Internet DRAFT - draft-voit-netmod-peer-mount-requirements
draft-voit-netmod-peer-mount-requirements
NETCONF Data Modeling Language Working Group (netmod) E. Voit
Internet-Draft A. Clemm
Intended status: Informational Cisco Systems
Expires: March 17, 2016 S. Mertens
Prismtech
September 14, 2015
Requirements for mounting of local and remote YANG subtrees
draft-voit-netmod-peer-mount-requirements-03
Abstract
Network integrated applications want simple ways to reference and
access YANG objects and subtrees. These simplifications might
include aliasing of local YANG information. These simplifications
might include remote referencing of YANG information distributed
across network.
For such applications, development complexity must be minimized.
Specific aspects of complexity developers want to ignore include:
o whether multiple aliases and paths for the same information are
exposed on a single device,
o whether authoritative information is actually sourced from local
or remote datastores,
o the overhead of session establishment and maintenance which is
needed in order to access information on remote datastores,
o whether objects have been locally cached or not, and
o whether there is a mix of controllers, NMSs, and/or CLI which have
access permission to update the primary copy of a particular
object.
The solution requirements described in this document detail what is
needed to support application access to authoritative network YANG
objects locally (via aliasing), or remotely from controllers or
peering network devices in such a way to meet these goals.
Status of This Memo
This Internet-Draft is submitted in full conformance with the
provisions of BCP 78 and BCP 79.
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Table of Contents
1. Business Problem . . . . . . . . . . . . . . . . . . . . . . 3
2. Terminology . . . . . . . . . . . . . . . . . . . . . . . . . 4
3. Solution Context . . . . . . . . . . . . . . . . . . . . . . 5
3.1. YANG Mount . . . . . . . . . . . . . . . . . . . . . . . 6
3.2. Eventual Consistency and YANG . . . . . . . . . . . . . . 8
4. Example Use Cases . . . . . . . . . . . . . . . . . . . . . . 8
4.1. Cloud Policer . . . . . . . . . . . . . . . . . . . . . . 9
4.2. DDoS Thresholding . . . . . . . . . . . . . . . . . . . . 10
4.3. Service Chain Classification, Load Balancing and Capacity
Management . . . . . . . . . . . . . . . . . . . . . . . 11
5. Requirements . . . . . . . . . . . . . . . . . . . . . . . . 12
5.1. Application Simplification . . . . . . . . . . . . . . . 12
5.2. Caching . . . . . . . . . . . . . . . . . . . . . . . . . 13
5.3. Subscribing to Remote Object Updates . . . . . . . . . . 14
5.4. Lifecycle of the Mount Topology . . . . . . . . . . . . . 14
5.5. Mount Filter . . . . . . . . . . . . . . . . . . . . . . 15
5.6. Auto-Negotiation of Peer Mount Client QoS . . . . . . . . 15
5.7. Datastore Qualification . . . . . . . . . . . . . . . . . 16
5.8. Mount Cascades . . . . . . . . . . . . . . . . . . . . . 16
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5.9. Transport . . . . . . . . . . . . . . . . . . . . . . . . 16
5.10. Security Considerations . . . . . . . . . . . . . . . . . 16
5.11. High Availability . . . . . . . . . . . . . . . . . . . . 17
5.12. Configuration . . . . . . . . . . . . . . . . . . . . . . 19
5.13. Assurance and Monitoring . . . . . . . . . . . . . . . . 19
6. IANA Considerations . . . . . . . . . . . . . . . . . . . . . 19
7. Acknowledgements . . . . . . . . . . . . . . . . . . . . . . 19
8. References . . . . . . . . . . . . . . . . . . . . . . . . . 19
8.1. Normative References . . . . . . . . . . . . . . . . . . 20
8.2. Informative References . . . . . . . . . . . . . . . . . 20
8.3. URIs . . . . . . . . . . . . . . . . . . . . . . . . . . 21
Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . . 21
1. Business Problem
Instrumenting Physical and Virtual Network Elements purely along
device boundaries and via a fully normalized object representation is
insufficient for today's requirements. Instead, users, applications,
and operators are asking for the ability to interact with local and
remote information exposed as simply as possible from a familiar
local datastore.
Achieving an easy, local abstract representation of any remote
information can be difficult since a running network is comprised of
a distributed mesh of object ownership. Solutions require the
transparent assembly of local and remote objects in order to provide
context specific, time synchronized, and consistent views required
for a simple local abstraction.
Ultimately network application programming must be simplified. To do
this:
o we must allow local and remote aliasing of network objects so that
programmers can work against models which have been tuned for
their development environment, structured in ways that best make
sense to them
o we must provide APIs to both controller and network element based
applications in a way which allows access to these objects,
o we must hide the mesh of interdependencies and consistency
enforcement mechanisms between devices which will underpin a
particular abstraction,
o we must enable flexible deployment models, in which applications
are able to run not only on controller and OSS frameworks but also
on network devices without requiring heavy middleware with large
footprints, and
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o we need to maintain clear authoritative ownership of individual
data items while not burdening applications with the need to
reconcile and synchronize information replicated in different
systems, nor needing to maintain redundant data models that
operate on the same underlying data.
These steps will eliminate much unnecessary overhead currently
required of today's network programmer.
2. Terminology
The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
"SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this
document are to be interpreted as described in RFC 2119 [RFC2119].
Alias Mount - A type of YANG Mount performed against a subtree
located in a local datastore.
Authoritative Datastore - A datastore containing the authoritative
copy of an object, i.e. the source and the "owner" of the object.
Client Datastore - a datastore containing an object whose source and
"owner" is a remote datastore.
Data Node - An instance of management information in a YANG
datastore.
Datastore - A conceptual store of instantiated information, with
individual data items represented by data nodes which are arranged in
hierarchical manner.
Data Subtree - An instantiated data node and the data nodes that are
hierarchically contained within it.
Mount Client - The system at which the mount point resides, into
which one or more subtrees may be mounted.
Mount Binding - An instance of YANG mount from a specific Mount Point
to a datastore. Types include:
o On-demand: Mount Client only pulls information when application
requests
o Periodic: Mount Server pushes current state at a pre-defined
interval
o Unsolicited: Mount Server maintains active bindings and sends to
client cache upon change
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Mount Point - Point in the local data store which may reference a
single remote subtree
Mount Server - The server with which the Mount Client communicates
and which provides the Mount Client with access to the mounted
information. Can be used synonymously with Mount Target.
Peer Mount - A method of YANG Mount which enables the representation
of remote objects within a local datastore.
Target Data Node - Data Node on Mount Server against which a Mount
Binding is established
YANG Mount - A method of including YANG data node from another
location as part of a specific YANG model and on a specific path in
the data tree via an explicit reference to a subtree to be included.
Two subtypes are Alias Mount and Peer Mount.
3. Solution Context
YANG modeling has emerged as a preferred way to offer network
abstractions. The requirements in this document can be enabled by
expanding of the syntax of YANG capabilities embodied within RFC 6020
[RFC6020] and YANG 1.1 [rfc6020bis]. A companion draft to this one
which details a potential set of YANG technology extensions which can
support key requirements within this document are contained in .
[draft-clemm-mount].
To date systems built upon YANG models have been missing two
capabilities:
1. YANG Datastore Mount: Datastores have not been able to proxy
objects located elsewhere on the same device, or upon a different
device. This puts additional burden upon applications which then
need to find and access multiple locations and which may be on
remote systems.
2. Eventual Consistency: YANG Datastore implementations have
typically assumed ACID [1] transaction models. There is nothing
inherent in YANG itself which demands ACID transactional
guarantees. YANG models can also expose information which might
be in the process of undergoing convergence. Since IP networking
has been designed with convergence in mind, this is a useful
capability since some types of applications must participate
where there is dynamically changing state.
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3.1. YANG Mount
First this document will dive deeper into YANG Datastore Mount
(a.k.a., "YANG Mount"). Two subtypes of YANG Mount are "Alias Mount"
and "Peer Mount".
Alias Mount allows access to the same YANG data node along different
paths within the same YANG datastore, allowing a given subtree to
subtend from different YANG models within the same system. This
provides a means to:
o Provide application developers with custom and consolidated YANG
objects that expose only the needed objects.
o Expose the objects organized into alternative structures,
referenced via alternative application-intuitive paths. (This may
include aliasing additional hierarchy layers to get to existing
objects, including objects that had hitherto been right under
root.)
o Accomplishing this without requiring mirroring or replication of
the underlying data across various datastores.
Considering there are YANG models incorporating intersected and
replicated information today, adding an Alias Mount capability should
reduce YANG model development and model mapping requirements.
For Peer Mount, we need the capability to refer to managed resources
that reside on different systems. This allows applications on the
same system as the YANG datastore server, as well as remote clients
that access the datastore through a management protocol such as
NETCONF, to access all data from a familiar local YANG model.
o This is done in a manner that is transparent to users and
applications.
o This is done in a way which does not require a user or application
to be aware of the fact that some data resides in a different
location and have them directly access that other system
In this way, an application developer is projected an image of one
virtual consolidated datastore. Peer Mount builds on Alias Mount by
allowing to incorporate redirection to remote systems into the
structure.
The value in YANG Mount comes from its under-the-covers federation.
The datastore transparently exposes information about objects that
can be reached along multiple paths, allowing to make the same data
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nodes part of multiple concurrent hierarchies. The user does not
need to be aware of the precise distribution and ownership of data
themselves, nor is there a need for the application to discover those
data sources, maintain separate associations with them, and partition
its operations to fit along remote system boundaries. The effect is
that a network device can broaden and customize the information
available for local access. Life for the application is easier.
At the same time, the authoritative ownership of a data node is never
in question. The original hierarchy and path that was defined when
the data node was first defined in a YANG module remain in effect,
and any validation involved in creating, modifying, or deleting the
data node always occurs in the same context in which it was
originally introduced. All that YANG Mount allows to do is to define
alternative, additional paths and hierarchies to which the object
could also be accessed.
Any Object or subtree type can be exposed via such a reference. This
can include configuration data that is either persistent or
ephemeral, and which is valid within only a single device or across a
domain of devices. This can include operational data that represents
state across a single device or across a multiple devices.
Another useful aspect of YANG Mount is its ability to embed
information from existing into newly defined models without requiring
additional normalization effort. Normalization is a good thing, but
the massive human efforts invested in uber-data-models have never
gained industry traction due to the resulting models' brittle nature
and complexity. By mounting subtrees/objects into local datastores
it is possible to expose objects under a locally optimized hierarchy
without having to transpose remote objects into a separate local
model.
It should be noted that YANG Mount does not require knowledge of the
entire subtree being mounted. For example, there might be
augmentations of that subtree, or even mounted information in the
subtree itself. Likewise, mounted objects might dynamically change,
or even come into being. These dynamic changes can be reflected as
needed under the "attachment points" within the namespace hierarchy
where the data subtrees from remote systems have been mounted. In
this case, the precise details of what these subtrees exactly contain
does not need to be understood by the system implementing the
attachment point, it simply acts as a single point of entry and
"proxy" for the attached data. .
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3.2. Eventual Consistency and YANG
The CAP theorem [2] states that it is impossible for a distributed
computer system to simultaneously provide Consistency, Availability,
and Partition tolerance. (I.e., distributed network state management
is hard.) Mostly for this reason YANG implementations have shied
away from distributed datastore implementations where ACID
transactional guarantees cannot be given. This of course limits the
universe of applicability for YANG technology.
Leveraging YANG concepts, syntax, and models for objects which might
be happening to undergo network convergence is valuable. Such reuse
greatly expands the universe of information visible to networking
applications. The good news is that there is nothing in YANG syntax
that prohibits its reapplication for distributed datastores.
Extensions are needed however.
Requirements described within this document can be used to define
technology extensions to YANG 1.1 for remote datastore mounting.
Because of the CAP theorem, it must be recognized that systems built
upon these extensions MAY choose to support eventual consistency
rather than ACID guarantees. Some applications do not demand ACID
guarantees (examples are contained in this document's Use Case
section). Therefore for certain classes of applications, eventual
consistency [3] should be viewed as a cornerstone feature capability
rather than a bug.
Other industries have been able to identify and realize the value in
such model. The Object Management Group Data-Distribution Service
for Real-Time Systems has even standardized these capabilities for
non-YANG deployments [OMG-DDS]. Commercial deployments exist.
4. Example Use Cases
Example Use Cases for Alias Mount can easily be seen from the
description within Section 3.1. Therefore these are not detailed
within this document. In general, those use cases involve imposing
an alternative structure over YANG data models. YANG allows to
extend and augment data models, allowing to add new data nodes as
child nodes or as siblings to existing data nodes. However, YANG
does not allow to superimpose a new data node on top of an existing
one, or move an existing node under a newly defined node. Peer Mount
closes that gap and allows to define models with alternative
hierarchies and insert existing data nodes into that hierarchy.
For Peer Mount, many types of applications can benefit from the
simple and quick availability of objects from peer network devices.
Because network management and orchestration systems have been
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fulfilling a subset of the requirements for decades, it is important
to focus on what has changed. Changes include:
o SDN applications wish to interact with local datastore(s) as if
they represent the real-time state of the distributed network.
o Independent sets of applications and SDN controllers might care
about the same authoritative data node or subtree.
o Changes in the real-time state of objects can announce themselves
to subscribing applications.
o The union of an ever increasing number of abstractions provided
from different layers of the network are assumed to be consistent
with each other (at least once a reasonable convergence time has
been factored in).
o CPU and VM improvements makes running Linux based applications on
network elements viable.
Such changes can enable a new class of applications. These
applications are built upon fast-feedback-loops which dynamically
tune the network based on iterative interactions upon a distributed
datastore.
4.1. Cloud Policer
A Cloud Policer enables a single aggregated data rate to tenants/
users of a data center cloud that applies across their VMs; a rate
independent of where specific VMs are physically hosted. This works
by having edge router based traffic counters available to a
centralized application, which can then maintain an aggregate across
those counters. Based on the sum of the counters across the set of
edge routers, new values for each device based Policer can be
recalculated and installed. Effectively policing rates are
continuously rebalanced based on the most recent traffic offered to
the aggregate set of edge devices.
The cloud policer provides a very simple cloud QoS model. Many other
QoS models could also be implemented. Example extensions include:
o CIR/PIR guarantees for a tenant,
o hierarchical QoS treatment,
o providing traffic delivery guarantees for specific enterprise
branch offices, and
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o adjusting the prioritization of one application based on the
activity of another application which perhaps is in a completely
different location.
It is possible to implement such a cloud policer application with
maximum application developer simplicity using peer mount. To do
this the application accesses a local datastore which in turn does a
peer mount from edge routers the objects which house current traffic
counter statistics. These counters are accessed as if they were part
of the local datastore structures, without concern for the fact that
the actual authoritative copies reside on remote systems.
Beyond this centralized counter collection peer mount, it is also
possible to have distributed edge routers mount information in the
reverse direction. In this case local edge routers can peer mount
centrally calculated policer rates for the device, and access these
objects as if they were locally configured.
For both directions of mounting, the authoritative copy resides in a
single system and is mounted by peers. Therefore issues with regards
to inconsistent configuration of the same redundant data across the
network are avoided. Also as can be seen in this use case, the same
system can act as a mount client of some objects while acting as
server for other objects.
4.2. DDoS Thresholding
Another extension of the "Cloud Policer" application is the creation
of additional action thresholds at bandwidth rates far greater than
might be expected. If these higher thresholds are hit, it is
possible to connect in DDoS scrubbers to ingress traffic. This can
be done in seconds after a bandwidth spike. This can also be done if
non-bandwidth counters are available. For example, if TCP flag
counts are available it is possible to look for changes in SYN/ACK
ratios which might signal a different type of attack. In all cases,
when network counters indicate a return to normal traffic profiles
the DDoS Scrubbers can be automatically disconnected.
Benefits of only connecting a DDoS scrubber in the rare event an
attack might be underway include:
o marking down traffic for an out-of-profile tenant so that an
potential attack doesn't adversely impact others,
o applying DDoS Scrubbing across many devices when an attack is
detected in one,
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o reducing DDoS scrubber CPU, power, and licensing requirements
(during the vast majority of time, spikes are not occurring), and
o dynamic management and allocation of scarce platform resources
(such as optimizing span port usage, or limiting IP-FIX reporting
to levels where devices can do full flow detail exporting).
4.3. Service Chain Classification, Load Balancing and Capacity
Management
Service Chains will dynamically change ingress classification
filters, allocate paths from many ingress devices across shared
resources. This information needs to be updated in real time as
available capacity is allocated or failures are discovered. It is
possible to simplify service chain configuration and dynamic topology
maintenance by transparently updating remote cached topologies when
an authoritative object is changed within a central repository. For
example if the CPU in one VM spikes, you might want to recalculate
and adjust many chained paths to relieve the pressure. Or perhaps
after the recalculation you want to spin up a new VM, and then adjust
chains when that capacity is on-line.
A key value here is central calculation and transparent auto-
distribution. In other words, a change only need be updated by an
application in a single location, and the infrastructure will
automatically synchronize changes across any number of subscribing
devices without application involvement. In fact, the application
need not even know many devices are monitoring the object which has
been changed.
Beyond 1:n policy distribution, applications can step back from
aspects of failure recovery. What happens if a device is rebooting
or simply misses a distribution of new information? With peer mount
there is no doubt as to where the authoritative information resides
if things get out of synch.
While this ability is certainly useful for dynamic service chain
filtering classification and next hop mapping, this use case has more
general applicability. With a distributed datastore, diverse
applications and hosts can locally access a single device's current
VM CPU and Bandwidth values. They can do it without needing to
explicitly query that remote machine. Updates from a device would
come from a periodic push of stats to a transparent cache to
subscribed, or via an unsolicited update which is only sent when
these value exceed established norms.
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5. Requirements
To achieve the objectives described above, the network needs to
support a number of requirements
5.1. Application Simplification
A major obstacle to network programmability are any requirements
which force applications to use abstractions more complicated than
the developer cares to touch. To simplify applications development
and reduce unnecessary code, the following needs must be met.
Applications MUST be able to access a local datastore which includes
objects whose authoritative source perhaps is located in a elsewhere
in some datastore.
Local datastores MUST be able to provide a hierarchical view of
objects assembled from objects whose authoritative source may
potentially originate from different and overlapping namespaces.
Applications MUST be able to access all objects of a datastore
without concern where the actual object is located, i.e. whether the
authoritative copy of the object is hosted on the same system as the
local datastore or whether it is hosted in a remote datastore.
A datastore's application facing interfaces MUST make no
differentiation whether individual objects exposed are
authoritatively owned by the datastore or mounted from elsewhere
When a change is made to an object, that change will be reflected in
any datastore in which the object is included.
A datastore supporting YANG Mount MUST allow the same object to be
mounted from multiple places.
Applications SHOULD be able to extract a time synchronized set of
operational data from the datastore. (In other words, the
application asks for a subset of network state at time-stamp or time-
range "X". The datastore would then deliver time synchronized
snapshots of the network state per the request. The datastore may
work with NTP and operational counter to optimize the synchronization
results of such a query. It is understood that some types of data
might be undergoing convergence conditions.)
Authoritative datastore retain full ownership of "their" objects.
This means that while remote datastores may access the data, any
modifications to objects that are initiated at those remote
datastores need to be authorized by the authoritative owner of the
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data. Likewise, the authoritative owner of the data may make changes
to objects, including modifications, additions, and deletions,
without needing to first ask for permission from remote clients.
Applications MUST be designed to deal with incomplete data if remote
objects are not accessible, e.g. due to temporal connectivity issues
preventing access to the authoritative source. (This will be true
for many protocols and programming languages. Mount is unlikely to
add anything new here unless applications have extra error handling
routines to deal with when there is no response from a remote
system.).
5.2. Caching
Remote objects in a datastore can be accessed "on demand", when the
application interacting with the datastore demands it. In that case,
a request made to the local datastore is forwarded to the remote
system. The response from the remote system, e.g. the retrieved
data, is subsequently merged and collated with the other data to
return a consolidated response to the invoking application.
A downside of a datastore which is distributed across devices can be
the latency induced when remote object acquisition is necessary.
There are plenty of applications which have requirements which simply
cannot be served when latency is introduced. The good news is that
the concept of caching lends itself well to distributed datastores.
It is possible to transparently store some types of objects locally
even when the authoritative copy is remote. Instead of fetching data
on demand when an application demands it, the application is simply
provided with the local copy. It is then up to the datastore
infrastructure to keep selected replicated info in synch, e.g. by
prefetching information, or by having the remote system publish
updates which are then locally stored. At this point, it is expected
that a preferred method of subscribing to and publishing updates will
be accomplished via [i2rs-pub-sub-reqts] and
[draft-clemm-datastore-push]. Other methods could work equally well
.
This is not a new idea. Caching and Content Delivery Networks (CDN)
have sped read access for objects within the Internet for years.
This has enabled greater performance and scale for certain content.
Just as important, these technologies have been employed without end
user applications being explicitly aware of their involvement. Such
concepts are applicable for scaling the performance of a distributed
datastore.
Where caching occurs, it MUST be possible for the Mount Client to
store object copies of a remote data node or subtree in such a way
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that applications are unaware that any caching is occurring.
However, the interface to a datastore MAY provide applications with a
special mode/flag to allow them to force a read-through.
Where caching occurs, system administration facilities SHOULD allow
facilities to flush either the entire cache, or information
associated with select Mount Points.
5.3. Subscribing to Remote Object Updates
When caching occurs, data can go stale. [draft-clemm-datastore-push]
provides a mechanism where changes in an authoritative data node or
subtree can be monitored. If changes occur, these changes can be
delivered to any subscribing datastores. In this way remote caches
can be kept up-to-date. In this way, directly monitoring remote
applications can quickly receive notifications without continuous
polling.
A Mount Server SHOULD support [draft-clemm-datastore-push] Periodic
and/or On-Change pub/sub capabilities in which one or more remote
clients subscribe to updates of a target data node / subtree, which
are then automatically published by the Mount Server.
It MUST be possible for Applications to bind to subscribed Data Node
/ Subtrees so that upon Mount Client receipt of subscribed
information, it is immediately passed to the application.
It MUST be possible for a Target Data Node to support 1:n Mount
Bindings to many subscribed Mount Points.
5.4. Lifecycle of the Mount Topology
Mount can drive a dynamic and richly interconnected mesh of peer-to-
peer of object relationships. Each of these Mounts will be
independently established by a Mount Client.
It MUST be possible to bootstrap the Mount Client by providing the
YANG paths to resources on the Mount Server.
There SHOULD be the ability to add Mount Client bindings during run-
time.
A Mount Client MUST be able to be able to create, delete, and timeout
Mount Bindings.
Any Subscription MUST be able to inform the Mount Client of an
intentional/graceful disconnect.
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A Mount Client MUST be able to verify the status of Subscriptions,
and drive re-establishment if it has disappeared.
5.4.1. Discovery and Creation of Mount Topology
Application visibility into an ever-changing set of network objects
is not trivial. While some applications can be easily configured to
know the Devices and available Mount Points of interest, other
applications will have to balance many aspects of dynamic device
availability, capabilities, and interconnectedness. Maintenance of
these dynamic elements can be done on the YANG objects themselves
without anything needed new for YANG Mount.
5.4.2. Restrictions on the Mount Topology
Mount Clients MUST NOT create recursive Mount bindings (i.e., the
Mount Client should not load any object or subtree which it has
already delivered to another in the role of a Mount Server.) Note:
Objects mounted from a controller as part of orchestration are *not*
considered the same objects as those which might be mounted back from
a network device showing the actual running config.
5.5. Mount Filter
The Mount Server default MUST be to deliver the same Data Node /
Subtree that would have been delivered via direct YANG access.
It SHOULD be possible for a Mount Client to request something less
than the full subtree or a target node as defined in
[i2rs-pub-sub-reqts].
5.6. Auto-Negotiation of Peer Mount Client QoS
The interest that a Mount Client expresses in a particular subtree
SHOULD include the non-functional data delivery requirements (QoS) on
the data that is being mounted. Additionally, Mount Servers SHOULD
advertise their data delivery capabilities. With this information
the Mount Client can decide whether the quality of the delivered data
is sufficient to serve applications residing above the Mount Client.
An example here is reliability. A reliable protocol might be
overkill for a state that is republished with high frequency.
Therefore a Mount Server may sometimes choose to not provide a
reliable method of communication for certain objects. It is up to
the Mount Client to determine whether what is offered is sufficiently
reliable for its application. Only when the Mount Server is offering
data delivery QoS better or equal to what is requested, shall a mount
binding be established.
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Another example is where subscribed objects must be pushed from the
Mount Server within a certain interval from when an object change is
identified. In such a scenario the interval period of the Mount
Server must be equal or smaller than what is requested by a Mount
Client. If this "deadline" is not met by the Mount Server the
infrastructure MAY take action to notify clients.
5.7. Datastore Qualification
It is conceivable to differentiate between different datastores on
the remote server, that is, to designate the name of the actual
datastore to mount, e.g. "running" or "startup". If on the target
node there are multiple datastores available, but there has no
specific datastore identified by the Mount Client, then the running
or "effective" datastore is the assumed target.
It is conceivable to use such Datastore Qualification in conjunction
with ephemeral datastores, to address requirements being worked in
the I2RS WG [draft-i2rs-ephemeral].
5.8. Mount Cascades
It is possible for the mounted subtree to in turn contain a
mountpoint. However, circular mount relationships MUST NOT be
introduced. For this reason, a mounted subtree MUST NOT contain a
mountpoint that refers back to a mount target that directly or
indirectly contains the originating mountpoint. As part of a mount
operation, the mount points of the mounted system need to be checked
accordingly.
5.9. Transport
Many secured transports are viable assuming transport, data security,
scale, and performance objectives are met. Netconf and/or Restconf
should be considered as starting points. Other transports may be
proposed over time.
It MUST be possible to support Netconf or Restconf Transport of
subscribed Nodes and Subtrees.
5.10. Security Considerations
Many security mechanisms exist to protect data access for CLI and API
on network devices. To the degree possible these mechanisms should
transparently protect data when performing a Peer Mount.
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The same mechanisms used to determine whether a remote host has
access to a particular YANG Data Node or Subtree MUST be invoked to
determine whether a Mount Client has access to that information.
The same traditional transport level security mechanism security used
for YANG over a particular transport MUST be used for the delivery of
objects from a Mount Server to a Mount Client.
A Mount Server implementation MUST NOT change any credentials passed
by the Mount Client system for any Mount Binding request.
The Mount Server MUST deliver no more objects from a Data Node or
Subtree than allowable based on the security credentials provided by
the Mount Client.
To ensure the ensuring maximum scale limits, it MUST be possible to
for a Mount Server to limit the number of bindings and transactional
limits
It SHOULD be possible to prioritize which Mount Binding instances
should be serviced first if there is CPU, bandwidth, or other
capacity constraints.
5.11. High Availability
A key intent for YANG Mount is to allow access to an authoritative
copy of an object for a particular domain. Of course system and
software failures or scheduled upgrades might mean that the primary
copy is not consistently accessible from a single device. In
addition, system failovers might mean that the authoritative copy
might be housed on a different device than the one where the binding
was originally established. YANG Mount architectures must be built
to enable Mount Clients to transparently provide access to objects
where the authoritative copy moves due to dynamic network
reconfigurations .
A YANG Mount architecture MUST guarantee that mount bindings between
a Mount Server and Mount Clients drive system behavior which is at
least eventually consistent. The infrastructure providing this level
of consistency MUST be able to operate in scenarios where a system is
(temporarily) not fully connected. Furthermore, Mount Clients MAY
have various requirements on the boundaries under which eventual
consistency is allowed to take place. This subject can be decomposed
in the following items:
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5.11.1. Reliability
A scenario that deserves attention in particular is when a subset of
Mount Clients receive and cache a pushed subscription update. If a
Mount Server loses connectivity, cross network element consistency
can be lost. In such a scenario Mount Clients MAY elect a new
designated Mount Server from the set of Mount Clients which have
received the latest state.
5.11.2. Alignment to late joining peers
When a mount binding is established a Mount Server SHOULD provide the
Mount Client with the latest state of the requested data. In order
to increase availability and fault tolerance an infrastructure MAY
support the capability to have multiple alignment sources. In
(temporary) absence of a Mount Server, Mount Clients MAY elect a
temporary Mount Server to service late joining Mount Clients.
5.11.3. Liveliness
Upon losing liveliness and being unable to refresh cached data
provided from a Mount Server, a Mount Client MAY decide to purge the
mount bindings of that server. Purging mount bindings under such
conditions however makes a system vulnerable to losing network-wide
consistency. A Mount Client can take proactive action based on the
assumption that the Mount Server is no longer available. When
connectivity is only temporarily lost, this assumption could be false
for other datastores. This can introduce a potential for decision-
making based on semantical disagreement. To properly handle these
scenarios, application behavior MUST be designed accordingly and
timeouts with regards to liveliness detection MUST be carefully
determined.
5.11.4. Merging of datasets
A traditional problem with merging replicated datasets during the
failover and recovery of Mount Servers is handling the corresponding
target data node lifecycle management. When two replicas of a
dataset experienced a prolonged loss of connectivity a merge between
the two is required upon re-establishing connectivity. A replica
might have been modifying contents of the set, including deletion of
objects. A naive merge of the two replicas would discard these
deletes by aligning the now stale, deleted objects to the replica
that deleted them.
Authoritative ownership is an elegant solution to this problem since
modifications of content can only take place at the owner. Therefore
a Mount Client SHOULD, upon reestablishing connectivity with a newly
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authoritative Mount Server, replace any existing cache contents from
a mount binding with the latest version.
5.11.5. Distributed Mount Servers
For selected objects, Mount Bindings SHOULD be allowed to Anycast
addresses so that a Distributed Mount Server implementation can
transparently provide (a) availability during failure events to Mount
Clients, and (b) load balancing on behalf of Mount Clients.
5.12. Configuration
At the Mount Client, it MUST be possible for all Mount bindings to
configure the following such that the application needs no knowledge.
This will include a diverse list of elements such as the YANG URI
path to the remote subtree.
5.13. Assurance and Monitoring
API usage for YANG should be tracked via existing mechanisms. There
is no intent to require additional transaction tracking than would
have been provided normally. However there are additional
requirements which should allow the state of existing and historical
bindings to be provided.
A Mount Client MUST be able to poll a Mount Server for the state of
Subsciptions maintained between the two devices.
A Mount Server MUST be able to publish the set of Subscriptions which
are currently established on or below any identified data node.
6. IANA Considerations
This document makes no request of IANA.
7. Acknowledgements
We wish to acknowledge the helpful contributions, comments, and
suggestions that were received from Ambika Prasad Tripathy. Shashi
Kumar Bansal, Prabhakara Yellai, Dinkar Kunjikrishnan, Harish
Gumaste, Rohit M., Shruthi V. , Sudarshan Ganapathi, and Swaroop
Shastri.
8. References
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8.1. Normative References
[RFC2119] Bradner, S., "Key words for use in RFCs to Indicate
Requirement Levels", BCP 14, RFC 2119,
DOI 10.17487/RFC2119, March 1997,
<http://www.rfc-editor.org/info/rfc2119>.
[RFC6020] Bjorklund, M., Ed., "YANG - A Data Modeling Language for
the Network Configuration Protocol (NETCONF)", RFC 6020,
DOI 10.17487/RFC6020, October 2010,
<http://www.rfc-editor.org/info/rfc6020>.
8.2. Informative References
[draft-clemm-datastore-push]
Clemm, A., "Subscribing to datastore push updates", July
2015, <https://tools.ietf.org/html/draft-clemm-netconf-
yang-push-01>.
[draft-clemm-mount]
Clemm, Alexander., "Mounting YANG-Defined Information from
Remote Datastores", April 2015, <http://tools.ietf.org/id/
draft-clemm-netmod-mount-03.txt>.
[draft-i2rs-ephemeral]
Haas, J., "I2RS Ephemeral State Requirements", June 2015,
<http://tools.ietf.org/html/
draft-ietf-i2rs-ephemeral-state-00>.
[i2rs-pub-sub-reqts]
Voit, Eric., Clemm, Alexander., and Alberto. Gonzalez
Prieto, "Requirements for Subscription to YANG
Datastores", March 2015, <http://datatracker.ietf.org/doc/
draft-ietf-i2rs-pub-sub-requirements/>.
[OMG-DDS] "Data Distribution Service for Real-time Systems, version
1.2", January 2007, <http://www.omg.org/spec/DDS/1.2/>.
[rfc6020bis]
Bjorklund, Martin., "YANG - A Data Modeling Language for
the Network Configuration Protocol (NETCONF)", May 2015,
<https://tools.ietf.org/html/draft-ietf-netmod-rfc6020bis-
05>.
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8.3. URIs
[1] http://en.wikipedia.org/wiki/ACID
[2] http://robertgreiner.com/2014/08/cap-theorem-revisited/
[3] http://guide.couchdb.org/draft/consistency.html
Authors' Addresses
Eric Voit
Cisco Systems
Email: evoit@cisco.com
Alexander Clemm
Cisco Systems
Email: alex@cisco.com
Sander Mertens
Prismtech
Email: sander.mertens8@gmail.com
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