(target)** - Unlock the configuration datastore target.
* R-29324 The xNF **SHOULD** implement the protocol operation:
**copy-config(target, source) -** Copy the content of the
configuration datastore source to the configuration datastore target.
* R-88031 The xNF **SHOULD** implement the protocol operation:
**delete-config(target) -** Delete the named configuration
datastore target.
* R-97529 The xNF **SHOULD** implement the protocol operation:
**get-schema(identifier, version, format) -** Retrieve the YANG schema.
* R-62468 The xNF **MUST** allow all configuration data to be
edited through a NETCONF <edit-config> operation. Proprietary
NETCONF RPCs that make configuration changes are not sufficient.
* R-01382 The xNF **MUST** allow the entire configuration of the
xNF to be retrieved via NETCONF's <get-config> and <edit-config>,
independently of whether it was configured via NETCONF or other
mechanisms.
* R-28756 The xNF **MUST** support **:partial-lock** and
**:partial-unlock** capabilities, defined in RFC 5717. This
allows multiple independent clients to each write to a different
part of the <running> configuration at the same time.
* R-83873 The xNF **MUST** support **:rollback-on-error** value for
the <error-option> parameter to the <edit-config> operation. If any
error occurs during the requested edit operation, then the target
database (usually the running configuration) will be left unaffected.
This provides an 'all-or-nothing' edit mode for a single <edit-config>
request.
* R-68990 The xNF **MUST** support the **:startup** capability. It
will allow the running configuration to be copied to this special
database. It can also be locked and unlocked.
* R-68200 The xNF **MUST** support the **:url** value to specify
protocol operation source and target parameters. The capability URI
for this feature will indicate which schemes (e.g., file, https, sftp)
that the server supports within a particular URL value. The 'file'
scheme allows for editable local configuration databases. The other
schemes allow for remote storage of configuration databases.
* R-20353 The xNF **MUST** implement at least one of the capabilities
**:candidate** or **:writable-running**. If both **:candidate** and
**:writable-running** are provided then two locks should be supported.
* R-11499 The xNF **MUST** fully support the XPath 1.0 specification
for filtered retrieval of configuration and other database contents.
The 'type' attribute within the <filter> parameter for <get> and
<get-config> operations may be set to 'xpath'. The 'select' attribute
(which contains the XPath expression) will also be supported by the
server. A server may support partial XPath retrieval filtering, but
it cannot advertise the **:xpath** capability unless the entire XPath
1.0 specification is supported.
* R-83790 The xNF **MUST** implement the **:validate** capability
* R-49145 The xNF **MUST** implement **:confirmed-commit** If
**:candidate** is supported.
* R-58358 The xNF **MUST** implement the **:with-defaults** capability
[RFC6243].
* R-59610 The xNF **MUST** implement the data model discovery and
download as defined in [RFC6022].
* R-87662 The xNF **SHOULD** implement the NETCONF Event Notifications
[RFC5277].
* R-93443 The xNF **MUST** define all data models in YANG [RFC6020],
and the mapping to NETCONF shall follow the rules defined in this RFC.
* R-26115 The xNF **MUST** follow the data model upgrade rules defined
in [RFC6020] section 10. All deviations from section 10 rules shall
be handled by a built-in automatic upgrade mechanism.
* R-10716 The xNF **MUST** support parallel and simultaneous
configuration of separate objects within itself.
* R-29495 The xNF **MUST** support locking if a common object is
being manipulated by two simultaneous NETCONF configuration operations
on the same xNF within the context of the same writable running data
store (e.g., if an interface parameter is being configured then it
should be locked out for configuration by a simultaneous configuration
operation on that same interface parameter).
* R-53015 The xNF **MUST** apply locking based on the sequence of
NETCONF operations, with the first configuration operation locking
out all others until completed.
* R-02616 The xNF **MUST** permit locking at the finest granularity
if a xNF needs to lock an object for configuration to avoid blocking
simultaneous configuration operations on unrelated objects (e.g., BGP
configuration should not be locked out if an interface is being
configured or entire Interface configuration should not be locked out
if a non-overlapping parameter on the interface is being configured).
* R-41829 The xNF **MUST** be able to specify the granularity of the
lock via a restricted or full XPath expression.
* R-66793 The xNF **MUST** guarantee the xNF configuration integrity
for all simultaneous configuration operations (e.g., if a change is
attempted to the BUM filter rate from multiple interfaces on the same
EVC, then they need to be sequenced in the xNF without locking either
configuration method out).
* R-54190 The xNF **MUST** release locks to prevent permanent lock-outs
when/if a session applying the lock is terminated (e.g., SSH session
is terminated).
* R-03465 The xNF **MUST** release locks to prevent permanent lock-outs
when the corresponding <partial-unlock> operation succeeds.
* R-63935 The xNF **MUST** release locks to prevent permanent lock-outs
when a user configured timer has expired forcing the NETCONF SSH Session
termination (i.e., product must expose a configuration knob for a user
setting of a lock expiration timer)
* R-10173 The xNF **MUST** allow another NETCONF session to be able to
initiate the release of the lock by killing the session owning the lock,
using the <kill-session> operation to guard against hung NETCONF sessions.
* R-88899 The xNF **MUST** support simultaneous <commit> operations
within the context of this locking requirements framework.
* R-07545 The xNF **MUST** support all operations, administration and
management (OAM) functions available from the supplier for xNFs using
the supplied YANG code and associated NETCONF servers.
* R-60656 The xNF **MUST** support sub tree filtering.
* R-80898 The xNF **MUST** support heartbeat via a <get> with null filter.
* R-06617 The xNF **MUST** support get-schema (ietf-netconf-monitoring)
to pull YANG model over session.
* R-25238 The xNF PACKAGE **MUST** validated YANG code using the open
source pyang [1]_ program using the following commands:
.. code-block:: python
$ pyang --verbose --strict <YANG-file-name(s)>
$ echo $!
* R-63953 The xNF **MUST** have the echo command return a zero value
otherwise the validation has failed
* R-26508 The xNF **MUST** support NETCONF server that can be
mounted on OpenDaylight (client) and perform the following operations:
- Modify, update, change, rollback configurations using each
configuration data element.
- Query each state (non-configuration) data element.
- Execute each YANG RPC.
- Receive data through each notification statement.
The following requirements provides the Yang models that suppliers must
conform, and those where applicable, that suppliers need to use.
* R-28545 The xNF **MUST** conform its YANG model to RFC 6060,
“YANG - A Data Modeling Language for the Network Configuration
Protocol (NETCONF)”
* R-29967 The xNF **MUST** conform its YANG model to RFC 6022,
“YANG module for NETCONF monitoring”.
* R-22700 The xNF **MUST** conform its YANG model to RFC 6470,
“NETCONF Base Notifications”.
* R-10353 The xNF **MUST** conform its YANG model to RFC 6244,
“An Architecture for Network Management Using NETCONF and YANG”.
* R-53317 The xNF **MUST** conform its YANG model to RFC 6087,
“Guidelines for Authors and Reviewers of YANG Data Model Documents”.
* R-33955 The xNF **SHOULD** conform its YANG model to RFC 6991,
“Common YANG Data Types”.
* R-22946 The xNF **SHOULD** conform its YANG model to RFC 6536,
“NETCONF Access Control Model”.
* R-10129 The xNF **SHOULD** conform its YANG model to RFC 7223,
“A YANG Data Model for Interface Management”.
* R-12271 The xNF **SHOULD** conform its YANG model to RFC 7223,
“IANA Interface Type YANG Module”.
* R-49036 The xNF **SHOULD** conform its YANG model to RFC 7277,
“A YANG Data Model for IP Management”.
* R-87564 The xNF **SHOULD** conform its YANG model to RFC 7317,
“A YANG Data Model for System Management”.
* R-24269 The xNF **SHOULD** conform its YANG model to RFC 7407,
“A YANG Data Model for SNMP Configuration”.
The NETCONF server interface shall fully conform to the following
NETCONF RFCs.
* R-33946 The xNF **MUST** conform to the NETCONF RFC 4741,
“NETCONF Configuration Protocol”.
* R-04158 The xNF **MUST** conform to the NETCONF RFC 4742,
“Using the NETCONF Configuration Protocol over Secure Shell (SSH)”.
* R-13800 The xNF **MUST** conform to the NETCONF RFC 5277,
“NETCONF Event Notification”.
* R-01334 The xNF **MUST** conform to the NETCONF RFC 5717,
“Partial Lock Remote Procedure Call”.
* R-08134 The xNF **MUST** conform to the NETCONF RFC 6241,
“NETCONF Configuration Protocol”.
* R-78282 The xNF **MUST** conform to the NETCONF RFC 6242,
“Using the Network Configuration Protocol over Secure Shell”.
VNF REST APIs
^^^^^^^^^^^^^^^
Healthcheck is a command for which no NETCONF support exists.
Therefore, this must be supported using a RESTful interface
(defined in this section) or with a Chef cookbook/Ansible playbook
(defined in sections `Chef Standards and Capabilities`_ and
`Ansible Standards and Capabilities`_).
HealthCheck Definition: The VNF level HealthCheck is a check over
the entire scope of the VNF. The VNF must be 100% healthy, ready
to take requests and provide services, with all VNF required
capabilities ready to provide services and with all active and
standby resources fully ready with no open MINOR, MAJOR or CRITICAL
alarms. NOTE: A switch may need to be turned on, but the VNF should
be ready to take service requests or be already processing service
requests successfully.
The VNF must provide a REST formatted GET RPCs to support Healthcheck
queries via the GET method over HTTP(s).
The port number, url, and other authentication information is provided
by the VNF provider.
REST APIs
~~~~~~~~~
* R-31809 The xNF **MUST** support the HealthCheck RPC. The HealthCheck
RPC executes a xNF Provider-defined xNF Healthcheck over the scope of
the entire xNF (e.g., if there are multiple VNFCs, then run a health check,
as appropriate, for all VNFCs). It returns a 200 OK if the test completes.
A JSON object is returned indicating state (healthy, unhealthy), scope
identifier, time-stamp and one or more blocks containing info and fault
information. If the xNF is unable to run the HealthCheck, return a
standard http error code and message.
Examples:
.. code-block:: java
200
{
"identifier": "scope represented",
"state": "healthy",
"time": "01-01-1000:0000"
}
200
{
"identifier": "scope represented",
"state": "unhealthy",
{[
"info": "System threshold exceeded details",
"fault":
{
"cpuOverall": 0.80,
"cpuThreshold": 0.45
}
]},
"time": "01-01-1000:0000"
}
Chef Standards and Capabilities
^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
ONAP will support configuration of VNFs via Chef subject to the
requirements and guidelines defined in this section.
The Chef configuration management mechanism follows a client-server
model. It requires the presence of a Chef-Client on the VNF that will be
directly managed by a Chef Server. The Chef-client will register with
the appropriate Chef Server and are managed via ‘cookbooks’ and
configuration attributes loaded on the Chef Server which contain all
necessary information to execute the appropriate actions on the VNF via
the Chef-client.
ONAP will utilize the open source Chef Server, invoke the documented
Chef REST APIs to manage the VNF and requires the use of open source
Chef-Client and Push Jobs Client on the VNF
(https://downloads.chef.io/).
VNF Configuration via Chef Requirements
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
Chef Client Requirements
+++++++++++++++++++++++++
* R-79224 The xNF **MUST** have the chef-client be preloaded with
validator keys and configuration to register with the designated
Chef Server as part of the installation process.
* R-72184 The xNF **MUST** have routable FQDNs for all the endpoints
(VMs) of a xNF that contain chef-clients which are used to register
with the Chef Server. As part of invoking xNF actions, ONAP will
trigger push jobs against FQDNs of endpoints for a xNF, if required.
* R-47068 The xNF **MAY** expose a single endpoint that is
responsible for all functionality.
* R-67114 The xNF **MUST** be installed with:
- Chef-Client >= 12.0
- Chef push jobs client >= 2.0
Chef Roles/Requirements
++++++++++++++++++++++++++
* R-27310 The xNF Package **MUST** include all relevant Chef artifacts
(roles/cookbooks/recipes) required to execute xNF actions requested by
ONAP for loading on appropriate Chef Server.
* R-26567 The xNF Package **MUST** include a run list of
roles/cookbooks/recipes, for each supported xNF action, that will
perform the desired xNF action in its entirety as specified by ONAP
(see Section 7.c, ONAP Controller APIs and Behavior, for list of xNF
actions and requirements), when triggered by a chef-client run list
in JSON file.
* R-98911 The xNF **MUST NOT** use any instance specific parameters
for the xNF in roles/cookbooks/recipes invoked for a xNF action.
* R-37929 The xNF **MUST** accept all necessary instance specific
data from the environment or node object attributes for the xNF
in roles/cookbooks/recipes invoked for a xNF action.
* R-62170 The xNF **MUST** over-ride any default values for
configurable parameters that can be set by ONAP in the roles,
cookbooks and recipes.
* R-78116 The xNF **MUST** update status on the Chef Server
appropriately (e.g., via a fail or raise an exception) if the
chef-client run encounters any critical errors/failures when
executing a xNF action.
* R-44013 The xNF **MUST** populate an attribute, defined as node
[‘PushJobOutput’] with the desired output on all nodes in the push job
that execute chef-client run if the xNF action requires the output of a
chef-client run be made available (e.g., get running configuration).
* R-30654 The xNF Package **MUST** have appropriate cookbooks that are
designed to automatically ‘rollback’ to the original state in case of
any errors for actions that change state of the xNF (e.g., configure).
* R-65755 The xNF **SHOULD** support callback URLs to return information
to ONAP upon completion of the chef-client run for any chef-client run
associated with a xNF action.
- As part of the push job, ONAP will provide two parameters in the
environment of the push job JSON object:
- ‘RequestId’ a unique Id to be used to identify the request,
- ‘CallbackUrl’, the URL to post response back.
- If the CallbackUrl field is empty or missing in the push job,then
the chef-client run need not post the results back via callback.
* R-15885 The xNF **MUST** Upon completion of the chef-client run,
POST back on the callback URL, a JSON object as described in Table
A2 if the chef-client run list includes a cookbook/recipe that is
callback capable. Failure to POST on the Callback Url should not be
considered a critical error. That is, if the chef-client successfully
completes the xNF action, it should reflect this status on the Chef
Server regardless of whether the Callback succeeded or not.
ONAP Chef API Usage
~~~~~~~~~~~~~~~~~~~
This section outlines the workflow that ONAP invokes when it receives an
action request against a Chef managed VNF.
1. When ONAP receives a request for an action for a Chef Managed VNF, it
retrieves the corresponding template (based on **action** and
**VNF)** from its database and sets necessary values in the
“Environment”, “Node” and “NodeList” keys (if present) from either
the payload of the received action or internal data.
2. If “Environment” key is present in the updated template, it posts the
corresponding JSON dictionary to the appropriate Environment object
REST endpoint on the Chef Server thus updating the Environment
attributes on the Chef Server.
3. Next, it creates a Node Object from the “Node” JSON dictionary for
all elements listed in the NodeList (using the FQDN to construct the
endpoint) by replicating it [2]_. As part of this process, it will
set the name field in each Node Object to the corresponding FQDN.
These node objects are then posted on the Chef Server to
corresponding Node Object REST endpoints to update the corresponding
node attributes.
4. If PushJobFlag is set to “True” in the template, ONAP requests a push
job against all the nodes in the NodeList to trigger
chef-client\ **.** It will not invoke any other command via the push
job. ONAP will include a callback URL in the push job request and a
unique Request Id. An example push job posted by ONAP is listed
below:
.. code-block:: java
{
"command": "chef-client",
"run\_timeout": 300,
"nodes”: [“node1.vnf\_a.onap.com”, “node2.vnf\_a.onap.com”],
"env": {
“RequestId”:”8279-abcd-aksdj-19231”,
“CallbackUrl”:”<callback>”
},
}
5. If CallbackCapable field in the template is not present or set to
“False” ONAP will poll the Chef Server to check completion status of
the push job.
6. If “GetOutputFlag” is set to “True” in the template and
CallbackCapable is not set to “True”, ONAP will retrieve any output
from each node where the push job has finished by accessing the Node
Object attribute node[‘PushJobOutput’].
Ansible Standards and Capabilities
^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
ONAP will support configuration of VNFs via Ansible subject to the
requirements and guidelines defined in this section.
Ansible allows agentless management of VNFs/VMs/VNFCs via execution
of ‘playbooks’ over ssh. The ‘playbooks’ are a structured set of
tasks which contain all the necessary data and execution capabilities
to take the necessary action on one or more target VMs (and/or VNFCs)
of the VNF. ONAP will utilize the framework of an Ansible Server that
will host and run playbooks to manage VNFs that support Ansible.
VNF Configuration via Ansible Requirements
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
Ansible Client Requirements
+++++++++++++++++++++++++++++
* R-32217 The xNF **MUST** have routable FQDNs that are reachable via
the Ansible Server for the endpoints (VMs) of a xNF on which playbooks
will be executed. ONAP will initiate requests to the Ansible Server
for invocation of playbooks against these end points [3]_.
* R-54373 The xNF **MUST** have Python >= 2.7 on the endpoint VM(s)
of a xNF on which an Ansible playbook will be executed.
* R-35401 The xNF **MUST** support SSH and allow SSH access to the
Ansible server for the endpoint VM(s) and comply with the Network
Cloud Service Provider guidelines for authentication and access.
* R-82018 The VNF **SHOULD** load the SSH key onto VNF VM(s) as part
of instantiation. This will allow the Ansible Server to authenticate
to perform post-instantiation configuration without manual intervention
and without requiring specific VNF login IDs and passwords.
CAUTION: For VNFs configured using Ansible, to eliminate the need
for manual steps, post-instantiation and pre-configuration, to upload
of SSH keys, SSH keys loaded during (heat) instantiation shall be
preserved and not removed by (heat) embedded scripts.
* R-92866 The VNF **MUST** include as part of post-instantiation
configuration done by Ansible Playbooks the removal/update of SSH
keys loaded through instantiation to support Ansible. This may
include download and install of new SSH keys.
* R-91745 The VNF **MUST** update the Ansible Server and other entities
storing and using the SSH key for authentication when the SSH key used
by Ansible is regenerated/updated.
Ansible Playbook Requirements
+++++++++++++++++++++++++++++++
An Ansible playbook is a collection of tasks that is executed on the
Ansible server (local host) and/or the target VM (s) in order to
complete the desired action.
* R-40293 The xNF **MUST** make available playbooks that conform
to the ONAP requirement.
* R-49396 The xNF **MUST** support each xNF action by invocation of
**one** playbook [4]_. The playbook will be responsible for executing
all necessary tasks (as well as calling other playbooks) to complete
the request.
* R-33280 The xNF **MUST NOT** use any instance specific parameters
in a playbook.
* R-48698 The xNF **MUST** utilize information from key value pairs
that will be provided by the Ansible Server as extra-vars during
invocation to execute the desired xNF action. If the playbook requires
files, they must also be supplied using the methodology detailed in
the Ansible Server API.
The Ansible Server will determine if a playbook invoked to execute a
xNF action finished successfully or not using the “PLAY_RECAP” summary
in Ansible log. The playbook will be considered to successfully finish
only if the “PLAY RECAP” section at the end of playbook execution output
has no unreachable hosts and no failed tasks. Otherwise, the playbook
will be considered to have failed.
* R-43253 The xNF **MUST** use playbooks designed to allow Ansible
Server to infer failure or success based on the “PLAY_RECAP” capability.
* R-50252 The xNF **MUST** write to a specific set of text files that
will be retrieved and made available by the Ansible Server if, as part
of a xNF action (e.g., audit), a playbook is required to return any
xNF information. The text files must be written in the same directory as
the one from which the playbook is being executed. A text file must be
created for each host the playbook run targets/affects, with the name
‘<hostname>_results.txt’ into which any desired output from each
respective VM/xNF must be written.
* R-51442 The xNF **SHOULD** use playbooks that are designed to
automatically ‘rollback’ to the original state in case of any errors
for actions that change state of the xNF (e.g., configure).
NOTE: In case rollback at the playbook level is not supported or possible,
the xNF provider shall provide alternative locking mechanism (e.g., for a
small xNF the rollback mechanism may rely on workflow to terminate and
re-instantiate VNF VMs and then re-run playbook(s)). Backing up updated
files also recommended to support rollback when soft rollback is feasible.
* R-58301 The VNF **SHOULD NOT** use playbooks that make requests to
Cloud resources e.g. Openstack (nova, neutron, glance, heat, etc.);
therefore, there is no use for Cloud specific variables like Openstack
UUIDs in Ansible Playbooks.
Rationale: Flows that require interactions with Cloud services
e.g. Openstack shall rely on workflows run by an Orchestrator or
other capability (such as a control loop or Operations GUI) outside
Ansible Server which can be executed by a Controller such as APPC.
There are policies, as part of Control Loop models, that send remediation
action requests to APPC; these are triggered as a response to an event
or correlated events published to Event Bus.
* R-02651 The VNF **SHOULD** use the Ansible backup feature to save a
copy of configuration files before implementing changes to support
operations such as backing out of software upgrades, configuration
changes or other work as this will help backing out of configuration
changes when needed.
* R-43353 The VNF **MUST** return control from Ansible Playbooks only
after tasks are fully complete, signaling that the playbook completed
all tasks. When starting services, return control only after all services
are up. This is critical for workflows where the next steps are dependent
on prior tasks being fully completed.
Detailed examples:
StopApplication Playbook – StopApplication Playbook shall return control
and a completion status only after VNF application is fully stopped, all
processes/services stopped.
StartApplication Playbook – StartApplication Playbook shall return control
and a completion status only after all VNF application services are fully up,
all processes/services started and ready to provide services. NOTE: Start
Playbook should not be declared complete/done after starting one or several
processes that start the other processes.
HealthCheck Playbook:
SUCCESS – HealthCheck success shall be returned (return code 0) by a
Playbook or Cookbook only when VNF is 100% healthy, ready to take requests
and provide services, with all VNF required capabilities ready to provide
services and with all active and standby resources fully ready with no
open MINOR, MAJOR or CRITICAL alarms.
NOTE: In some cases, a switch may need to be turned on, but a VNF
reported as healthy, should be ready to take service requests or be
already processing service requests successfully.
A successful execution of a health-check playbook shall also create one
file per VNF VM, named using IP address or VM name followed by
“_results.txt (<hostname>_results.txt) to indicate health-check was
executed and completed successfully, example: 1xx.2yy.zzz.105_results.txt,
with the following contents:
"status”:"healthy”
Example:
$ cat 1xx.2yy.zzz.105_results.txt
"status”:"healthy”
FAILURE – A health check playbook shall return a non-zero return code in
case VNF is not 100% healthy because one or more VNF application processes
are stopped or not ready to take service requests or because critical or
non-critical resources are not ready or because there are open MINOR, MAJOR
or CRITICAL traps/alarms or because there are issues with the VNF that
need attention even if they do not impact services provided by the VNF.
A failed health-check playbook shall also create one file per VNF VM,
named using Playbook Name plus IP address or VM name, followed by
“_results.txt to indicate health-check was executed and found issues
in the health of the VNF. This is to differentiate from failure to
run health-check playbook or tasks to verify the health of the VNF,
example: 1xx.2yy.zzz.105_results.txt, with the following contents:
"status”:"unhealthy”
Example:
$ cat 1xx.2yy.zzz.105_results.txt
"status”:"unhealthy”
See `VNF REST APIs`_ for additional details on HealthCheck.
ONAP Controller / Ansible API Usage
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
This section outlines the workflow that ONAP Controller invokes when
it receives an action request against an Ansible managed VNF.
#. When ONAP Controller receives a request for an action for an
AnsibleManaged VNF, it retrieves the corresponding template (based
on **action** and **VNF**) from its database and sets necessary
values (such as an Id, NodeList, and EnvParameters) from either
information in the request or data obtained from other sources.
This is referred to as the payload that is sent as a JSON object
to the Ansible server.
#. The ONAP Controller sends a request to the Ansible server to
execute the action.
#. The ONAP Controller polls the Ansible Server for result (success
or failure). The ONAP Controllers has a timeout value which is
contained in the template. If the result is not available when the
timeout is reached, the ONAP Controller stops polling and returns a
timeout error to the requester. The Ansible Server continues to
process the request.
ONAP Controller APIs and Behavior
^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
ONAP Controllers such as APPC expose a northbound API to clients
which offer a set of commands. The following commands are expected
to be supported on all VNF’s if applicable, either directly (via the
Netconf interface) or indirectly (via a Chef or Ansible server).
There are additional commands offered to northbound clients that are
not listed here, as these commands either act internally on the Controller
itself or depend upon network cloud components for implementation
(thus, these actions do not put any special requirement on the VNF provider).
The following table summarizes how the VNF must act in response to
commands from ONAP.
Table 8. ONAP Controller APIs and NETCONF Commands
+------------------+---------------------------------+------------------------+
| **Action** | **Description** | **NETCONF Commands** |
+==================+=================================+========================+
| Action | Queries ONAP Controller for the | There is currently no |
| Status | current state of a previously | way to check the |
| | submitted runtime LCM (Lifecycle| request status in |
| | Management) action. | NETCONF so action |
| | | status is managed |
| | | internally by the ONAP |
| | | controller. |
+------------------+---------------------------------+------------------------+
| Audit, Sync | Compare active (uploaded) | The <get-config> |
| | configuration against the | operation is used to |
| | current configuration in the | retrieve the running |
| | ONAP controller. Audit returns | configuration from the |
| | failure if different. Sync | VNF. |
| | considers the active (uploaded) | |
| | configuration as the current | |
| | configuration. | |
+------------------+---------------------------------+------------------------+
| Lock, | Returns true when the given VNF | There is currently no |
| Unlock, | has been locked. | way to query lock state|
| CheckLock | | in NETCONF so VNF |
| | | locking and unlocking |
| | | is managed internally |
| | | by the ONAP controller.|
+------------------+---------------------------------+------------------------+
| Configure, | Configure applies a | The <edit-config> |
| ConfigModify | post-instantiation configuration| operation loads all or |
| | the target VNF or VNFC. | part of a specified |
| | ConfigModify updates only a | configuration data set |
| | subset of the total | to the specified target|
| | configuration parameters of a | database. If there is |
| | VNF. | no <candidate/> |
| | | database, then the |
| | | target is the |
| | | <running/> database. A |
| | | <commit> follows. |
+------------------+---------------------------------+------------------------+
| Health | Executes a VNF health check and | This command has no |
| Check | returns the result. A health | existing NETCONF RPC |
| | check is VNF-specific. | action. It must be |
| | | supported either by |
| | | REST (see |
| | | `VNF REST APIs`_) or |
| | | using Ansible or Chef. |
+------------------+---------------------------------+------------------------+
| StartApplication,| ONAP requests application to be | These commands have no |
| StopApplication | started or stopped on the VNF. | specific NETCONF RPC |
| | These actions do not need to be | action. |
| | supported if (1) the application| |
| | starts automatically after | |
| | Configure or if the VM’s are | |
| | started and (2) the application | |
| | gracefully shuts down if the | |
| | VM’s are stopped. | |
| | | |
| | | If applicable, these |
| | | commands must be |
| | | supported using Ansible|
| | | or Chef (see Table 9 |
| | | below). |
+------------------+---------------------------------+------------------------+
| ConfigBackup, | ONAP requests the VNF | These commands have no |
| ConfigRestore | configuration parameters to be | specific NETCONF RPC |
| | backed up or restored (replacing| action. |
| | existing configuration | |
| | parameters on the VNF). | |
| | | |
| | | They can be supported |
| | | using Ansible or Chef |
| | | (see Table 9 below). |
+------------------+---------------------------------+------------------------+
Table 9 lists the required Chef and Ansible support for commands from
ONAP.
Table 9. ONAP Controller APIs and Chef/Ansible Support
+------------------+------------------------------+---------------------------+
| **Action** | **Chef** | **Ansible** |
+==================+==============================+===========================+
| Action | Not needed. ActionStatus is | Not needed. ActionStatus |
| Status | managed internally by the | is managed internally by |
| | ONAP controller. | the ONAP controller. |
+------------------+------------------------------+---------------------------+
| Audit, Sync | VNF provider must provide any| VNF provider must provide |
| | necessary roles, cookbooks, | an Ansible playbook to |
| | recipes to retrieve the | retrieve the running |
| | running configuration from a | configuration from a VNF |
| | VNF and place it in the | and place the output on |
| | respective Node Objects | the Ansible server in a |
| | ‘PushJobOutput’ attribute of | manner aligned with |
| | all nodes in NodeList when | playbook requirements |
| | triggered by a chef-client | listed in this document. |
| | run. | |
| | | |
| | The JSON file for this VNF | The PlaybookName must be |
| | action is required to set | provided in the JSON file.|
| | “PushJobFlag” to “True” and | |
| | “GetOutputFlag” to “True”. | |
| | The “Node” JSON dictionary | |
| | must have the run list | |
| | populated with the necessary | |
| | sequence of roles, cookbooks,| |
| | recipes. | |
| | | |
| | The Environment and Node | NodeList must list FQDNs |
| | values should contain all | of an example VNF on which|
| | appropriate configuration | to execute playbook. |
| | attributes. | |
| | | |
| | NodeList must list sample | |
| | FQDNs that are required to | |
| | conduct a chef-client run for| |
| | this VNF Action. | |
+------------------+------------------------------+---------------------------+
| Lock, | Not needed. VNF locking and | Not needed. VNF locking |
| Unlock, | unlocking is managed | and unlocking is managed |
| CheckLock | internally by the ONAP | internally by the ONAP |
| | controller. | controller. |
+------------------+------------------------------+---------------------------+
| Configure, | VNF provider must provide any| VNF provider must provide |
| ConfigModify | necessary roles, cookbooks, | an Ansible playbook that |
| | recipes to apply | can configure the VNF with|
| | configuration attributes to | parameters supplied by the|
| | the VNF when triggered by a | Ansible Server. |
| | chef-client run. All | |
| | configurable attributes must | |
| | be obtained from the | |
| | Environment and Node objects | |
| | on the Chef Server. | |
| | | |
| | The JSON file for this VNF | The PlaybookName must be |
| | action should include all | provided in the JSON file.|
| | configurable attributes in | |
| | the Environment and/or Node | |
| | JSON dictionary. | |
| | | |
| | The “PushJobFlag” must be set| The “EnvParameters” and/or|
| | to “True”. | “FileParameters” field |
| | | values should be provided |
| | | and contain all |
| | | configurable parameters |
| | | for the VNF. |
| | | |
| | The “Node” JSON dictionary | NodeList must list FQDNs |
| | must have the run list | of an example VNF on which|
| | populated with necessary | to execute playbook. |
| | sequence of roles, cookbooks,| |
| | recipes. This action is not | |
| | expected to return an output.| |
| | | |
| | “GetOutputFlag” must be set | |
| | to “False”. | |
| | | |
| | NodeList must list sample | |
| | FQDNs that are required to | |
| | conduct a chef-client run for| |
| | this VNF Action. | |
+------------------+------------------------------+---------------------------+
| Health | The VNF level HealthCheck run| The VNF level HealthCheck |
| Check | a check over the entire scope| run a check over the |
| | of the VNF (for more details,| entire scope of the VNF |
| | see `VNF REST APIs`_). It | (for more details, see |
| | can be supported either via a| `VNF REST APIs`_). It can|
| | REST interface or with Chef | be supported either via a |
| | roles, cookbooks, and | REST interface or with an |
| | recipes. | Ansible playbook. |
+------------------+------------------------------+---------------------------+
| StartApplication,| VNF provider must provide | VNF provider must provide |
| | roles, cookbooks, recipes to | an Ansible playbook to |
| | start an application on the | start the application on |
| | VNF when triggered by a | the VNF. If application |
| | chef-client run. If | does not start, the |
| | application does not start, | playbook must indicate |
| | the run must fail or raise an| failure. If application is|
| | exception. If application is | already started, or starts|
| | already started, or starts | successfully, the playbook|
| | successfully, the run must | must finish successfully. |
| | finish successfully. | |
| | | |
| StopApplication | For StopApplication, the | For StopApplication, the |
| | application must be stopped | application must be |
| | gracefully (no loss of | stopped gracefully (no |
| | traffic). | loss of traffic). |
+------------------+------------------------------+---------------------------+
| ConfigBackup, | VNF provider must provide | VNF provider must provide |
| | roles, cookbooks, recipes to | an Ansible playbook to |
| | backup or restore the | backup or restore the |
| | configuration parameters on | configuration parameters |
| | the VNF when triggered by an | on the VNF when triggered |
| | ECOMP request. | by an ECOMP request. |
| | | |
| | When the ConfigBackup command| When the ConfigBackup |
| | is executed, the current VNF | command is executed, the |
| | configuration parameters are | current VNF configuration |
| | copied over to the Ansible or| parameters are copied over|
| | Chef server (if there is an | to the Ansible or Chef |
| | existing set of backed up | server (if there is an |
| | parameters, they are | existing set of backed up |
| | overwritten). When the | parameters, they are |
| | ConfigRestore command is | overwritten). When the |
| | executed, the VNF | ConfigRestore command is |
| | configuration parameters | executed, the VNF |
| ConfigRestore | which are backed up on the | configuration parameters |
| | Ansible or Chef server are | which are backed up on the|
| | applied to the VNF (replacing| Ansible or Chef server are|
| | existing parameters). It can | applied to the VNF |
| | be assumed that the VNF is | (replacing existing |
| | not in service when a | parameters). It can be |
| | ConfigRestore command is | assumed that the VNF is |
| | executed. | not in service when a |
| | | ConfigRestore command is |
| | | executed. |
| | | |
| | If either command fails, the | If either command fails, |
| | run must fail or raise an | the run must fail or raise|
| | exception. | an exception. |
+------------------+------------------------------+---------------------------+
For information purposes, the following ONAP controller functions are
planned in the future:
Table 10. Planned ONAP Controller Functions
+------------------+-------------------------------------------------------+
| Action | Description |
+==================+=======================================================+
| UpgradeSoftware | Upgrades the target VNF to a new software version. |
+------------------+-------------------------------------------------------+
| QuiesceTraffic, | Quiesces traffic (stops traffic gracefully) and resume|
| ResumeTraffic | traffic on the VNF. These commands do not stop the |
| | application processes (which is done using |
| | StopApplication). |
+------------------+-------------------------------------------------------+
Monitoring & Management
--------------------------------------------------
This section addresses data collection and event processing
functionality that is directly dependent on the interfaces
provided by the VNFs’ APIs. These can be in the form of asynchronous
interfaces for event, fault notifications, and autonomous data streams.
They can also be synchronous interfaces for on-demand requests to
retrieve various performance, usage, and other event information.
The target direction for VNF interfaces is to employ APIs that are
implemented utilizing standardized messaging and modeling protocols
over standardized transports. Migrating to a virtualized environment
presents a tremendous opportunity to eliminate the need for proprietary
interfaces for VNF provider equipment while removing the traditional
boundaries between Network Management Systems and Element Management
Systems. Additionally, VNFs provide the ability to instrument the
networking applications by creating event records to test and monitor
end-to-end data flow through the network, similar to what physical or
virtual probes provide without the need to insert probes at various
points in the network. The VNF providers must be able to provide the
aforementioned set of required data directly to the ONAP collection
layer using standardized interfaces.
Data Model for Event Records
^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
This section describes the data model for the collection of telemetry
data from VNFs by Service Providers (SPs) to manage VNF health and
runtime lifecycle. This data model is referred to as the VNF Event
Streaming (VES) specifications. While this document is focused on
specifying some of the records from the ONAP perspective, there may
be other external bodies using the same framework to specify additional
records. For example, OPNFV has a VES project that is looking to specify
records for OpenStack’s internal telemetry to manage Application (VNFs),
physical and virtual infrastructure (compute, storage, network devices),
and virtual infrastructure managers (cloud controllers, SDN controllers).
Note that any configurable parameters for these data records (e.g.,
frequency, granularity, policy-based configuration) will be managed
using the “Configuration” framework described in the prior sections
of this document.
The Data Model consists of:
- Common Header Record: This data structure precedes each of the
Technology Independent and Technology Specific records sections of
the data model.
- Technology Independent Records: This version of the document
specifies the model for Fault, Heartbeat, State Change, Syslog,
Threshold Crossing Alerts, and VNF Scaling* (short for
measurementForVfScalingFields – actual name used in JSON
specification) records. In the future, these may be extended to
support other types of technology independent records. Each of
these records allows additional fields (name/ value pairs) for
extensibility. The VNF provider can use these VNF Provider-specific
additional fields to provide additional information that may be
relevant to the managing systems.
- Technology Specific Records: This version of the document specifies
the model for Mobile Flow records, Signaling and Voice Quality records.
In the future, these may be extended to support other types of records
(e.g. Network Fabric, Security records, etc.). Each of these records
allows additional fields (name/value pairs) for extensibility. The VNF
providers can use these VNF-specific additional fields to provide
additional information that may be relevant to the managing systems.
A placeholder for additional technology specific areas of interest to
be defined in the future documents has been depicted.
|image0|
Figure 1. Data Model for Event Records
Event Records - Data Structure Description
^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
The data structure for event records consists of:
- a Common Event Header block;
- zero or more technology independent domain blocks; and
- e.g., Fault domain, State Change domain, Syslog domain, etc.
- zero or more technology specific domain blocks.
- e.g., Mobile Flow domain, Signaling domain, Voice Quality domain,
etc.
Common Event Header
~~~~~~~~~~~~~~~~~~~~~
The common header that precedes any of the domain-specific records contains
information identifying the type of record to follow, information about
the sender and other identifying characteristics related to timestamp,
sequence number, etc.
Technology Independent Records – Fault Fields
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
The Fault Record, describing a condition in the Fault domain, contains
information about the fault such as the entity under fault, the
severity, resulting status, etc.
Technology Independent Records – Heartbeat Fields
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
The Heartbeat Record provides an optional structure for communicating
information about heartbeat or watchdog signaling events. It can
contain information about service intervals, status information etc.
as required by the heartbeat implementation.
Note: Heartbeat records would only have the Common Event Header block.
An optional heartbeat domain is available if required by the heartbeat
implementation.
Technology Independent Records – State Change Fields
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
The State Change Record provides a structure for communicating information
about data flow through the VNF. It can contain information about state
change related to physical device that is reported by VNF. As an example,
when cards or port name of the entity that has changed state.
Technology Independent Records – Syslog Fields
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
The Syslog Record provides a structure for communicating any type of
information that may be logged by the VNF. It can contain information
about system internal events, status, errors, etc.
Technology Independent Records – Threshold Crossing Alert Fields
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
The Threshold Crossing Alert (TCA) Record provides a structure for
communicating information about threshold crossing alerts. It can
contain alert definitions and types, actions, events, timestamps
and physical or logical details.
Technology Independent Records - VNF Scaling Fields
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
The VNF Scaling\* (short for measurementForVfScalingFields –
actual name used in JSON specification) Record contains information
about VNF and VNF resource structure and its condition to help in
the management of the resources for purposes of elastic scaling.
Technology Independent Records – otherFields
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
The otherFields Record defines fields for events belonging to the
otherFields domain of the Technology Independent domain enumeration.
This record provides a mechanism to convey a complex set of fields
(possibly nested or opaque) and is purely intended to address
miscellaneous needs such as addressing time-to-market considerations
or other proof-of-concept evaluations. Hence, use of this record
type is discouraged and should be minimized.
Technology Specific Records – Mobile Flow Fields
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
The Mobile Flow Record provides a structure for communicating
information about data flow through the VNF. It can contain
information about connectivity and data flows between serving
elements for mobile service, such as between LTE reference points, etc.
Technology Specific Records – Signaling Fields
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
The Signaling Record provides a structure for communicating information
about signaling messages, parameters and signaling state. It can
contain information about data flows for signaling and controlling
multimedia communication sessions such as voice and video calls.
Technology Specific Records – Voice Quality Fields
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
The Voice Quality Record provides a structure for communicating information
about voice quality statistics including media connection information,
such as transmitted octet and packet counts, packet loss, packet delay
variation, round-trip delay, QoS parameters and codec selection.
Technology Specific Records – Future Domains
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
The futureDomains Record is a placeholder for additional technology
specific areas of interest that will be defined and described
in the future documents.
Data Structure Specification of the Event Record
^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
For additional information on the event record formats of the data
structures mentioned above, please refer to `VES Event
Listener <https://github.com/att/evel-test-collector/tree/master/docs/att_interface_definition>`__.
Transports and Protocols Supporting Resource Interfaces
^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
Delivery of data from VNFs to ONAP must use the common transport
mechanisms and protocols for all VNFs as defined in this document.
Transport mechanisms and protocols have been selected to enable both
high volume and moderate volume datasets, as well as asynchronous and
synchronous communications over secure connections. The specified
encoding provides self-documenting content, so data fields can be
changed as needs evolve, while minimizing changes to data delivery.
The term ‘Event Record’ is used throughout this document to represent
various forms of telemetry or instrumentation made available by the
VNF including, faults, status events, various other types of VNF
measurements and logs. Headers received by themselves must be used
as heartbeat indicators. Common structures and delivery protocols for
other types of data will be given in future versions of this document
as we get more insight into data volumes and required processing.
In the following sections, we provide options for encoding, serialization
and data delivery. Agreements between Service Providers and VNF providers
shall determine which encoding, serialization and delivery method to use
for particular data sets. The selected methods must be agreed to prior to
the on-boarding of the VNF into ONAP design studio.
VNF Telemetry using VES/JSON Model
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
The preferred model for data delivery from a VNF to ONAP DCAE is
the JSON driven model as depicted in Figure 2.
|image1|
Figure 2. VES/JSON Driven Model
VNF providers will provide a YAML artifact to the Service Provider
that describes:
* standard VES/JSON model information elements (key/values) that
the VNF provides
* any additional non-standard (custom) VES/JSON model information
elements (key/values) that the VNF provides
Using the semantics and syntax supported by YAML, VNF providers
will indicate specific conditions that may arise, and recommend
actions that should be taken at specific thresholds, or if specific
conditions repeat within a specified time interval.
Based on the VNF provider's recommendations, the Service Provider may
create additional YAML artifacts (using ONAP design Studio), which
finalizes Service Provider engineering rules for the processing of
the VNF events. The Service Provider may alter the threshold levels
recommended by the VNF providor, and may modify and more clearly
specify actions that should be taken when specified conditions arise.
The Service Provider-created version of the YAML artifact will be
distributed to ONAP applications by the Design framework.
VNF Telemetry using YANG Model
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
In addition to the JSON driven model described above, a YANG
driven model can also be supported, as depicted in Figure 3.
|image2|
Figure 3. YANG Driven Model
VNF providers will provide to the Service Provider the following
YANG model artifacts:
* common IETF YANG modules that support the VNF
* native (VNF provider-supplied) YANG modules that support the VNF
* open (OpenConfig) YANG modules and the following
configuration-related information, including:
* telemetry configuration and operational state data; such as:
* sensor paths
* subscription bindings
* path destinations
* delivery frequency
* transport mechanisms
* data encodings
* a YAML artifact that provides all necessary mapping relationships
between YANG model data types to VES/JSON information elements
* YANG helper or decoder functions that automate the conversion between
YANG model data types to VES/JSON information elements
* OPTIONAL: YANG Telemetry modules in JSON format per RFC 7951
Using the semantics and syntax supported by YANG, VNF providers
will indicate specific conditions that may arise, and recommend
actions that should be taken at specific thresholds, or if specific
conditions repeat within a specified time interval.
Based on the VNF provider's recommendations, the Service Provider may
create additional YAML artifacts (using ONAP design Studio), which
finalizes Service Provider engineering rules for the processing of the
VNF events. The Service Provider may alter the threshold levels recommended
by the VNF provider, and may modify and more clearly specify actions that
should be taken when specified conditions arise. The Service
Provided-created version of the YAML will be distributed to ONAP
applications by the Design framework.
Note: While supporting the YANG model described above, we are still
leveraging the VES JSON based model in DCAE. The purpose of the
diagram above is to illustrate the concept only and not to imply a
specific implementation.
VNF Telemetry using Google Protocol Buffers
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
In addition to the data delivery models described above, support for
delivery of VNF telemetry using Google Protocol Buffers (GPB) can
also be supported, as depicted in Figure 4.
VNF providers will provide to the Service Provider the additional
following artifacts to support the delivery of VNF telemetry to DCAE
via the open-source gRPC mechanism using Google's Protocol Buffers:
* the YANG model artifacts described in support of the
"VNF Telemetry using YANG Model"
* valid definition file(s) for all GPB / KV-GPB encoded messages
* valid definition file(s) for all gRPC services
* gRPC method parameters and return types specified as Protocol
Buffers messages
|image3|
Figure 4. Protocol Buffers Driven Model
Note: if Google Protocol Buffers are employed for delivery of VNF
telemetry, Key-Value Google Protocol Buffers (KV-GPB) is the
preferred serialization method. Details of specifications and
versioning corresponding to a release can be found at:
`VES Event Listener <https://github.com/att/evel-test-collector/tree/master/docs/att_interface_definition>`__.
Note: While supporting the VNF telemetry delivery approach described above,
we are still leveraging the VES JSON based model in DCAE. The purpose of
the diagram above is to illustrate the concept only and not to imply a
specific implementation.
Monitoring & Management Requirements
^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
VNF telemetry via standardized interface
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
* R-51910 The xNF **MUST** provide all telemetry (e.g., fault event
records, syslog records, performance records etc.) to ONAP using the
model, format and mechanisms described in this section.
Encoding and Serialization
~~~~~~~~~~~~~~~~~~~~~~~~~~~
Content delivered from VNFs to ONAP is to be encoded and serialized using JSON:
JSON
~~~~~~~~~~~~~~~~~~
* R-19624 The xNF **MUST** encode and serialize content delivered to ONAP using JSON (RFC 7159) plain text format. High-volume data
is to be encoded and serialized using `Avro <http://avro.apache.org/>`_, where the Avro [5]_ data format are described using JSON.
- JSON plain text format is preferred for moderate volume data sets
(option 1), as JSON has the advantage of having well-understood simple
processing and being human-readable without additional decoding. Examples
of moderate volume data sets include the fault alarms and performance
alerts, heartbeat messages, measurements used for xNF scaling and syslogs.
- Binary format using Avro is preferred for high volume data sets
(option 2) such as mobility flow measurements and other high-volume
streaming events (such as mobility signaling events or SIP signaling)
or bulk data, as this will significantly reduce the volume of data
to be transmitted. As of the date of this document, all events are
reported using plain text JSON and REST.
- Avro content is self-documented, using a JSON schema. The JSON schema is
delivered along with the data content
(http://avro.apache.org/docs/current/ ). This means the presence and
position of data fields can be recognized automatically, as well as the
data format, definition and other attributes. Avro content can be
serialized as JSON tagged text or as binary. In binary format, the
JSON schema is included as a separate data block, so the content is
not tagged, further compressing the volume. For streaming data, Avro
will read the schema when the stream is established and apply the
schema to the received content.
In addition to the preferred method (JSON), content can be delivered
from xNFs to ONAP can be encoded and serialized using Google Protocol
Buffers (GPB).
KV-GPB/GPB
~~~~~~~~~~~~~~~~~~
Telemetry data delivered using Google Protocol Buffers v3 (proto3)
can be serialized in one of the following methods:
* Key-value Google Protocol Buffers (KV-GPB) is also known as
self-describing GPB:
* keys are strings that correspond to the path of the system
resources for the VNF being monitored.
* values correspond to integers or strings that identify the
operational state of the VNF resource, such a statistics counters
and the state of a VNF resource.
* VNF providers must supply valid KV-GPB definition file(s) to allow
for the decoding of all KV-GPB encoded telemetry messages.
* Native Google Protocol Buffers (GPB) is also known as compact GPB:
* keys are represented as integers pointing to the system resources for
the VNF being monitored.
* values correspond to integers or strings that identify the operational
state of the VNF resource, such a statistics counters and the state
of a VNF resource.
* Google Protocol Buffers (GPB) requires metadata in the form of .proto
files. VNF providers must supply the necessary GPB .proto files such that
GPB telemetry messages can be encoded and decoded.
* In the future, we may consider support for other types of
encoding & serialization methods based on industry demand.
Reporting Frequency
~~~~~~~~~~~~~~~~~~~~~
* R-98191 The xNF **MUST** vary the frequency that asynchronous data
is delivered based on the content and how data may be aggregated or
grouped together. For example, alarms and alerts are expected to be
delivered as soon as they appear. In contrast, other content, such as
performance measurements, KPIs or reported network signaling may have
various ways of packaging and delivering content. Some content should
be streamed immediately; or content may be monitored over a time interval,
then packaged as collection of records and delivered as block; or data
may be collected until a package of a certain size has been collected;
or content may be summarized statistically over a time interval, or
computed as a KPI, with the summary or KPI being delivered.
- We expect the reporting frequency to be configurable depending
on the virtual network function’s needs for management. For example,
Service Provider may choose to vary the frequency of collection between
normal and trouble-shooting scenarios.
- Decisions about the frequency of data reporting will affect the
size of delivered data sets, recommended delivery method, and how the
data will be interpreted by ONAP. These considerations should not
affect deserialization and decoding of the data, which will be guided
by the accompanying JSON schema or GPB definition files.
Addressing and Delivery Protocol
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
ONAP destinations can be addressed by URLs for RESTful data PUT. Future
data sets may also be addressed by host name and port number for TCP
streaming, or by host name and landing zone directory for SFTP transfer
of bulk files.
* R-88482 The xNF **SHOULD** use REST using HTTPS delivery of plain
text JSON for moderate sized asynchronous data sets, and for high
volume data sets when feasible.
* R-84879 The xNF **MUST** have the capability of maintaining a primary
and backup DNS name (URL) for connecting to ONAP collectors, with the
ability to switch between addresses based on conditions defined by policy
such as time-outs, and buffering to store messages until they can be
delivered. At its discretion, the service provider may choose to populate
only one collector address for a xNF. In this case, the network will
promptly resolve connectivity problems caused by a collector or network
failure transparently to the xNF.
* R-81777 The VNF **MUST** be configured with initial address(es) to use
at deployment time. Subsequently, address(es) may be changed through
ONAP-defined policies delivered from ONAP to the VNF using PUTs to a
RESTful API, in the same manner that other controls over data reporting
will be controlled by policy.
* R-08312 The xNF **MAY** use other options which are expected to include
- REST delivery of binary encoded data sets.
- TCP for high volume streaming asynchronous data sets and for other
high volume data sets. TCP delivery can be used for either
JSON or binary encoded data sets.
- SFTP for asynchronous bulk files, such as bulk files that contain
large volumes of data collected over a long time interval or data
collected across many xNFs. This is not preferred. Preferred is to
reorganize the data into more frequent or more focused data sets, and
deliver these by REST or TCP as appropriate.
- REST for synchronous data, using RESTCONF (e.g., for xNF state polling).
* R-03070 The xNF **MUST**, by ONAP Policy, provide the ONAP addresses
as data destinations for each xNF, and may be changed by Policy while
the xNF is in operation. We expect the xNF to be capable of redirecting
traffic to changed destinations with no loss of data, for example from
one REST URL to another, or from one TCP host and port to another.
Asynchronous and Synchronous Data Delivery
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
* R-06924 The xNF **MUST** deliver asynchronous data as data becomes
available, or according to the configured frequency.
* R-73285 The xNF **MUST** must encode, address and deliver the data
as described in the previous paragraphs.
* R-42140 The xNF **MUST** respond to data requests from ONAP as soon
as those requests are received, as a synchronous response.
* R-34660 The xNF **MUST** use the RESTCONF/NETCONF framework used by
the ONAP configuration subsystem for synchronous communication.
* R-86585 The VNF **MUST** use the YANG configuration models and RESTCONF
[RFC8040] (https://tools.ietf.org/html/rfc8040).
* R-11240 The xNF **MUST** respond with content encoded in JSON, as
described in the RESTCONF specification. This way the encoding of a
synchronous communication will be consistent with Avro.
* R-70266 The xNF **MUST** respond to an ONAP request to deliver the
current data for any of the record types defined in
`Event Records - Data Structure Description`_ by returning the requested
record, populated with the current field values. (Currently the defined
record types include fault fields, mobile flow fields, measurements for
xNF scaling fields, and syslog fields. Other record types will be added
in the future as they become standardized and are made available.)
* R-46290 The xNF **MUST** respond to an ONAP request to deliver granular
data on device or subsystem status or performance, referencing the YANG
configuration model for the xNF by returning the requested data elements.
* R-43327 The xNF **SHOULD** use `Modeling JSON text with YANG
<https://tools.ietf.org/html/rfc7951>`_, If YANG models need to be
translated to and from JSON{RFC7951]. YANG configuration and content can
be represented via JSON, consistent with Avro, as described in “Encoding
and Serialization” section.
Security
~~~~~~~~~~
* R-42366 The xNF **MUST** support secure connections and transports such as
Transport Layer Security (TLS) protocol
[`RFC5246 <https://tools.ietf.org/html/rfc5246>`_] and should adhere to
the best current practices outlined in
`RFC7525 <https://tools.ietf.org/html/rfc7525>`_.
* R-44290 The xNF **MUST** control access to ONAP and to xNFs, and creation
of connections, through secure credentials, log-on and exchange mechanisms.
* R-47597 The xNF **MUST** carry data in motion only over secure connections.
* R-68165 The xNF **MUST** encrypt any content containing Sensitive Personal
Information (SPI) or certain proprietary data, in addition to applying the
regular procedures for securing access and delivery.
.. [1]
https://github.com/mbj4668/pyang
.. [2]
Recall that the Node Object **is required** to be identical across
all VMs of a VNF invoked as part of the action except for the “name”.
.. [3]
Upstream elements must provide the appropriate FQDN in the request to
ONAP for the desired action.
.. [4]
Multiple ONAP actions may map to one playbook.
.. [5]
This option is not currently supported in ONAP and it is currently
under consideration.
.. [6]
https://wiki.opnfv.org/display/PROJ/VNF+Event+Stream
.. |image0| image:: Data_Model_For_Event_Records.png
:width: 7in
:height: 8in
.. |image1| image:: VES_JSON_Driven_Model.png
:width: 5in
:height: 3in
.. |image2| image:: YANG_Driven_Model.png
:width: 5in
:height: 3in
.. |image3| image:: Protocol_Buffers_Driven_Model.png
:width: 4.74in
:height: 3.3in
|