Applicability of Generalized Multiprotocol Label Switching (GMPLS) User-Network Interface (UNI)
draft-zhang-ccamp-gmpls-uni-app-03
The information below is for an old version of the document.
| Document | Type | Active Internet-Draft (individual) | |
|---|---|---|---|
| Authors | Fatai Zhang , Oscar Gonzalez de Dios , Adrian Farrel , Xian Zhang , Daniele Ceccarelli | ||
| Last updated | 2013-02-21 | ||
| Stream | (None) | ||
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| Stream | Stream state | (No stream defined) | |
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| Send notices to | (None) |
draft-zhang-ccamp-gmpls-uni-app-03
Network Working Group Fatai Zhang
Internet Draft Huawei
Category: Informational O. Gonzalez de Dios
Telefonica Investigacion y Desarrollo
A. Farrel
Old Dog Consulting
Xian Zhang
Huawei
D. Ceccarelli
Ericsson
Expires: August 21, 2013 February 22, 2013
Applicability of Generalized Multiprotocol Label Switching (GMPLS)
User-Network Interface (UNI)
draft-zhang-ccamp-gmpls-uni-app-03.txt
Status of this Memo
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This Internet-Draft will expire on August 21, 2013.
Abstract
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Generalized Multiprotocol Label Switching (GMPLS) defines a set of
protocols for the creation of Label Switched Paths (LSPs) in various
switching technologies. The GMPLS User-Network Interface (UNI) was
developed in RFC4208 in order to be applied to an overlay network
architectural model.
This document examines a number of GMPLS UNI application scenarios.
It shows how techniques developed after the GMPLS UNI can be applied
to automate or enable critical processes for these applications. This
document also suggests simple extensions that could be made to
existing technologies to further enable the UNI and points out some
unresolved issues.
Table of Contents
1. Introduction ................................................ 3
2. UNI Addressing .............................................. 5
3. UNI Auto Discovery .......................................... 6
4. UNI Path Computation......................................... 7
4.1. UNI Link Selection...................................... 8
5. UNI Path Provisioning........................................ 9
5.1. Flat Model ............................................. 9
5.2. Stitching Model........................................ 10
5.3. Session Shuffling Model................................ 11
5.4. Hierarchal Model....................................... 11
6. UNI Recovery ............................................... 12
6.1. End-to-end Recovery.................................... 12
6.1.1. Serial Provisioning of Working and Protection Paths 13
6.1.2. Concurrent Computation of Working and Protection Path14
6.2. Segment Recovery....................................... 14
7. UNI Call ................................................... 15
7.1. Exchange of UNI Link Information ....................... 15
7.2. Control of Call Route.................................. 16
8. UNI Multicast .............................................. 16
8.1. UNI Multicast Connection Model ......................... 17
8.2. UNI Multicast Connection Provisioning .................. 18
9. Security Considerations..................................... 19
10. IANA Considerations........................................ 19
11. Acknowledgments ........................................... 19
12. References ................................................ 20
12.1. Normative References.................................. 20
12.2. Informative References................................ 22
13. Contributors' Address...................................... 23
14. Authors' Addresses ........................................ 23
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1. Introduction
Generalized Multiprotocol Label Switching (GMPLS) [RFC3945] defines a
set of protocols, including Open Shortest Path Fist - Traffic
Engineering (OSPF-TE) [RFC4203] and Resource ReserVation Protocol -
Traffic Engineering (RSVP-TE) [RFC3473], which can be used to create
Label Switched Paths (LSPs) in a number of deployment scenarios with
various transport technologies.
The User-Network Interface (UNI) reference point is defined in the
Automatically Switched Optical Network (ASON) [G.8080]. According to
[G.8080], the UNI may be implemented as a peering between a client-
side entity (UNI-C) and a network-side entity (UNI-N). End-to-end
connectivity between UNI-C nodes is achieved across the core network
by three components: a UNI request from source UNI-C to source UNI-N;
a core network connection from source UNI-N to destination UNI-N; and
a UNI request from destination UNI-N to destination UNI-C.
The GMPLS overlay model, as per [RFC4208], can be applied at the UNI,
as shown in Figure 1.
Overlay Overlay
Network +----------------------------------+ Network
+---------+ | | +---------+
| +----+ | | +-----+ +-----+ +-----+ | | +----+ |
| | | | UNI | | | | | | | | UNI | | | |
| -+ EN1+-+-----+--+ CN1 +----+ CN2 +----+ CN3 +---+-----+-+ EN3+- |
| | | | +--+--+ | | | | | | | | | |
| +----+ | | | +--+--+ +--+--+ +--+--+ | | +----+ |
+---------+ | | | | | | +---------+
| | | | | |
+---------+ | | +--+--+ | +--+--+ | +---------+
| +----+ | | | | | +-------+ | | | +----+ |
| | +-+--+ | | CN4 +---------------+ CN5 | | | | | |
| -+ EN2+-+-----+--+ | | +---+-----+-+ EN4+- |
| | | | UNI | +-----+ +-----+ | UNI | | | |
| +----+ | | | | +----+ |
+---------+ +----------------------------------+ +---------+
Overlay Core Network Overlay
Network Network
Legend: EN - Edge Node
CN - Core Node
Figure 1 - Applying GMPLS overlay model at UNI
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In Figure 1, assume that there is an end-to-end UNI connection
passing through EN1-CN1-CN2-CN3-EN3. For convenience, some terms used
in this document are defined below:
- "source EN" refers to the edge-node which initiates the
connection (i.e., EN1);
"destination EN" refers to the edge-node where the connection is
terminated (i.e., EN3);
- "ingress CN" refers to the core-node to which the source EN is
attached (i.e., CN1);
- "egress CN" refers to the core-node to which the destination EN
is attached (i.e., CN3).
[RFC4208] provides mechanisms for UNI signaling, which are compatible
with GMPLS RSVP-TE signaling ([RFC3471] and [RFC3473]). A single end-
to-end RSVP session between source EN and destination EN is used for
the user connection, just as it would be for connection creation
between two core nodes. However, when considering the isolation of
topology information between the core network and the overlay network,
additional processing of the RSVP-TE Explicit Route Object (ERO) and
Record Route Object (RRO) is required. For example, the ingress CN
should verify the ERO it receives against its topology database and
may enhance it with additional path information before forwarding the
PATH message. And the ingress/egress CN may edit or remove the RRO in
order to hide the path segment used inside the core network from the
EN.
The GMPLS UNI can be used in many application scenarios. For example,
in a multi-layer network [RFC6001] the interface between client layer
node and server layer node can be seen as a UNI. Or, when deploying
VPN services such as Layer One Virtual Private Networks (L1VPNs)
[RFC4847], [RFC5253], users can connect to a service provider network
via a UNI.
This document examines a number of current and future GMPLS
application scenarios. It shows how techniques developed after the
GMPLS UNI can be used to automate or enable critical aspects of these
application scenarios. It points out some potential technology
extensions that could improve UNI operation, and highlights some
unresolved issues.
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2. UNI Addressing
In [RFC4208], the GMPLS overlay model is applied at the UNI reference
point, and it is required that the edge-node and its attached core-
node of the overlay network share the same address space that is used
by GMPLS to signal between the edge-nodes across the core network.
Under this condition, the user connection can be created using a
single end-to-end RSVP session, which is consistent with the RSVP
model. Therefore, RSVP-TE defined in [RFC3473] can be used for
support GMPLS UNI without any extensions.
However, in some deployments of the GMPLS UNI, it is not practical
for the EN and its attached CN to share the same address space. This
can arise if the core and overlay networks were designed and deployed
separately or belong to different carriers. For example, the core
network may use IPv6 addresses, while the overlay network uses IPv4
addresses. Or, since the core network is a closed system, the
assignment of the IP addresses of the CNs may be independent of other
IP addresses outside the core network. This implies that the nodes in
the core network may use addresses which could collide with the edge
nodes in the overlay network.
[RFC4208] does not state how to ensure that an edge-node and its
attached core-node share the same address space. This document
analyzes the addressing deployment scenarios as follows:
1. Overlay network and core network share a common addressing policy.
This might be quite feasible in a multi-layer network operated by
a single carrier.
In this scenario, end-to-end UNI connectivity may use a single
RSVP session, and the core routing information (assuming it is
shared and not stripped for confidentiality reasons) will be
meaningful to the ENs. Note, however, that the overlay model
examined by this document assumes that there is some separation
between the overlay and core networks, and this might mean that
the overlay network is not able to see the topology or routing
information of the core network even when they share a common
address space.
2. ENs have visibility into the core network, but overlay and core
networks have different address spaces. This is the more common
model envisaged by [RFC4208] and for basic mode L1VPN deployments
[RFC5251]. The previous scenario can be seen to be a special case
of this scenario where the two address spaces are complementary.
In this deployment the ENs each have two addresses: one in the
overlay network and one in the core network. The source EN is
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aware of the addresses for itself, the ingress CN, the egress CN,
and the destination EN in the address space of the core network.
It may also have full visibility into the core network, but this
is not a requirement.
In this scenario, the ENs are responsible for performing address
mapping between the overlay network's addresses for the ENs, and
the core network's addresses for the same nodes and/or its TE
links. A typical deployment may assign addresses in the core
network address space for the EN and/or its TE links at the EN
side, so that EN can use these addresses to communicate with the
core network for UNI connection provisioning.
In this deployment, a single end-to-end RSVP-TE session can still
be utilized from the source EN to the destination EN using
addressing and naming from the core network's address space.
3. ENs do not have any knowledge of the core address space, or do not
support the address space the core network uses (e.g., ENs do not
support IPv6 that is used by the core network). ENs will have no
visibility into the core network.
In this scenario, the ingress CN is responsible for mapping
addresses to the core address space and filling in any additional
routing information. A typical deployment is to assign addresses
in the overlay address space for the ingress CN and/or its TE
links at the CN side, so that the EN can use overlay addresses to
reach the ingress CN and to identify the destination EN.
In this deployment the end-to-end connectivity must be created
either using "session stitching" (see Section 5.2) or "session
shuffling" (see Section 5.3).
3. UNI Auto Discovery
When the end-to-end connection is set up across the core network, it
must be targeted at the destination CN so that it can be extended to
the destination EN. This means that either the source EN must know
the identity of the destination CN to which the destination EN is
attached, or the source CN must know this information. This requires
some form of "discovery" (possibly including configuration), and
depending on the addressing scheme in use (see Section 2), address
mapping needs to be performed by the source EN or the source CN.
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The discovery problem may be exacerbated when a variety of services
are requested since the source EN will need to know the capabilities
and available resources on the link between the destination CN and
the destination EN. It could discover this by attempting to set up a
connection and by drawing conclusions from connection setup failures,
but this is not efficient. Furthermore, in the case of a dual-homed
destination EN (such as EN2 in Figure 1), a choice of destination CN
must be made, and that choice may be influenced by the capabilities
and available resources on the CN-EN links leading to the destination
EN.
If the UNI is applied in an L1VPN scenario, two mechanisms for auto
discovery have been defined. Auto discovery of UNI using OSPFv2 is
provided in [RFC5252] using an L1VPN LSA to advertise the L1VPN
information via the L1VPN info TLV and the TE information of the CE-
PE link (in the language of UNI, it's the EN-CN link) via the TE link
TLV. Auto discovery of UNI using BGP is provided in [RFC5195] by
having each edge CN advertise to other edge CN the following
information, at a minimum: its own IP address and the list of
<private address, provider address> tuples local to that PE. Once
that information is received, the remote PEs will identify the list
of VPN members they have in common with the advertising PE, and use
the information carried within the discovery mechanism to perform
address resolution during the signaling phase of Layer-1 VPN
connections.
4. UNI Path Computation
End-to-end UNI path computation includes three parts: the selection
of the source UNI link, the path computation inside the core network
and the selection of the destination UNI link.
The selection of UNI links may not be necessary in all scenarios. One
example is in the case of single-homing with only one UNI link
between EN and CN. Another example is manual selection of the UNI
link when the service is requested (i.e., as a function of the
service request such as the port mapping used in a L1VPN). In such
cases, the CN to which the source EN is attached, or the path
Computation Element (PCE) ([RFC4655]) which is responsible for the
core network, can perform the path computation across the core
network when the UNI signaling request is sent from the source EN to
the source CN.
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4.1. UNI Link Selection
This document is specific to the overlay architectural model, and
that means that the source EN does not have the topology and TE
information of the core network. Therefore, in the case of multi-
homing (i.e., the source EN is connected to more than one CN), the
source EN does not have enough information to make a correct choice
among all the UNI links between itself and the core network for an
optimal end-to-end connection.
In this case, a PCE whose computation domain covers both the core
network and the ENs attached to it can be used. Note that the GMPLS
UNI predates PCE and hence a PCE was not available in early GMPLS UNI
deployments. A PCE that has the topology and TE information of the
core network can use the UNI discovery mechanism described in Section
3 to learn the EN-CN relationship and the TE information of the UNI
links, and therefore has the ability to select the optimal UNI link
for the connection.
Figure 2 shows the procedures for UNI path computation using a single
PCE with visibility into the core network and information about all
of the CN-EN links. When the UNI path computation request is received,
the PCE can help the source EN to compute the end-to-end route of the
UNI connection based on routing information it has accesses to, so
that the source EN can create the UNI connection using the optimal
UNI link. As shown in Figure 2, the following steps are carried out:
Step 1: EN1 requests a path from EN1 to EN2 by sending a PCReg
message to the PCE;
Step 2: The PCE computes a path based on its view of the core network
and knowledge of all the EN-CN links. In this case, it returns the
path En1-CN4-CN5-Cn6-EN2 to the EN1 node;
Step 3: EN1 starts the signaling process to set up the LSP by using s
standard RSVP signaling process, using the path information as
computed.
If confidentiality of the topology within the core network needs to
be preserved, the Path Key Subobject (PKS) can be used for either
approach outlined here (see [RFC5520] and [RFC5553]). In the PCRep
message returned to EN1, the Confidential Path Segment (CPS) (i.e.,
CN4-CN5-CN6) is encoded as a PKS by the PCE. Therefore, EN1 only
learns the selected UNI link from the PCE. When CN4 receives the UNI
signaling message from EN1 carrying the PKS, CN4 asks the PCE to
decode the PKS and then continues to signal the LSP.
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1) PCReq: EN1-EN2 +-----+
+------------------------>| |
| | PCE |
| +----------------------| |
| | +-----+
| | 2) PCRep: EN1-CN4-CN5-CN6-EN2
| |
| | +----------------------------------+
| | | Core Network |
| | | +----+ +----+ +----+ |
| V +----+--+ CN1+------+ CN2+------+ CN3+--+----+
+----+ | | +--+-+ +--+-+ +--+-+ | | +----+
| +--+ | | | | | +--+ |
| EN1| UNI | | | | | UNI | EN2|
| +--+ | | | | | +--+ |
+----+ | | +--+-+ +--+-+ +--+-+ | | +----+
+----+--+ CN4+------+ CN5+------+ CN6+--+----+
---------> | +----+ +----+ +----+ |
3) Signaling +----------------------------------+
Figure 2 - Procedure using a PCE for UNI path computation
Note that in both cases described in this section, the PCE needs to
be visible to the ENs, and there also needs to be a control channel
between the PCE and the ENs for the exchange of PCE Protocol (PCEP)
messages. An alternative implementation could be that a PCE is
located inside each CN to which the source EN is attached, so that
the source EN can use the UNI control channel to send and receive the
PCEP messages.
5. UNI Path Provisioning
The basic GMPLS UNI application is to provide end-to-end connections
between edge-nodes through a core network via the overlay model. This
section briefly describes four ways in which the end-to-end LSP can
be created and operated across the core network.
5.1. Flat Model
In this model, the edge-nodes have the same switching capability as
the nodes in the core network. In this case, one single end-to-end
RSVP session through the edge-nodes and a series of core-nodes can be
used to create the connection, which forms a flat LSP model, as shown
in Figure 3.
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+----------------------------------+
| Core Network |
+----+ UNI | +----+ +----+ +----+ | UNI +----+
| EN +-------+--+ CN +------+ CN +------+ CN +--+-------+ EN |
+----+ | +----+ +----+ +----+ | +----+
| | | |
| +----------------------------------+ |
| |
|<------------- End-to-end RSVP Session -------------->|
| |
Figure 3 - The Flat Model
If the edge-nodes and their attached core-nodes share the same
address space, or the ENs can perform address mapping into the core
network address space, the GMPLS signaling described in [RFC3471],
[RFC3473] and other related specifications, with special ERO and RRO
processing as described in [RFC4208], can be used to create a
connection.
5.2. Stitching Model
The stitching mechanism described in [RFC5150] can be used to create
an LSP segment (S-LSP) between the ingress and the egress CN, and to
stitch the end-to-end UNI connection to the created S-LSP, as shown
in Figure 4.
+----------------------------------+
| Core Network |
+----+ UNI | +----+ +----+ +----+ | UNI +----+
| EN +-------+--+ CN +------+ CN +------+ CN +--+-------+ EN |
+----+ | +----+ +----+ +----+ | +----+
| | | | | |
| +----+------------------------+----+ |
| | | |
| |<-LSP Segment (S-LSP)-->| |
| |
|<------------- End-to-end RSVP Session -------------->|
Figure 4 - The Stitching Model
This model allows the core network a degree of independence so that
the S-LSP can be set up and modified without the knowledge of the
overlay network. Remember that stitching is a data plane function, so
that the EN-CN LSP segments are cross-connected to the S-LSP at the
edge CNs. This means that, just as in Section 5.1, the overlay and
core networks must have the same switching capabilities. However, the
control plane for the stitching model operates just as the
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hierarchical model described in Section 5.4, so the S-LSP appears as
a single hop in the overlay network.
5.3. Session Shuffling Model
The session shuffling approach ([RFC5251]) is a modification of the
flat model described in Section 5.1. In this approach a single end-
to-end session is established, but as the signaling messages pass
through the ingress and egress CNs, address mapping is performed on
all addresses carried by the messages to replace the addresses with
values from the correct address space. The ERO and RRO are stripped
from the messages as previously discussed, so there is no need for
the CNs to examine those objects to map addresses. However, all other
addresses must be mapped including the important session identifiers
(the source and destination addresses). Viewed from the outside
(perhaps through an NMS) this gives the impression of session
stitching because the session has different identifiers as it crosses
the core network. An NMS might, therefore, present the shuffling
model as the stitching model, or it might operate the same address
shuffling/mapping as is used by CNs.
5.4. Hierarchal Model
If the ENs and CNs have the same switching capability, a tunnel
between the ingress and egress core-nodes can be provisioned to carry
the end-to-end connection. The tunnel may have a larger capacity than
the end-to-end UNI connection, depending on the policies configured
at the ingress CN of the core network. The end-to-end connection can
be nested into a tunnel, which forms the LSP hierarchy [RFC4206] as
shown in Figure 5. If the tunnel has a larger capacity, other LSPs
can also be nested within the same tunnel.
Alternatively, if the ENs and CNs have different switching
capabilities the LSP hierarchical model can also be used exactly as
described in [RFC4206].
In the hierarchal model, the end-to-end connection can be divided
into three hops: one for each UNI link and one hop across the core
network. The core network tunnel can be pre-provisioned via network
planning, or triggered by the UNI signalling. For the latter case,
[RFC5212], [RFC6001] and other multi-layer network related
specifications can be used to create the hierarchical LSP.
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+----------------------------------+
| Core Network |
+----+ UNI | +----+ +----+ +----+ | UNI +----+
| EN +-------+--+ CN +======+ CN +======+ CN +--+-------+ EN |
+----+ | +----+ +----+ +----+ | +----+
| | | | | |
| +----+------------------------+----+ |
| | | |
| |<-Core Network Tunnel-->| |
| |
|<------------- End-to-end RSVP Session -------------->|
| |
Figure 5 - The Hierarchal Model
6. UNI Recovery
One of the significant uses of GMPLS is to provide recovery
mechanisms for connections. Recovery and protection mechanisms are
also needed in many UNI scenarios, and the relationship between the
overlay and core network provide obvious places at which to operate
the recovery techniques.
6.1. End-to-end Recovery
In the case of multi-homing, UNI end-to-end recovery is possible. As
shown in Figure 6, the working path (W) and the protection path (P)
are disjoint from each other not only inside the core network, but
also at both the source and destination sides of the UNI. Mechanisms
need to be provided to ensure the selection of disjoint working and
backup paths as discussed in the following subsections.
It should be noted that end-to-end recovery can be operated even when
the ENs are single-homed. However, obviously, in this case there is
no protection against the failure of an EN-CN link, or of the edge CN
itself.
+----------------------------------+
| Core Network |
W | +----+ +----+ +----+ |
+----+--+ CN +------+ CN +------+ CN +--+----+
+----+ | | +----+ +----+ +----+ | | +----+
| +--+ | | +--+ |
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| EN | UNI | | UNI | EN |
| +--+ | | +--+ |
+----+ | | +----+ +----+ +----+ | | +----+
+----+--+ CN +------+ CN +------+ CN +--+----+
P | +----+ +----+ +----+ |
+----------------------------------+
Figure 6 - UNI End-to-End Recovery
6.1.1. Serial Provisioning of Working and Protection Paths
In serial provisioning, one path is computed before another and the
associated LSP may even be set up before the second path is computed.
In the case where the working path is computed and created before the
protection path, path computation for the protection path needs to
select a (maximally) disjoint path given this existing working path.
If the EN is allowed to see details of the core network, the EN can
use the RRO to collect the route of the working path. It can then use
the Exclude Route Object (XRO) to exclude the working path when
signaling the protection path, as described in [RFC4874].
But in most cases, in order to preserve the confidentiality of
topology within the core network, the route of the working path as it
traverses the core network will be hidden from the EN. In such cases,
the RRO and XRO mechanism cannot be used. An alternative would be to
only collect the Shared Risk Group (SRG) information, but not the
full path information. This is because the SRG information is
normally less confidential than the information of node ID and link
ID. Another possible solution is encrypted the SRG information and
provide it to the EN nodes, so that the EN nodes can using this
information to convey the diversity constraint, as the method
specified in [UNIExt].In an application scenario where a PCE is
involved inside the core network, then the Path Key mechanism can be
used. The confidential path segment, i.e., the route of the working
path as it traverses the core network, is encoded as a PKS by the PCE
when computing the working path [RFC5520]. This PKS can be used by
the EN when it requests the PCE to compute a protection path, to
exclude the nodes and links used by the working path. As previously
described, the PKS is also used in signaling [RFC5553] so that the EN
can indicate to the CN what path to use across the core network.
In order to specify the diversity requirement, it is required that
the PKS should be carried in the XRO in both PCEP message and RSVP-TE
signaling.
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6.1.2. Concurrent Computation of Working and Protection Path
The working and protection path can be computed at the same time
(e.g., by PCE or by one of the CNs to which the source EN is
attached).
[PCE-GMPLS] adds support for an end node to request a protected
service using the protection types defined in [RFC4872].Therefore,
it's possible that the source EN requests the edge CN or PCE to
compute both the working and the protection path at the same time. At
this time, the disjunction requirement can be resolved inside the
path computation server.
Same as described in the previous section, the path segment
traversing the core network can be encoded as a PKS if
confidentiality is requested.
6.2. Segment Recovery
The UNI connection may request protection only inside the core
network, especially in case of single-homing. A UNI segment
protection example is shown in Figure 7. In this case, the core
network provides a "recovery domain".
+--------------------------------------+
| Core Network |
| W +----+ +----+ |
| +--+ CN +--+ CN +--+ |
+----+ | +----+ | +----+ +----+ | +----+ | +----+
| | | | +--+ +--+ | | | |
| EN +-----+-+ CN | | CN +-+-----+ EN |
| | UNI | | +--+ +--+ | | UNI | |
+----+ | +----+ | +----+ +----+ | +----+ | +----+
| +--+ CN +--+ CN +--+ |
| P +----+ +----+ |
+--------------------------------------+
Figure 7 - UNI Segment Recovery
[RFC4873] provides a mechanism for segment recovery, in which the
PROTECTION Object is extended to indicate segment recovery, and the
Secondary ERO (SERO) is introduced for the explicit control of the
protection LSP between the branch node and the merge node.
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However, in the overlay model, the mechanisms of segment recovery
described in [RFC4873] may not be appropriate. In particular, the
source EN might not know the CN to which the destination EN is
attached. That means that the source EN knows the branch for the
protection segment, but does not know the merge node.
But the model shown in Figure 7 is particularly important because it
places the responsibility for service delivery with the edge CNs.
This will be a common operational model in overlay networks.
Fortunately the stitching model (Section 5.2) and the hierarchical
model (Section 5.4) are good at providing the necessary protection
within the core network without the ENs having to be aware of the
paths in the core network.
7. UNI Call
The Call is a fundamental component of the ASON model [G.8080]. It is
used to maintain the association between one or more user
applications and the network, and to control the set-up, release,
modification, and maintenance of sets of Connections (LSPs). In
simple cases, the Call and Connection can be established at the same
time and in a strict one-to-one ratio. In this case, Call signaling
requires only minor extensions to connection signaling. However, if
Calls are handled separately from Connections, or if more than one
Connection can be associated with a single Call, additional Call
signaling is required.
The GMPLS Call, defined in [RFC4974], provides a mechanism to
negotiate agreement between endpoints possibly in cooperation with
the nodes that provide access to the network. Typically the GMPLS
Call can be applied in the UNI scenario for access link capability
exchange, policy, authorization, security, and so on.
7.1. Exchange of UNI Link Information
It is possible that the TE attributes of the access link (i.e., the
UNI link) are not shared across the core network. So the source EN
may not have the TE information of the destination access link as
well as the capability of the destination EN. For example, in case of
TDM network, the Virtual Concatenation (VCAT) and Link Capacity
Adjustment Scheme (LCAS) capability of the destination EN may not be
known.
In this case, the source EN can raise a Call carrying the
LINK_CAPABILITY object to have a capability exchange with the
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destination EN, as described in [RFC4974].
7.2. Control of Call Route
When applying the Call, it's possible that there are multiple core
network domains between the source EN (Call initiator) and the
destination EN (Call terminator), or there is more than one Call
manager in the core network (e.g., in the multi-homing scenario where
the CNs to which the ENs are attached act as the Call managers).
In the both cases, when establishing the Call, there may be multiple
alternative routes for the Call message to reach the destination EN.
One can simply use the hop-by-hop manner (i.e., each Call manager
determines the next Call manager to which the Call message will be
sent by itself) to control the path of the Call.
However, in the practical deployment of UNI Call, commercial and
policy motivations normally play an important role in selecting the
Call route, especially in the multi-domain scenario. In this case,
the hop-by-hop manner is not practical because the route of the Call
needs to be pre-determined in consideration of commercial and policy
factors before establishing the Call.
Therefore, it is desirable to allow full control of the Call by the
source EN. That is, the source EN can identify the full Call route
and signal it explicitly, so that the Call message can be forwarded
along the desired route. Moreover, the management plane needs to be
able to identify the Call route explicitly as an instruction to the
source EN.
8. UNI Multicast
Data plane multicasting is supported in existing Traffic-Engineering
networks. GMPLS provides extensions to RSVP-TE to support
provisioning of point-to-multipoint (P2MP) TE LSPs via the control
plane, as described in [RFC4461] and [RFC4875].
In the scenarios where P2MP is supported using the overlay
architectural model, it is a requirement to transport signals from
one source EN to multiple destination ENs. One could create a point-
to-point (P2P) connection between the source EN and each destination
EN, but it will likely be a waste of bandwidth resource both of the
UNI link and in the core network.
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Therefore, there are some scenarios required to support point-to-
multipoint (P2MP) TE LSPs from one source EN to multiple leaf ENs.
8.1. UNI Multicast Connection Model
There are two cases for the UNI multicast. For the first case, only
the ingress and egress CNs in the core network support P2MP. The core
network has to provide multiple P2P connections between ingress CN
and each egress CN for the end-to-end UNI multicast, as shown in
Figure 8. This relieves the pressure on the source UNI link, but does
not help the over use of the core links such as CN1-CN2.
+----------------------------------------+
| Core Network |
| +-----+ +-----+ +-----+ |UNI +---+
+---+ UNI| | +--------+-----+-------+ +--+----+EN2|
|EN1+----+--+ CN1 +--------+-\CN2| | CN3 | | +---+
+---+ | | +--------+\ \ | | | | Leaf A
Source | +-----+ +-+-+-+ +-----+ |
| | | |
| +-+-+-+ +-----+ |UNI +---+
| | | \+-------+ +--+----+EN3|
| | |CN4| | CN5 | | +---+
| +-+---+ +-----+ | Leaf B
| | |
| +-+---+ +-----+ |UNI +---+
| | \---+-------+ +--+----+EN4|
| | CN6 | | CN7 | | +---+
| +-----+ +-----+ | Leaf C
+----------------------------------------+
Figure 8 - Only ingress/egress CNs support multicast
For example, in multi-layer scenario of a packet overlay network with
a TDM core, the ingress/egress CNs may have packet multicast
capabilities and therefore can adapt the packets from EN into
multiple TDM connections to transit the core network, but the CNs
inside the core network only support point-to-point (P2P) TDM
connections.
In another case, all the CNs in the core network can support
multicast, so that the core network can create a P2MP LSP to provide
the end-to-end UNI multicast, as shown in Figure 9.
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+----------------------------------------+
| Core Network |
| +-----+ +-----+ +-----+ |UNI +---+
+---+ UNI| | +--------+-+-->+-------+ +--+----+EN2|
|EN1+----+--+ CN1 | | |CN2| | CN3 | | +---+
+---+ | +-----+ +-V---+ +-----+ | Leaf A
Source | | |
| +-+---+ +-----+ |UNI +---+
| | +-->+-------+ +--+----+EN3|
| | |CN4| | CN5 | | +---+
| +-V---+ +-----+ | Leaf B
| | |
| +-+---+ +-----+ |UNI +---+
| | \-->+-------+ +--+----+EN4|
| | CN6 | | CN7 | | +---+
| +-----+ +-----+ | Leaf C
+----------------------------------------+
Figure 9 - All CNs support multicast
For example, in the Ethernet over OTN scenario, if the core network
can support ODU0 multicast, then an ODU0 P2MP LSP can be created
inside the core network to carry the client Gigabit Ethernet (GE)
signal for the ENs.
Note that the branching of the P2MP connection could also happen at
the source EN if the EN is multi-homed. In this case, each branch
from the source EN uses a separate UNI link connecting the source EN
to the core network. For each UNI branch, the connection model inside
the core network is the same as described in this section.
8.2. UNI Multicast Connection Provisioning
The four UNI connection provisioning models, as described in Section
5, should also be applied in the UNI multicast scenario.
For the flat model, one end-to-end P2MP session as described in
[RFC4875] can be used to create the P2MP LSP from source EN to leaf
ENs.
For the stitching model, multiple P2P LSP segments or one P2MP LSP
segment between the ingress CN and each egress CNs needs to be
created and then stitched to the UNI P2MP LSP. GMPLS UNI signaling
should have the capability to convey the multicast information by
using stitching model.
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For the session shuffling model, one end-to-end P2MP session can be
used to create the P2MP LSP, with an address mapping performed at
both ingress and egress CNs.
For the hierarchical model, multiple P2P LSP tunnels or one P2MP LSP
tunnel between the ingress CN and each egress CNs needs be triggered
by the UNI signaling for creating the P2MP LSP. GMPLS UNI signaling
should have the capability to convey the multicast information by
using the hierarchical model.
9. Security Considerations
[RFC5920] provides an overview of security vulnerabilities and
protection mechanisms for the GMPLS control plane, which is
applicable to this document.
The details of the specific security measures of the overlay network
architectural model are provided in [RFC4208], which permits the core
network to filter out specific RSVP objects to hide its topology from
the EN.
Furthermore, if PCE is used, the security issues described in
[RFC4655] should also be considered.
Additionally, when the PKS mechanism is applied, the security issues
can be dealt with using [RFC5520] and [RFC5553].
10. IANA Considerations
This informational document does not make any requests for IANA
action.
11. Acknowledgments
TBD.
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12. References
12.1. Normative References
[RFC3209] D. Awduche et al, "RSVP-TE: Extensions to RSVP for LSP
Tunnels", RFC3209, December 2001.
[RFC3471] Berger, L., Ed., "Generalized Multi-Protocol Label
Switching (GMPLS) Signaling Functional Description", RFC
3471, January 2003.
[RFC3473] L. Berger, Ed., "Generalized Multi-Protocol Label
Switching (GMPLS) Signaling Resource ReserVation
Protocol-Traffic Engineering (RSVP-TE) Extensions", RFC
3473, January 2003.
[RFC3945] Mannie, E., "Generalized Multi-Protocol Label Switching
(GMPLS) Architecture", RFC 3945, October 2004.
[RFC4203] Kompella, K., and Rekhter, Y., "OSPF Extensions in
Support of Generalized Multi-Protocol Label Switching
(GMPLS)", RFC 4203, October 2005.
[RFC4206] K. Kompella et al, "Label Switched Paths (LSP) Hierarchy
with Generalized Multi-Protocol Label Switching (GMPLS)
Traffic Engineering (TE)", RFC4206, October 2005.
[RFC4208] G. Swallow et al, "Generalized Multiprotocol Label
Switching (GMPLS) User-Network Interface (UNI): Resource
ReserVation Protocol-Traffic Engineering (RSVP-TE)
Support for the Overlay Model", RFC4208, October 2005.
[RFC4655] A. Farrel et al, "A Path Computation Element (PCE)-Based
Architecture", RFC4655, August 2006.
[RFC4847] T. Takeda, Ed., "Framework and Requirements for Layer 1
Virtual Private Networks", RFC4847, April 2007.
[RFC4872] J.P. Lang et al, "RSVP-TE Extensions in Support of End-
to-End Generalized Multi-Protocol Label Switching (GMPLS)
Recovery", RFC4872, May 2007.
[RFC4873] L. Berger et al, "GMPLS Segment Recovery", RFC4873, May
2007.
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[RFC4874] CY. Lee et al, "Exclude Routes - Extension to Resource
ReserVation Protocol-Traffic Engineering (RSVP-TE)",
RFC4874, April 2007.
[RFC4875] R. Aggarwal et al, "Extensions to Resource Reservation
Protocol - Traffic Engineering (RSVP-TE) for Point-to-
Multipoint TE Label Switched Paths (LSPs)", RFC4875, May
2007.
[RFC4974] D. Papadimitriou and A. Farrel, Ed., "Generalized MPLS
(GMPLS) RSVP-TE Signaling Extensions in Support of Calls",
RFC4974, August 2007.
[RFC5150] A. Ayyangar et al, "Label Switched Path Stitching with
Generalized Multiprotocol Label Switching Traffic
Engineering (GMPLS TE)", RFC5150, February 2008.
[RFC5195] Ould-Brahim, H., Fedyk, D., and Y. Rekhter, "BGP-Based
Auto-Discovery for Layer-1 VPNs", RFC 5195, June 2008.
[RFC5251] D. Fedyk and Y. Rekhter, Ed., "Layer 1 VPN Basic Mode",
RFC5251, July 2008.
[RFC5252] I. Bryskin and L. Berger Ed., "OSPF-Based Layer 1 VPN
Auto-Discovery", RFC5252, July 2008.
[RFC5520] R. Bradford, Ed., "Preserving Topology Confidentiality in
Inter-Domain Path Computation Using a Path-Key-Based
Mechanism", RFC5520, April 2009.
[RFC5553] A. Farrel, Ed., "Resource Reservation Protocol (RSVP)
Extensions for Path Key Support", RFC5553, May 2009.
[RFC6001] Dimitri Papadimitriou et al, "Generalized Multi-Protocol
Label Switching (GMPLS) Protocol Extensions for Multi-
Layer and Multi-Region Networks (MLN/MRN)", RFC6001,
October, 2010.
[RFC6107] K. Shiomoto, A. Farrel, "Procedures for Dynamically
Signaled Hierarchical Label Switched Paths", RFC6107,
February 2011.
[G.8080] ITU-T Rec. G.8080/Y.1304, "Architecture for the
Automatically Switched Optical Network (ASON)," June 2006
(and Amend.2, September 2010).
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12.2. Informative References
[RFC4461] S. Yasukawa, Ed., "Signaling Requirements for Point-to-
Multipoint Traffic-Engineered MPLS Label Switched Paths
(LSPs)", RFC4461, April 2006.
[RFC5212] K. Shiomoto et al, "Requirements for GMPLS-Based Multi-
Region and Multi-Layer Networks (MRN/MLN)", RFC5212, July
2008.
[RFC5253] T. Takeda, Ed., "Applicability Statement for Layer 1
Virtual Private Network (L1VPN) Basic Mode", RFC 5253,
July 2008.
[RFC5339] JL. Le Roux et al, "Evaluation of Existing GMPLS
Protocols against Multi-Layer and Multi-Region Networks
(MLN/MRN)", RFC5339, September 2008.
[RFC5441] JP. Vasseur et al, "A Backward-Recursive PCE-Based
Computation (BRPC) Procedure to Compute Shortest
Constrained Inter-Domain Traffic Engineering Label
Switched Paths", RFC5441, April 2009.
[RFC5623] Oki, E., Takeda, T., Le Roux, J.L., and Farrel, A.,
"Framework for PCE-Based Inter-Layer MPLS and GMPLS
Traffic Engineering", RFC 5623, September 2009.
[RFC5920] L. Fang, Ed., "Security Framework for MPLS and GMPLS
Networks", RFC5920, July 2010.
[Call-ext] Fatai Zhang et al, "RSVP-TE extensions to GMPLS Calls",
draft-zhang-ccamp-gmpls-call-extensions-01.txt, July 08,
2009.
[PCE-GMPLS] C. Margaria et al, "PCEP extensions for GMPLS", draft-
ietf-pce-gmpls-pcep-extensions-07.txt, October 21, 2012.
[SRLG-FA] Fatai Zhang et al, "RSVP-TE Extensions for Configuration
SRLG of an FA", draft-ietf-ccamp-rsvp-te-srlg-collect-
01.txt, October 22, 2012.
[RFC6344] G. Bernstein et al, "Operating Virtual Concatenation
(VCAT) and the Link Capacity Adjustment Scheme (LCAS)
with Generalized Multi-Protocol Label Switching (GMPLS)",
RFC6344, August 2011.
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[UNIExt] D. Fedyk, D. Beller, Lieven Levrau, D. Ceccarelli, F. Zhang,
et al, "UNI Extensions for Diversity and Latency Support",
draft-fedyk-ccamp-uni-extensions-00.txt, Feb. 2013;
13. Contributors' Address
Yi Lin
Huawei Technologies
F3-5-B R&D Center, Huawei Base
Bantian, Longgang District
Shenzhen 518129 P.R.China
Phone: +86-755-28972914
Email: yi.lin@huawei.com
Young Lee
Huawei Technologies
1700 Alma Drive, Suite 100
Plano, TX 75075
USA
Phone: (972) 509-5599 (x2240)
Email: leeyoung@huawei.com
Dan Li
Huawei Technologies
F3-5-B R&D Center, Huawei Base
Bantian, Longgang District
Shenzhen 518129 P.R.China
Phone: +86-755-28973237
Email: huawei.danli@huawei.com
14. Authors' Addresses
Fatai Zhang
Huawei Technologies
F3-5-B R&D Center, Huawei Base
Bantian, Longgang District
Shenzhen 518129 P.R.China
Phone: +86-755-28972912
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Email: zhangfatai@huawei.com
Oscar Gonzalez de Dios
Telefonica Investigacion y Desarrollo
Emilio Vargas 6
Madrid, 28045
Spain
Phone: +34 913374013
Email: ogondio@tid.es
Adrian Farrel
Old Dog Consulting
EMail: adrian@olddog.co.uk
Xian Zhang
Huawei Technologies
F3-5-B R&D Center, Huawei Base
Bantian, Longgang District
Shenzhen 518129 P.R.China
Phone: +86-755-28972913
Email: zhang.xian@huawei.com
Daniele Ceccarelli
Ericsson
Via A. Negrone 1/A
Genova - Sestri Ponente
Italy
Email: daniele.ceccarelli@ericsson.com
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