One document matched: draft-abfb-mpls-tp-control-plane-framework-01.txt
Differences from draft-abfb-mpls-tp-control-plane-framework-00.txt
Internet Draft Loa Andersson, Ed. (Acreo AB)
Category: Informational Lou Berger, Ed. (LabN)
Expiration Date: January 13, 2010 Luyuan Fang, Ed. (Cisco)
Nabil Bitar, Ed. (Verizon)
July 13, 2009
MPLS-TP Control Plane Framework
draft-abfb-mpls-tp-control-plane-framework-01.txt
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Abstract
The MPLS Transport Profile (MPLS-TP) supports both static
provisioning of transport paths via an NMS/OSS, and dynamic
provisioning of transport paths via a control plane. This document
provides the framework for MPLS-TP dynamic provisioning, and covers
control plane signaling, routing, addressing, traffic engineering,
path computation, and recovery in the event of network failures. The
document focuses on the control of Label Switched Paths (LSPs) as the
Pseudowire (PW) control plane is not modified by MPLS-TP. MPLS-TP
uses GMPLS as the control plane for MPLS-TP LSPs. Backwards
compatibility to MPLS is required. Management plane functions such as
manual configuration, the initiation of LSP setup are out of scope of
this document.
Table of Contents
1 Introduction ........................................... 3
1.1 Conventions Used In This Document ...................... 3
1.2 Scope .................................................. 3
1.3 Basic Approach ......................................... 4
1.4 Reference Model ........................................ 5
2 Control plane requirements ............................. 8
2.1 Primary Requirements ................................... 8
2.2 MPLS-TP Framework Derived Requirements ................. 16
2.3 OAM Framework Derived Requirements ..................... 17
2.4 Security Requirements .................................. 19
3 Relationship of PWs and TE LSPs ........................ 19
4 TE LSPs ................................................ 19
4.1 General reuse of existing GMPLS control plane mechanisms ...19
4.1.1 In-Band and Out-Of-Band ................................ 20
4.1.2 Addressing ............................................. 21
4.2 Signaling .............................................. 21
4.3 Routing ................................................ 22
4.3.1 ISIS-TE/OSPF-TE routing in support of MPLS-TP .......... 23
4.3.2 TE link bundling ....................................... 25
4.4 OAM, MEP (hierarchy) configuration & control ........... 25
4.5 Traffic engineering and constraint-based path computation ..25
4.5.1 Relation to PCE ........................................ 26
4.6 Applicability .......................................... 26
4.7 Recovery ............................................... 26
4.7.1 E2E, segment ........................................... 26
4.7.2 P2P, P2MP .............................................. 27
4.7.3 Recovery Triggers ...................................... 27
4.8 Diffserv object usage in GMPLS (E-LSPs, L-LSPs) ........ 27
4.9 Management plane support ............................... 27
4.9.1 Management Plane / Control Plane Ownership Transfer .... 27
4.10 CP reference points (E-NNI, I-NNI, UNI) ................ 28
4.11 MPLS to MPLS-TP interworking ........................... 28
5 Pseudo Wires ........................................... 28
5.1 General reuse of existing PW control plane mechanisms .. 31
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5.2 Signaling .............................................. 31
5.3 Recovery (Redundancy) .................................. 31
6 Security Considerations ................................ 31
7 IANA Considerations .................................... 31
8 Acknowledgments ........................................ 31
9 References ............................................. 32
9.1 Normative References ................................... 32
9.2 Informative References ................................. 34
10 Authors' Addresses ..................................... 36
1. Introduction
The MPLS Transport Profile (MPLS-TP) is being defined in a joint
effort between the International Telecommunications Union (ITU) and
the IETF. The requirements for MPLS-TP are defined in the
requirements document, see [TP-REQ]. These requirements state that
"A solution MUST be provided to support dynamic provisioning of MPLS-
TP transport paths via a control plane." This document provides the
framework for such dynamic provisioning.
1.1. Conventions Used In This Document
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 [RFC2119].
1.2. Scope
This document covers control plane related topics for MPLS-TP Label
Switched Paths (LSPs) and Pseudowire (PW). The control plane
requirements for MPLS-TP are defined in [TP-REQ]. These requirements
defined the role of the control plane in MPLS-TP. In particular,
Sections 2.4 and portions of the remainder of Section 2 of [TP-REQ]
provide specific control plane requirements.
The LSPs provided by MPLS-TP are used as a server layer for IP, MPLS
and PWs, as well as other tunneled MPLS-TP LSPs. The PWs are used to
carry client signal other than IP and MPLS. The relationship between
pseudo wires and MPLS-TP LSPs is exactly the same as between pseudo
wires and MPLS LSPs in a Packet switched network (PSN). The PW
encapsulation over MPLS-TP LSPs used in MPLS-TP networks is the same
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as for PWs over MPLS in an MPLS network. MPLS-TP also defines
protection and restoration (or, collectively, recovery) functions.
The MPLS-TP control plane provides methods to establish, remove and
control MPLS-TP LSP and PW functions. This includes control of data
plane, OAM and recovery functions.
A general framework for MPLS-TP has been defined in [TP-FWK], and a
survivability framework for MPLS-TP has been defined in [TP-SURVIVE].
These document scope the approaches and protocols that will be used
as the foundation for MPLS-TP. Notably, Section 3.5 of [TP-FWK]
scopes the IETF protocols that serve as the foundation of the MPLS-TP
control plane. The PW control plane is based on the existing PW
control plane, see [RFC4447], and the PW end-to-end (PWE3)
architecture, see [RFC3985]. The LSP control plane is based on
Generalized MPLS (GMPLS), see [RFC3945], which is built on MPLS-TE
and its numerous extensions. [TP-SURVIVE] focuses on LSPs, and the
protection functions that must be supported within MPLS-TP. It does
not specify which control plane mechanisms are to be used.
This document discusses the impact of MPLS-TP requirements on the
signaling that is used to provision pseudo wires as specified in
RFC4447. This document also discusses the impact of the MPLS-TP
requirements on the GMPLS signaling and routing protocols that is
used to provision MPLS-TP LSPs.
1.3. Basic Approach
The basic approach taken in defining the MPLS-TP Control Plane
framework is:
1) MPLS technology as defined by the IETF is the foundation for
the MPLS Transport Profile. [Editor's note: should also be in
primary TP documents.]
2) The data plane for MPLS and MPLS-TP is identical, i.e. any
extensions defined for MPLS-TP is also applicable to MPLS. And
the same encapsulation used for MPLS over any layer 2 network
is also used for MPLS-TP. [Editor's note: should also be in
primary TP documents.]
3) MPLS PWs are used as-is by MPLS-TP including the use of
targeted-LDP for PW signaling [RFC4447], OSPF-TE, ISIS-TE or
MP-BGP as they apply for Multi-Segment(MS)-PW routing. However,
the PW can be encapsulated over an MPLS-TP LSP in (established
using methods and procedures for MPLS-TP LSP establishment) in
addition to the presently defined methods of carrying PWs over
packet switched networks (PSNs). That is, the MPLS-TP domain is
a packet switched network from PWE3 architecture aspect
[RFC3985].
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4) The MPLS-TP LSP control plane builds on the GMPLS control plane
as defined by the IETF for transport LSPs, the protocols within
scope are RSVP-TE [RFC3473], OSPF-TE [RFC4203][RFC5392], and
ISIS-TE [RFC5307][RFC5316]. ASON/ASTN signaling and routing
requirements in the context of GMPLS can be found in [RFC4139]
and [RFC4258].
5) Existing IETF MPLS and GMPLS RFCs and evolving Working Group
Internet-Drafts should be reused wherever possible.
6) If needed, extensions for the MPLS-TP control plane should
first based on the existing and evolving IETF work, secondly
based on work by other Standard bodies only when IETF decides
that the work is out of IETF scope. New extensions may be
defined otherwise.
7) Extensions to the GMPLS control plane may be required in order
to fully automate MPLS-TP functions.
8) Control-plane software upgrades to existing equipment running
MPLS is acceptable and expected.
9) It is permissible for functions present in the GMPLS control
plane not to be used in MPLS-TP networks, e.g. the possibility
to merge LSPs.
10) One possible use of the control plane is to configure, enable
and empower OAM functionality; this will require extensions to
existing control plane specifications.
11) MPLS-TP requirements are primarily defined in Section 2.4 and
relevant portions of the remainder Section 2 of [TP-REQ].
1.4. Reference Model
The control plane reference model is based on the general MPLS-TP
reference model as defined in MPLS-TP framework [TP-FWK]. Per MPLS-TP
framework [TP-FWK], MPLS-TP control plane is based on GMPLS with
RSVP-TE for LSP signaling and LDP for PW signaling. In both cases,
OSPF-TE or ISIS-TE with GMPLS extensions is used for dynamic routing.
From a service perspective, client interfaces are provided for both
the PWs and LSPs. PW client interfaces are defined on an interface
technology basis, e.g., Ethernet over PW [RFC4448]. In the context of
MPLS-TP LSP, the client interface is expected to be provided via a
UNI, [RFC4208]. As discussed in [TP-FWK], MPLS-TP also presumes an
LSP NNI reference point.
The MPLS-TP end-to-end control plane reference model is shown in
Figure 1. It shows the control plane protocols used by MPLS-TP, as
well as the UNI and NNI reference points. [Editor's note: need to
add more explanatory text.]
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|< ---- client signal (IP / MPLS / L2 / PW) ------------ >|
|< --------- SP1 ----------- >|< ------- SP2 ------- >|
|< ---------- MPLS-TP End to End PW ------------ >|
|< -------- MPLS-TP End to End LSP --------- >|
+---+ +---+ +---+ +---+ +---+ +---+ +---+ +---+ +---+
|CE1|-|-|PE1|--|P1 |--|P2 |--|PE2|-|-|PEa|--|Pa |--|PEb|-|-|CE2|
+---+ +---+ +---+ +---+ +---+ +---+ +---+ +---+ +---+
UNI NNI UNI
TE-RTG |< ---------------- >|< --- >|< ---------- >|
RSVP-TE
LDP |< --------------------------------------- >|
Figure 1. End-to-End MPLS-TP Control Plane Reference Model
Legend:
CE: Customer Edge
Client signal: defined in MPLS-TP Requirements
L2: Any layer 2 signal that may be carried
over a PW, e.g. Ethernet.
NNI: Network to Network Interface
PE: Provider Edge
SP: Service Provider
TE-RTG: OSPF-TE or ISIS-TE
UNI: User to Network Interface
Figure 2 adds three hierarchical LSP segments, labeled as "H- LSPs".
These segments are present to support OAM and MEPs within each
provider and across the inter-provider NNI. The MEPs are used to
collect performance information and support OAM triggered
survivability schemes as discussed in [TP-SURVIVE], and each H-LSP
may be protected using any of the schemes discussed in [TP-SURVIVE].
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|< ------- client signal (IP / MPLS / L2 / PW) ------ >|
|< -------- SP1 ----------- >|< ------- SP2 ----- >|
|< ----------- MPLS-TP End to End PW -------- >|
|< ------- MPLS-TP End to End LSP ------- >|
|< -- H-LSP1 ---- >|<-H-LSP2->|<- H-LSP3 ->|
+---+ +---+ +---+ +---+ +---+ +---+ +---+ +---+ +---+
|CE1|-|-|PE1|--|P1 |--|P2 |--|PE2|-|-|PEa|--|Pa |--|PEb|-|-|CE2|
+---+ +---+ +---+ +---+ +---+ +---+ +---+ +---+ +---+
UNI NNI UNI
..... ..... ..... ......... ......... ..... .....
|MEP|-|MIP|-|MIP|-|MEP|MEP|-|MEP|MEP|-|MIP|-|MEP|
''''' ''''' ''''' ''''''''' ''''''''' ''''' '''''
TE-RTG |< -- >|< -- >|< -- >||< -- >||< -- >|< -- >|
RSVP-TE (within the MPLS-TP domain)
TE-RTG |< ---------------- >|< ---- >|< --------- >|
RSVP-TE
LDP |< --------------------------------------- >|
Figure 2. MPLS-TP Control Plane Reference Model with OAM
Legend:
CE: Customer Edge
Client signal: defined in MPLS-TP Requirements
L2: Any layer 2 signal that may be carried
over a PW, e.g. Ethernet.
H-LSP: Hierarchical LSP
MEP: Maintenance end points
MIP: Maintenance intermediate points
NNI: Network to Network Interface
PE: Provider Edge
SP: Service Provider
TE-RTG: OSPF-TE or ISIS-TE
While not shown in the Figures above, it is worth noting that the
MPLS-TP control plane must support the addressing separation and
independence between the data, control and management planes as shown
in Figure 3 of [TP-FWK]. Address separation between the planes is
already included in GMPLS.
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2. Control plane requirements
The requirements for the MPLS-TP control plane are derived from the
MPLS-TP requirements and framework documents, specifically [TP-REQ],
[TP-FWK], [TP-OAM-REQ], [TP-OAM], and [TP-SURVIVE]. The requirements
are summarized in this section, but do not replace those documents.
If there are differences between this section and those documents,
those documents shall be considered authoritative.
2.1. Primary Requirements
These requirements are based on Section 2 [TP-REQ]:
1. Any new functionality that is defined to fulfill the
requirements for MPLS-TP must be agreed within the IETF through
the IETF consensus process as per [RFC4929].
2. The MPLS-TP control plane design should as far as reasonably
possible re-use existing MPLS standards.
3. The MPLS-TP control plane must be able to interoperate with
existing IETF MPLS and PWE3 control planes where appropriate.
4. The MPLS-TP control plane must be sufficiently well-defined
that interworking equipment supplied by multiple vendors will
be possible both within a single domain, and between domains.
5. The MPLS-TP control plane must support a connection- oriented
packet switching model with traffic engineering capabilities
that allow deterministic control of the use of network
resources.
6. The MPLS-TP control plane must support traffic engineered
point-to-point (P2P) and point-to-multipoint (P2MP) transport
paths.
7. The MPLS-TP control plane must support unidirectional,
associated bidirectional and co-routed bidirectional point-to-
point transport paths.
8. The MPLS-TP control plane must support unidirectional point-to-
multipoint transport paths.
9. All nodes (i.e., ingress, egress and intermediate) must be
aware about the pairing relationship of the forward and the
backward directions belonging to the same co-routed
bidirectional transport path.
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10. Edge nodes (i.e., ingress and egress) must be aware about the
pairing relationship of the forward and the backward directions
belonging to the same associated bidirectional transport path.
11. Transit nodes should be aware about the pairing relationship of
the forward and the backward directions belonging to the same
associated bidirectional transport path.
12. The MPLS-TP control plane must support bidirectional transport
paths with symmetric bandwidth requirements, i.e. the amount of
reserved bandwidth is the same in the forward and backward
directions.
13. The MPLS-TP control plane must support bidirectional transport
paths with asymmetric bandwidth requirements, i.e. the amount
of reserved bandwidth differs in the forward and backward
directions.
14. The MPLS-TP control plane must support the logical separation
of the control and management planes from the data plane.
15. The MPLS-TP control plane must support the physical separation
of the control and management planes from the data plane.
16. A control plane must be defined to support dynamic provisioning
and restoration of MPLS-TP transport paths, but its use is a
network operator's choice.
17. A control plane must not be required to support the static
provisioning of MPLS-TP transport paths.
18. The MPLS-TP control plane must permit the co-existence of
statically and dynamically provisioned/managed MPLS-TP
transport paths within the same layer network or domain.
19. The MPLS-TP control plane should be operable in a way that is
similar to the way the control plane operates in other
transport layer technologies.
20. The MPLS-TP control plane must avoid or minimize traffic impact
(e.g. packet delay, reordering and loss) during network
reconfiguration.
21. The MPLS-TP control plane must work across multiple homogeneous
domains.
22. The MPLS-TP control plane should work across multiple non-
homogeneous domains.
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23. The MPLS-TP control plane must not dictate any particular
physical or logical topology.
24. The MPLS-TP control plane must include support of ring
topologies which may be deployed with arbitrarily
interconnection, support rings of at least 16 nodes.
25. The MPLS-TP control plane must support scale gracefully to
support a large number of transport paths, nodes and links.
That is it must be able to scale at least as well as control
planes in existing transport technologies with growing and
increasingly complex network topologies as well as with
increasing bandwidth demands, number of customers, and number
of services.
26. The MPLS-TP control plane should not provision transport paths
which contain forwarding loops.
27. The MPLS-TP control plane must support multiple client layers.
(e.g. MPLS-TP, IP, MPLS, Ethernet, ATM, FR, etc.)
28. The MPLS-TP control plane must provide a generic and extensible
solution to support the transport of MPLS-TP transport paths
over one or more server layer networks (such as MPLS-TP,
Ethernet, SONET/SDH, OTN, etc.). Requirements for bandwidth
management within a server layer network are outside the scope
of this document.
29. In an environment where an MPLS-TP layer network is supporting
a client layer network, and the MPLS-TP layer network is
supported by a server layer network then the control plane
operation of the MPLS-TP layer network must be possible without
any dependencies on the server or client layer network.
30. The MPLS-TP control plane must allow for the transport of a
client MPLS or MPLS-TP layer network over a server MPLS or
MPLS-TP layer network.
31. The MPLS-TP control plane must allow the operation the layers
of a multi-layer network that includes an MPLS-TP layer
autonomously.
32. The MPLS-TP control plane must allow the hiding of MPLS-TP
layer network addressing and other information (e.g. topology)
from client layer networks. However, it should be possible, at
the option of the operator, to leak a limited amount of
summarized information (such as SRLGs or reachability) between
layers.
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33. The MPLS-TP control plane must allow for the identification of
a transport path on each link within and at the destination
(egress) of the transport network.
34. The MPLS-TP control plane must allow for P2MP capable server
(sub-)layers.
35. The MPLS-TP control plane must be extensible in order to
accommodate new types of client layer networks and services.
36. The MPLS-TP control plane should support the reserved bandwidth
associated with a transport path to be increased without
impacting the existing traffic on that transport path provided
enough resources are available.
37. The MPLS-TP control plane should support the reserved bandwidth
of a transport path to be decreased without impacting the
existing traffic on that transport path, provided that the
level of existing traffic is smaller than the reserved
bandwidth following the decrease.
38. The MPLS-TP control plane must support an unambiguous and
reliable means of distinguishing users' (client) packets from
MPLS-TP control packets (e.g. control plane, management plane,
OAM and protection switching packets).
39. The control plane for MPLS-TP must fit within the ASON
architecture. The ITU-T has defined an architecture for
Automatically Switched Optical Networks (ASON) in G.8080
[ITU.G8080.2006] and G.8080 Amendment 1 [ITU.G8080.2008]. An
interpretation of the ASON signaling and routing requirements
in the context of GMPLS can be found in [RFC4139] and
[RFC4258].
40. The MPLS-TP control plane must support control plane topology
and data plane topology independence.
41. A failure of the MPLS-TP control plane must not interfere with
the deliver of service or recovery of established transport
paths.
42. The MPLS-TP control plane must be able to operate independent
of any particular client or server layer control plane.
43. The MPLS-TP control plane should support, but not require, an
integrated control plane encompassing MPLS-TP together with its
server and client layer networks when these layer networks
belong to the same administrative domain.
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44. The MPLS-TP control plane must support configuration of
protection functions and any associated maintenance (OAM)
functions.
45. The MPLS-TP control plane must support the configuration and
modification of OAM maintenance points as well as the
activation/deactivation of OAM when the transport path or
transport service is established or modified.
46. The MPLS-TP control plane must capable of restarting and
relearning its previous state without impacting forwarding.
47. The MPLS-TP control plane must provide a mechanism for dynamic
ownership transfer of the control of MPLS-TP transport paths
from the management plane to the control plane and vice versa.
The number of reconfigurations required in the data plane must
be minimized (preferably no data plane reconfiguration will be
required).
48. The MPLS-TP control plane must support protection and
restoration mechanisms, i.e., recovery.
Note that the MPLS-TP Survivability Framework document, [TP-
SURVIVE], provides additional useful information related to
recovery.
49. The MPLS-TP control plane mechanisms should be identical (or as
similar as possible) to those already used in existing
transport networks to simplify implementation and operations.
However, this must not override any other requirement.
50. The MPLS-TP control plane mechanisms used for P2P and P2MP
recovery should be identical to simplify implementation and
operation. However, this must not override any other
requirement.
51. The MPLS-TP control plane must support recovery mechanisms that
are applicable at various levels throughout the network
including support for link, transport path, segment,
concatenated segment and end to end recovery.
52. The MPLS-TP control plane must support recovery paths that meet
the SLA protection objectives of the service. Including:
a. Guarantee 50ms recovery times from the moment of fault
detection in networks with spans less than 1200 km.
b. Protection of up to 100% of the traffic on the protected
path.
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c. Recovery must meet SLA requirements over multiple
domains.
53. The MPLS-TP control plane should support per transport path
Recovery objective.
54. The MPLS-TP control plane must support recovery mechanisms that
are applicable to any topology.
55. The MPLS-TP control plane must operate in synergy with
(including coordination of timing/timer settings) the recovery
mechanisms present in any client or server transport networks
(for example, Ethernet, SDH, OTN, WDM) to avoid race conditions
between the layers.
56. The MPLS-TP control plane must support recovery and reversion
mechanisms that prevent frequent operation of recovery in the
event of an intermittent defect.
57. The MPLS-TP control plane must support revertive and non-
revertive protection behavior.
58. The MPLS-TP control plane must support 1+1 bidirectional
protection for P2P transport paths.
59. The MPLS-TP control plane must support 1+1 unidirectional
protection for P2P transport paths.
60. The MPLS-TP control plane must support 1+1 unidirectional
protection for P2MP transport paths.
61. The MPLS-TP control plane must support the ability to share
protection resources amongst a number of transport paths.
62. The MPLS-TP control plane must support 1:n bidirectional
protection for P2P transport paths, and this should be the
default for 1:n protection.
63. The MPLS-TP control plane must support 1:n unidirectional
protection for P2MP transport paths.
64. The MPLS-TP control plane may support 1:n unidirectional
protection for P2P transport paths.
65. The MPLS-TP control plane may support extra-traffic.
66. The MPLS-TP control plane should support 1:n (including 1:1)
shared mesh recovery.
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67. The MPLS-TP control plane must support sharing of protection
resources such that protection paths that are known not to be
required concurrently can share the same resources.
68. The MPLS-TP control plane must support the sharing of resources
between a restoration transport path and the transport path
being replaced.
69. The MPLS-TP control plane must support restoration priority so
that an implementation can determine the order in which
transport paths should be restored.
70. The MPLS-TP control plane must support preemption priority in
order to allow restoration to displace other transport paths in
the event of resource constraints.
71. The MPLS-TP control plane may support revertive and non-
revertive restoration behavior.
72. The MPLS-TP control plane must support recovery being triggered
by physical (lower) layer fault indications.
73. The MPLS-TP control plane must support recovery being triggered
by OAM.
74. The MPLS-TP control plane must support management plane
recovery triggers (e.g., forced switch, etc.).
75. The MPLS-TP control plane must support the differentiation of
administrative recovery actions from recovery actions initiated
by other triggers.
76. The MPLS-TP control plane should support control plane
restoration triggers (e.g., forced switch, etc.).
77. The MPLS-TP control plane must support priority logic to
negotiate and accommodate coexisting requests (i.e., multiple
requests) for protection switching (e.g., administrative
requests and requests due to link/node failures).
78. The MPLS-TP control plane must support the relationships of
protection paths and protection-to-working paths (sometimes
known as protection groups).
79. The MPLS-TP control plane must support pre-calculation of
recovery paths.
80. The MPLS-TP control plane must support pre-provisioning of
recovery paths.
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81. The MPLS-TP control plane must support the external commands
defined in [RFC4427]. External controls overruled by higher
priority requests (e.g., administrative requests and requests
due to link/node failures) or unable to be signaled to the
remote end (e.g. because of a protection state coordination
fail) must be dropped.
82. The MPLS-TP control plane must permit the testing and
validation of the integrity of the protection/recovery
transport path.
83. The MPLS-TP control plane must permit the testing and
validation of protection/ restoration mechanisms without
triggering the actual protection/restoration.
84. The MPLS-TP control plane must permit the testing and
validation of protection/ restoration mechanisms while the
working path is in service.
85. The MPLS-TP control plane must permit the testing and
validation of protection/ restoration mechanisms while the
working path is out of service.
86. The MPLS-TP control plane must support the establishment and
maintenance of all recovery entities and functions.
87. The MPLS-TP control plane must support signaling of recovery
administrative control.
88. The MPLS-TP control plane must support protection state
coordination (PSC). Since control plane network topology is
independent from the data plane network topology, the PSC
supported by the MPLS-TP control plane may run on resources
different than the data plane resources handled within the
recovery mechanism (e.g. backup).
89. The MPLS-TP control plane may support recovery mechanisms that
are optimized for specific network topologies. These
mechanisms must be interoperable with the mechanisms defined
for arbitrary topology (mesh) networks to enable protection of
end-to-end transport paths.
90. (Editor's note: inclusion of ring specific control plane
requirements are TBD, See Section 2.8.6.1. of [TP-REQ])
91. The MPLS-TP control plane must include support for
differentiated services and different traffic types with
traffic class separation associated with different traffic.
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92. The MPLS-TP control plane must support the provisioning of
services that provide a guaranteed of Service Level
Specifications (SLS), with support for hard and relative end-
to-end bandwidth guarantees. [Editor's note: add reference to
definition of hard and relative guarantees]
93. The MPLS-TP control plane must support the provisioning of
services which are sensitive to jitter and delay.
2.2. MPLS-TP Framework Derived Requirements
The following additional requirements are based on [TP-FWK]:
94. Per-packet equal cost multi-path (ECMP) load balancing is not
applicable to MPLS-TP.
95. Penultimate hop popping (PHP) is disabled on MPLS-TP LSPs by
default. The applicability of PHP to both MPLS-TP LSPs and MPLS
networks general providing packet transport services will be
clarified in a future version.
96. The MPLS-TP control plane must support both E-LSP and L- LSP as
specified in [RFC3270].
97. The address spaces used in the management, control and data
planes are independent.
98. The MPLS-TP control plane is based on the MPLS control plane
for pseudowires, and more specifically, LDP is used for PW
signaling.
99. Both single-segment and multi-segment PWs shall be supported by
the MPLS-TP control plane. MPLS-TP shall use the definition of
multi-segment PWs that is under development in the IETF
independent from MPLS-TP.
100. The MPLS-TP control plane is based on the GMPLS control plane
for MPLS-TP LSPs. More specifically, GMPLS RSVP-TE [RFC3473]
and related extensions are used for LSP signaling, and GMPLS
OSPF-TE [RFC5392] and ISIS-TE [RFC5316] are used for routing.
101. The MPLS-TP LSP control plane must allow for interoperation
with the MPLS-TE LSP control plane.
102. The MPLS-TP control plane must ensure its own survivability and
to enable it to recover gracefully from failures and
degradations. These include graceful restart and hot redundant
configurations.
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103. The MPLS-TP control plane must support linear, ring and meshed
protection schemes.
2.3. OAM Framework Derived Requirements
The following additional requirements are based on [TP-OAM-REQ] and
[TP-OAM]:
104. The MPLS-TP control plane must support the capability to
enable/disable OAM functions as part of service establishment.
105. The MPLS-TP control plane must support the capability to
enable/disable OAM functions after service establishment. In
such cases, the customer must not perceive service degradation
as a result of OAM enabling/disabling.
106. The MPLS-TP control plane must allow for the IP/MPLS and PW OAM
protocols (e.g., LSP-Ping [RFC4379], MPLS-BFD [BFD-MPLS], VCCV
[RFC5085] and VCCV-BFD [VCCV-BFD]).
107. The MPLS-TP control plane must allow for the ability to support
experimental OAM functions. These functions must be disabled
by default.
108. The MPLS-TP control plane must support the choice of which (if
any) OAM function(s) to use and on which PW, LSP or Section to
apply it(them) to.
109. The MPLS-TP control plane must provide a mechanism to support
the localization of faults and the notification of appropriate
nodes. Such notification should trigger corrective (recovery)
actions.
110. The MPLS-TP control plane must allow service provider to be
informed of a fault or defect affecting the service(s) it
provides, even if the fault or defect is located outside of his
domain.
111. Information exchange between various nodes involved in the
MPLS-TP control plane should be reliable such that, for
example, defects or faults are properly detected or that state
changes are effectively known by the appropriate nodes.
112. The MPLS-TP control plane must provide functionality to control
the verification of the continuity (checks) (CC) of a PW, LSP
or Section.
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113. The MPLS-TP control plane must provide functionality to control
the verification of the connectivity (CV) of a PW, LSP or
Section.
114. The MPLS-TP control plane may provide functionality to control
the conduction of diagnostic tests on a PW, LSP or Section.
115. The MPLS-TP control plane must provide functionality to enable
an End Point to discover the Intermediate (if any) and End
Point(s) along a PW, LSP or Section, and more generally to
trace (record) the route of a PW, LSP or Section.
116. The MPLS-TP control plane must provide functionality to enable
an End Point of a PW, LSP or Section to instruct its associated
End Point(s) to lock the PW, LSP or Section. Note that lock
corresponds to an administrative status in which forwarding
traffic on and from the PW, LSP or Section is disabled. (This
requirement duplicates a requirement stated above but is listed
again to maintain alignment with [TP-OAM].)
117. The MPLS-TP control plane must provide functionality to enable
an Intermediate Point of a PW or LSP to report, to an End Point
of that same PW or LSP, an external lock condition affecting
that PW or LSP.
118. The MPLS-TP control plane must provide functionality to enable
an Intermediate Point of a PW or LSP to report, to an End Point
of that same PW or LSP, a fault or defect condition affecting
that PW or LSP.
119. The MPLS-TP control plane must provide functionality to enable
an End Point to report, to its associated End Point, a fault or
defect condition that it detects on a PW, LSP or Section for
which they are the End Points.
120. The MPLS-TP control plane must provide functionality to enable
the propagation, across an MPLS-TP network, of information
pertaining to a client defect of fault condition detected at an
End Point of a PW or LSP, if the client layer mechanisms do not
provide an alarm notification/propagation mechanism.
121. The MPLS-TP control plane must provide functionality to enable
the control of quantification of packet loss ratio over a PW,
LSP or Section.
122. The MPLS-TP control plane must provide functionality to report
an expected one-way, and if appropriate, the two-way, delay of
a PW, LSP or Section.
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123. The MPLS-TP control plane must support the configuration of
MEPs.
a. The CC and CV functions operate between MEPs.
b. All OAM packets coming to a MEP source are tunneled via
label stacking, and therefore a MEP may only be present
at an LSP's ingress and egress nodes (and never at an
LSP's transit node).
c. The CC and CV functions may serve as a trigger for
protection switching, see requirement 45 above.
d. This implies that LSP hierarchy must be used in cases
where OAM is used to trigger recovery.
124. The MPLS-TP control plane must support the signaling of the
transmission period and the ME identifier used in CC and CV.
2.4. Security Requirements
There are no specific MPLS-TP control plane security requirements.
The existing framework for MPLS and GMPLS security is documented on
[MPLS-SEC] and that document applies equally to MPLS-TP.
3. Relationship of PWs and TE LSPs
[Editor's note: This section (and the remainder of this document) is
preliminary and will be edited/replaced in future versions.]
TBD
4. TE LSPs
[Editor's note: This section (and the remainder of this document) is
preliminary and will be edited/replaced in future versions.]
4.1. General reuse of existing GMPLS control plane mechanisms
As described in [RFC3945], Generalized MPLS (GMPLS) extends MPLS to
support additional switching technologies. GMPLS is thus capable of
controlling packet technologies. Most of the initial efforts on
Generalized MPLS (GMPLS) have been related to delivering circuit
connectivity. With the emergence of devices capable of multiple
switching capabilities and the integrated control paradigm, there is
a need to clarify the applicability of GMPLS to packet switching
technologies. In particular, the formal definition of FAs and
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hierarchy in [RFC4206] led to the definition of four regions for PSC
(Packet Switching Capable) interfaces: PSC-1, PSC-2, PSC-3, and
PSC-4. This document describes the GMPLS topics specifically related
to MPLS-TP.
4.1.1. In-Band and Out-Of-Band
The terms in-band and out-of-band typically refer to the relationship
of the management and control planes relative to the data plane. The
terms may be used to refer to the management plane independent of the
control plane, or to both of them in concert. There are multiple
uses of the terms in-band and out-of-band, and they may relate to a
channel, a path or a network. Each of these can be used
independently or in combination. Briefly, the terms are typically
used as follows:
o In-band
This term is used to refer to cases where management and/or
control plane traffic is sent using or embedded in the same
communication channel used to transport the associated data. IP
forwarded, MPLS packet, and Ethernet networks are all examples
where control traffic is typically sent in-band with the data
traffic.
o Out-of-band, in-fiber
This term is used to refer to cases where management and/or
control plane traffic is sent using a different communication
channel from the associated data traffic, and the
control/management communication channel resides in the same
fiber as the data traffic. Optical transport networks typically
operate in an out-of-band in-fiber configuration.
o Out-of-band, aligned topology
This term is used to refer to the cases where management and/or
control plane traffic is sent using a different communication
channel from the associated data traffic, and the
control/management communication must follow the same node-to-
node path as the data traffic. Such topologies are usually
supported using a parallel fiber or other configuration where
multiple data channels are available and one is (dynamically)
selected as the control channel.
o Out-of-band, independent topology
This term is used to refer to the cases where management and/or
control plane traffic is sent using a different communication
channel from the associated data traffic, and the
control/management communication may follow a path that is
completely independent of the data traffic. Such configurations
don't preclude the use of in-fiber or aligned topology links, but
alignment is not required.
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In the context of MPLS-TP, requirement 4 can be met using out-of-band
in-fiber or aligned topology types of control. Requirement 5 can
only be met by using Out-of-band, independent topology. GMPLS
routing and signaling can be used to support in-band and all of the
out-of-band forms of control, see [RFC3945].
4.1.2. Addressing
MPLS-TP uses the IPv4 and IPv6 address families to identify MPLS-TP
nodes by default for network management and signaling purposes. The
separation of the control and management planes from the data plane
allows each plane to be independently addressable. Each plane may
use addresses that are not mutually reachable, e.g., it is likely
that the data plane will not be able to reach an address from the
management or control planes and vice versa. Each plane may also use
a different address family. It is even possible to reuse addresses
in each plane, but this is not recommended as it is likely lead to
operational confusion.
Unnumbered interfaces and links are also permitted and usage is at
the discretion of the network operator.
4.2. Signaling
In this section, we reference the existing MPLS and GMPLS signaling
and routing mechanisms which can be used to support MPLS-TP LSPs.
When controlling a packet-switched data-plane with GMPLS, the packets
have an MPLS (see [RFC3032]) format, with the so-called "shim header"
including a 20-bit label. Unlike MPLS, GMPLS uses the Generalized
Label Object defined in [RFC3471] to signal such labels.
In the current RSVP-TE signaling protocol, many objects make use of
the Generalized Label.
According to [RFC3471], a Generalized Label has the following format:
"Generic MPLS labels and Frame Relay labels are encoded right
justified aligned in 32 bits (4 octets)". This is primarily used in
RESV messages to encode the downstream assigned label which shall be
used on a link or FA of an LSP, using the LABEL object (class = 16).
When the C-Type is set to 2, this LABEL object is carrying a
Generalized Label encoded as defined in [RFC3471].
When a node wishes to restrict the set of labels possibly assigned by
its downstream neighbor (for the LSP), it can use the LABEL_SET
object in PATH messages: the Label Type must be set to "Generalized
Label" (value=2) and the Sub-Channels must be such Generalized
Labels.
The SUGGESTED_LABEL, RECOVERY_LABEL and UPSTREAM_LABEL objects
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(respectively, class = 129, 34, 35; C-Type = 2) of the PATH messages
have an identical format to that of the Generalized Label Object.
Similarly, the RECORD_ROUTE object of the PATH message can record the
labels which are used along the LSP, using the label subobject TLV
(type = 3). In this subobject, the C-type of the recorded label is
copied (value is therefore 2 in the packet case), and the Label
Object is copied into the appropriate field.
The Generalized Label Request Object must be used in PATH messages
(C-Type = 4) instead of the simple Label Request without range such
as defined in [RFC3209] (C-Type = 1). In this object the Switching
Type is then set to PSC-1, PSC-2, PSC-3 or PSC-4 (respectively values
1 to 4) according to the type of LSP being opened (see Section 3).
The ACCEPTABLE_LABEL_SET object (Class= 130, C-Type = 1) of the
PathErr message has an identical format to that of the LABEL_SET
object of PATH messages.
An MPLS-TP domain may be a switching point for an LSP that extends
between client network islands. In this case, the MPLS- TP domain
edge that connects to the respective client domain may have a static
switching in the data plane done on the interface connecting to the
respective client node. Alternatively, the LSP may be signaled
between the client network and the MPLS-TP domain. There are two
cases: (1) the client network connects via a GMPLS UNI to the MPLS-TP
domain with knowledge of the remote MPLS-TP edge node and link that
connects to the remote client node or there is some reachability
information exchanged between the MPLS-TP domain and the client
network via dynamic protocol, or (2) integrated model whereby the
client network is an integrated part of the MPLS-TP domain, less
likely option in some of the operation environments.
4.3. Routing
The major extension in the context of routing PSC-LSPs within the
GMPLS framework is the use of the various PSC-regions introduced by
[RFC3945]. With the introduction of the hierarchy, formally specified
in [RFC4206], it is necessary to use PSC-x as Switching Capability
(SC) and therefore, the nesting process is modified with regards to
the MPLS procedures. In particular, the policy chosen for announcing
the SC associated with a Forwarding Adjacency has a significant
impact. That is an MPLS-TP announced as an FA in a client network in
an integrated model to support hierarchical MPLS-TP in MPLS-TP
domain.
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4.3.1. ISIS-TE/OSPF-TE routing in support of MPLS-TP
The major extension in the context of routing PSC-LSPs within the
GMPLS framework is the use of the various PSC-regions introduced by
[RFC3945]. In MPLS, no hierarchy being formally defined, no
limitations were applied on nesting packet LSPs within other packet
LSPs. With the introduction of the hierarchy, formally specified in
[RFC4206], it is necessary to use PSC-x as Switching Capability (SC)
and therefore, the nesting process is modified with regards to the
MPLS procedures. In particular, the policy chosen for announcing the
SC associated with a Forwarding Adjacency has a significant impact.
4.3.1.1. ISIS-TE/OSPF-TE routing for MPLS-TP
Per [RFC4203] for OSPF and [RFC5307] for IS-IS, the Interface
Switching Capability Descriptor (ISCD) is a sub-TLV (of type 15) of
the Link TLV, which is used to indicate the Switching Capability (or
Capabilities) of an interface. Per [RFC4203], this TLV indicates
encoding, MTU and bandwidth available at each priority level. The TLV
also carries a Switching Capability field which indicates the
switching hierarchy level:
1: Packet-Switch Capable-1 (PSC-1)
2: Packet-Switch Capable-2 (PSC-2)
3: Packet-Switch Capable-3 (PSC-3)
4: Packet-Switch Capable-4 (PSC-4)
4.3.1.2. Multiple Switching Capabilities
To support interfaces that have more than one ISCD (see Section
"Interface Switching Capability Descriptor" of [RFC4202]), the ISCD
may occur more than once within a single routing protocol link
description message. This allows a single packet TE-link or FA to be
announced in multiple PSC regions, both as a PSC-1 and PSC-2 for
instance.
The "regular" packet TE-links (non-FAs) can also be configured to be
used by one or several of the regions. A TE-link set to a single PSC-
x region will be reserved for establishing PSC-x LSPs, whereas one
set to multiple PSC-x, PSC-y and PSC-z regions will be shared by PSC
LSPs of these switching types.
When a TE-link or an FA is shared among regions, it is important for
the nodes receiving traffic over this link/FA to have a single label-
space shared across the regions. This is critical for the node to
guarantee it will receive packets with different labels in different
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packet regions, even when they arrive on the same interface.
The fact that the label-space must be cross-region is independent
from the fact that label-spaces may be per- interface, per-tunnel,
per-upstream neighbor or per-platform.
4.3.1.3. Hierarchy
[RFC4206] defines network regions based on switching capabilities.
The hierarchy of regions is novel in GMPLS and this section intends
to clarify the hierarchy for PSC nodes, and the use of the various
PSC-regions.
According to [RFC4206], there are four PSC regions which are
hierarchically ordered in the following way: PSC-1 < PSC-2 < PSC-3 <
PSC-4, that is PSC-1 is the smallest SC and PSC-4 is the largest SC.
Let us consider two consecutive nodes of an LSP, such that the first
node's SC is PSC-x and the second node's is PSC-y. The first node is
said to be at the border of two packet regions, with regard to that
LSP, if PSC-y is larger than PSC-x (i.e.: x < y ). Similarly, the
second node is said to be at the border of two packet regions, with
regard to that LSP, if x > y.
According to [RFC4202], "a unidirectional LSP must have the same sets
of SCs at both ends". Additionally, such an LSP will only be routed
over TE-links and/or FAs which have (at least) that SC (since
otherwise, the region crossing would trigger the setup of an FA-LSP,
as described in [RFC4206]). This imposes that a PSC-x LSP be setup
using only TE-links and/or FAs which include at least PSC-x. In the
packet-switching context, this means that a PSC-x cannot directly use
links/FAs which do not have a PSC-x set in their ISCD's Switching
Capability Field. Therefore, if one wants to establish a PSC-x LSP
across a PSC-y region, an FA- LSP must either be available or set-up.
It may be announced in the PSC-x region routing instance (which may
be the same as the PSC-y region routing instance) as a PSC-x TE-link.
The SC associated with an FA is announced using the routing
protocol's Interface Switching Capability Descriptor (ISCD) (see
Section 3.1). For instance, if a PSC-1 LSP has to be setup across a
PSC- 3 region, the region border node will first have to establish a
PSC-3 LSP in which the PSC-1 LSP will be nested. The PSC-3 LSP may
then be used to announce an FA in the PSC-1 routing protocol.
In the four packet regions, the switching principles are the same,
which means that a PSC node is most likely to have in fact all four
PSC-1, PSC-2, PSC-3 and PSC-4 switching types. When using a packet
LSP to nest other LSPs, the policy for deciding which PSCs to
announce for the packet FAs and TE-links, and the policy for cross-
region LSP triggering determine the type of interactions between the
PSC-regions. This means there are in fact multiple ways of using the
PSC regions.
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4.3.2. TE link bundling
4.4. OAM, MEP (hierarchy) configuration & control
Current MPLS LSP and PW OAM capabilities are not suitable for
transport applications. Hence IETF has started work to define a
comprehensive set of MPLS-TP OAM functions. Specific OAM requirements
for MPLS-TP are documented in [draft-ietf-mpls-tp- oam-requirements].
In addition to the actual OAM requirements, it is also required that
the control plane is able to configure and control OAM entities. This
requirement is not yet addressed by the foreseen MPLS-TP control
protocols (i.e, GMPLS for LSPs and T-LDP for PWs).
To emphasize the importance of OAM establishment via the control
plane it must be noted that for proper OAM; OAM messages and the
actual normal traffic must be congruent: taking the same path and
relying on the same forwarding decisions at intermediate nodes.
Hence, it is desirable that OAM is setup together with the
establishment of the data path (i.e., with the same signaling). This
way OAM setup is bound to connection establishment signaling,
avoiding two separate management/configuration steps (connection
setup followed by OAM configuration) which would increases delay,
processing and more importantly may be prune to misconfiguration
errors.
It must be noted that although the control plane is used to establish
OAM entities, subsequently OAM is executed independently from the
control plane. That is, OAM mechanisms are responsible for monitoring
and initiating recovery actions (driving switches between primary and
backup paths).
GMPLS RSVP-TE based OAM configuration and control should be general
to be applicable to a wide range of data plane technologies and OAM
solution and not be limited to the MPLS technology and MPLS-TP OAM.
On the other hand, GMPLS based OAM configuration must satisfy all
MPLS-TP requirements.
PW OAM establishment is FFS.
4.5. Traffic engineering and constraint-based path computation
Same approach as MPLS. Specific algorithms out of scope. Similar to
MPLS, but adds bidirectional and recovery path computation.
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4.5.1. Relation to PCE
Path Computation Element (PCE) may be used for path computation of a
GMPLS LSP across domains and in a single domain. A Network Management
System (NMS) may be used to trigger path computation for a GMPLS LSP
and configure the cross-connects along the computed path.
Alternatively, the path computation may be triggered by a network
node via PCE Communication Protocol (PCECP) and the LSP signaled
using GMPLS.
4.6. Applicability
4.7. Recovery
4.7.1. E2E, segment
GMPLS defines recovery signaling for P2P LSPs in [RFC4872], RSVP-TE
extensions in support for end-to-end GMPLS recovery, and [RFC4873],
GMPLS segment recovery. GMPLS segment recovery provides a superset
of the function in end-to-end recovery. The former can be viewed as
a special case of segment recovery where there is a single recovery
domain whose borders coincide with the ingress and egress of the LSP.
All five of the protection types defined for recovery are supported
in MPLS-TP.
- 1+1 bidirectional protection for P2P LSPs
- 1+1 unidirectional protection for P2MP LSPs
- 1:n (including 1:1) protection with or without extra traffic
- Rerouting without extra traffic (sometimes known as soft
rerouting), including shared mesh restoration
- Full LSP rerouting
Recovery MUST be signaled using the mechanism defined in [RFC4872]
and [RFC4873]. The use of Notify messages to trigger protection
switching and recovery is not required in MPLS-TP as this function is
expected to be supported via OAM. However, it's use is not
precluded.
The restoration priority for an MPLS-TP LSP is taken from the setup
priority field in the SESSION_ATTRIBUTE object.
The preemption priority for an MPLS-TP LSP is taken from the holding
priority field in the SESSION_ATTRIBUTE object.
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4.7.2. P2P, P2MP
4.7.3. Recovery Triggers
The GMPLS control plane allows for management plane recovery triggers
and directly supports control plane recovery triggers. Support for
control plane recovery triggers is defined in [RFC4872] which refers
to the triggers as "Recovery Commands". These commands can be used
with both end-to-end and segment recovery, but are always controlled
on an end-to-end basis. The recovery triggers/commands defined in
[RFC4872] are:
a. Lockout of recovery LSP
b. Lockout of normal traffic
c. Forced switch for normal traffic
d. Requested switch for normal traffic
e. Requested switch for recovery LSP
Note that control plane triggers are typically invoked in response to
a management plane request at the ingress.
4.8. Diffserv object usage in GMPLS (E-LSPs, L-LSPs)
4.9. Management plane support
In MPLS-TP networks, like in any other technology, a control plane
can be used to speed up and simplify provisioning and recovery
actions in case of failures. The control plane needs, as does the
data plane, to interact with the management plane in order to set-
up/delete/modify LSPs and it also needs to be managed as any other
network components by the Management Plane.
[Editor's note: need to describe how the last sentence is supported
via standard MIBs.]
4.9.1. Management Plane / Control Plane Ownership Transfer
In networks where both control plane and management plane are
provided, LSP provisioning can be bone either by control plane or
management plane. As mentioned in the requirements section above, it
must be possible to transfer, or handover, management plane created
circuit under the control plane domain and vice-versa. [RFC5493]
defines the specific requirements for an LSP ownership handover
procedure. It must be possible for the control plane to notify, in
reliable manner, the management plane about the status/result of
either synchronous or asynchronous, with respect to the management
plane, operation performed. Moreover it must be possible to monitor,
via query or spontaneous notify, the status of the control plane
object such as example the TE Link status, the available resources,
etc. A mechanism must be made available by the control plane to the
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management plane to log control plane LSP related operation, that is,
it must be possible from the NMS to have a clear view of the life,
(traffic hit, action performed, signaling etc.) of a given LSP. The
LSP handover procedure for MPLS-TP LSPs is supported via [PC-SCP].
4.10. CP reference points (E-NNI, I-NNI, UNI)
4.11. MPLS to MPLS-TP interworking
- Leverage current MPLS and GMPLS development
- Backward compatibility
5. Pseudo Wires
[Editor's note: This section is preliminary and will be
edited/replaced in future versions. There could be some differences
(e.g., OAM interaction), and this section will focus on those
differences.]
MPLS Pseudo Wires, as defined in [RFC3985], provide for emulated
services over an MPLS Packet Switched Network (PSN). There are
several types of pseudowires: (1) Ethernet PWs providing for Ethernet
port or Ethernet VLAN over MPLS [RFC4448], (2) HDLC/PPP Pseudowire
providing for HDLC/PPP leased line transport of MPLS[RFC4618], (3)
ATM PWs [RFC4816], (4) Frame Relay PWs [RFC4619], and (5) circulation
Emulation PWs [RFC4553].
Today's transport networks based on PDH, WDM, or SONET/SDH provide
transport for PDH or SONET (e.g., ATM over SONET or Packet PPP over
SONET) client signals with no payload awareness. Implementing PW
capability allows the use of an existing technology to substitute the
TDM transport with Packet-aware transport, using well-defined
pseudowire encapsulation methods for carrying various packet services
over MPLS, and providing for potentially better bandwidth
utilization.
There are two types of pseudowires: (1) Single-Segment pseudowires
(SS-PW), and (2) Multi-segment pseudowires (MS-PW). An MPLS-TP
domain may transport a PW with endpoints within a client network
transparently. Alternatively, an MPLS-TP edge node may be the
Terminating PE (T-PE) for a PW, performing adaptation from the native
attachment circuit technology (e.g. Ethernet 802.1q) to an MPLS PW
for transport over an MPLS-TP domain, with a GMPLS LSP or a hierarchy
of LSPs transporting the PW between the T-PEs. In this way, the PW is
analogous to a transport channel in a TDM network and the LSP is
equivalent to a container of multiple non-concatenated channels,
albeit they are packet containers. The MPLS-TP domain may also
contain Switching PEs (S-PEs) for a multi-segment PW whereby the T-
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PEs may be at the edge of the MPLS-TP domain or in a client network.
In this latter case, a T-PE in a client network is a T-PE performing
the adaptation of the native service to MPLS and the MPLS-TP domain
performs Pseudo-wire switching.
SS-PW signaling control plane is based on LDP with specific
procedures defined in [RFC4447]. [Segmented-PW] and [MS-PW] allow for
static switching of multi-segment pseudowires in data and control
plane and for dynamic routing and placement of an MS-PW whereby
signaling is still based on Targeted LDP (T-LDP). The MPLS-TP domain
shall use the same PW signaling protocols and procedures for placing
SS-PWs and MS-PWs. This will leverage existing technology as well as
facilitate interoperability with client networks with native
attachment circuits or PW segment that is switched across the MPLS-TP
domain.
The same control protocol and procedures are reused as much as
possible. However, when using PWs in MPLS-TP, a set of new
requirements are defined which may require extensions of the existing
control mechanisms. This section identifies areas where extensions
are needed based on the PW Control Plane related requirements
documented in [draft-ietf-mpls-tp-requirements].
The baseline requirement for extensions to support transport
applications is that any new mechanisms and capabilities must be able
to interoperate with existing IETF MPLS [RFC3031] and IETF PWE3
[RFC3985] control and data planes where appropriate. Hence,
extensions of the PW Control Plane must be in-line with the
procedures defined in [RFC4447].
For MPLS-TP, it is required that the data and control planes are both
logically and physically separated. That is, the PW Control Plane
must be able to operate out-of-band (OOB). This ensures that in the
case of control plane failures the data plane is not affected and can
continue to operate normally. This was not a design requirement for
the current PW Control Plane. However, due to the PW concept, i.e.,
PWs are connecting logical entities ('forwarders'), and the operation
of the PW control protocol, i.e., only edge PE nodes (T-PE, S-PE)
take part in the signaling exchanges: moving T-LDP out-of-band seems
to be, theoretically, a straightforward exercise.
More precisely, if IP addressing is used in the MPLS-TP control plane
then T-LDP addressing can be maintained, although all addresses will
refer to control plane entities. Both, the PWid FEC and Generalized
PWid FEC Elements can possibly be used in an OOB case as well
(Detailed evaluation is FFS). The PW Label allocation and exchange
mechanisms can be possibly reused unchanged (Detailed evaluation is
FFS). Binding a PW to an LSP, or PW segments to LSPs can be left to
networks elements acting as T-PEs and S-PEs or a control plane entity
that may be the same one signaling the PW. If the control plane is
physically separated from the forwarder, the control plane must be
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able to program the forwarders with necessary information.
For transport applications, it is mandatory that bidirectional
traffic is following congruent paths. Today, each direction of a PW
or a PW segment is bound to a unidirectional LSP that extends between
two T-PEs, S-PEs, or a T-PE and an S-PE. The unidirectional LSPs in
both directions are not required to following congruent paths, and
therefore both directions of a PW may not follow congruent paths. The
only requirement today is that a PW or a PW segment shares the same
T-PEs in both directions, and same S-PEs in both directions. This
poses a new requirement on the PW Control Plane, namely to ensure
that both ends map the PW to the same transport path. When a
bidirectional LSP is selected on one end to transport the PW, a
mechanism is needed that signals to the remote end which LSP has been
selected locally to transport the PW. This likely can be accomplished
by adding a new TLV to PW signaling. This coincides with the gap
identified for OOB support: a new mechanism may be needed to
explicitly bind PWs to the supporting transport LSP.
Alternatively, two unidirectional LSPs may be used to support the PW.
However, to meet the congruency requirement, the LSPs must be placed
so that they are forced to follow the same path (switches and links).
This maybe accomplished by placing one unidirectional TE-LSP in one
direction at one endpoint, and forcing the other endpoint to setup a
TE-LSP with an ERO that has the nodes/links in the reverse order from
the RRO seen in the path message of the LSP in the reverse direction.
In this case, when one endpoint selects an LSP to bind the PW to, it
must identify to the remote end which LSP to bind the other direction
of the PW to.
Transport applications require resource guarantees. In the case of
transport LSPs, resource reservation mechanisms are provided via
RSVP-TE and the use of DiffServ. If multiple PWs are
multiplexed into the same transport LSP resources, contention may
occur. However, local policy at PEs may ensure proper resource
sharing among PWs mapped into a resource guaranteed LSP. On the other
hand, it is limited if any guarantees can be provided to PWs if the
LSPs used to support MPLS-TP PWs do not support resource guarantees.
The PW control plane must be able to establish and configure all of
the available features manageable for the PW, including protection
and OAM entities and mechanisms. There is ongoing work on PW
protection and MPLS-TP OAM.
To summarize, the main areas identified for potential PW Control
Plane extensions to support MPLS-TP are the following.
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o Move PW Control Plane out-of-band
o Explicit control of PW to LSP binding
o PW QoS and congestion control
o PW protection
o PW OAM configuration and control
5.1. General reuse of existing PW control plane mechanisms
5.2. Signaling
5.3. Recovery (Redundancy)
6. Security Considerations
[Editor's note: This section is preliminary and will be
edited/replaced in future versions.]
This document is a framework document and does not describe bits on
the wire and have a very small impact on MPLS/GMPLS security issues.
However it gives guidelines for future extension to existing MPLS and
GMPLS protocols, it is understood that the documents that specify
these extensions will address the security issues that relates to the
extensions.
The MPLS/GMPLS security framework [MPLS-SEC] is applicable to both
this document and the documents that will be written as a result of
the output of this document.
7. IANA Considerations
There are no new IANA considerations introduced by this document.
8. Acknowledgments
The authors would like to acknowledge the contributions of Yannick
Brehon, Diego Caviglia, Nic Neate, and Dave Mcdysan to this work.
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9. References
9.1. Normative References
[RFC2119] Bradner, S., "Key words for use in RFCs to Indicate
Requirement Levels," RFC 2119.
[RFC3031] Rosen, E., Viswanathan, A., Callon, R.,
"Multiprotocol Label Switching Architecture", RFC
3031, January 2001.
[RFC3032] Rosen, E., Tappan, D., Fedorkow, G., Rekhter, Y.,
Farinacci, D., Li, T., and Conta, A. "MPLS Label
Stack Encoding", RFC 3032, January 2001.
[RFC3209] Awduche, D., Berger, L., Gan, D., Li, T., Srinivasan,
V., and G. Swallow, "RSVP-TE: Extensions to RSVP for
LSP Tunnels", RFC 3209, December 2001.
[RFC3471] Berger, L., "Generalized Multi-Protocol Label
Switching (GMPLS) Signaling Functional Description",
RFC 3471, January 2003.
[RFC3473] Berger, L. Ed., "Generalized Multi-Protocol Label
Switching (GMPLS) Signaling Resource ReserVation
Protocol-Traffic Engineering (RSVP-TE) Extensions",
January 2003.
[RFC4202] Kompella, K. and Y. Rekhter, "Routing Extensions in
Support of Generalized Multi-Protocol Label
Switching(GMPLS)", RFC 4202, October 2005.
[RFC4203] Kompella, K. and Y. Rekhter, "OSPF Extensions in
Support of Generalized Multi-Protocol Label Switching
(GMPLS)", RFC 4203, October 2005.
[RFC4206] Kompella, K. and Y. Rekhter, "Label Switched Paths
(LSP) Hierarchy with Generalized Multi-Protocol Label
Switching (GMPLS) Traffic Engineering (TE)", RFC
4206, October 2005.
[RFC4447] Martini, L., Ed., "Pseudowire Setup and Maintenance
Using the Label Distribution Protocol (LDP)", RFC
4447, April 2006.
[RFC4448] Martini, L., Ed., "Encapsulation Methods for
Transport Ethernet over MPLS Network", RFC 4448,
April 2006.
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[RFC4872] Lang, J., Rekhter, Y., and Papadimitriou, D.,
"RSVP-TE Extensions in Support of End-to-End
Generalized Multi- Protocol Label Switching (GMPLS)
Recovery", RFC 4872, May 2007.
[RFC4873] Berger, L., Bryskin, I., Papadimitriou, D., Farrel, A.,
"GMPLS Segment Recovery", RFC 4873, May 2007.
[RFC4929] Andersson, L. and A. Farrel, "Change Process for
Multiprotocol Label Switching (MPLS) and Generalized
MPLS (GMPLS) Protocols and Procedures", BCP 129, RFC
4929, June 2007.
[RFC5307] Kompella, K. and Rekhter, Y., "IS-IS Extensions in
Support of Generalized Multi-Protocol Label Switching
(GMPLS)", RFC 5307, October 2008.
[RFC5316] Chen, M., Zhang, R., and Duan, X., "ISIS Extensions
in Support of Inter-Autonomous System (AS) MPLS and
GMPLS Traffic Engineering", RFC 5392, December 2008.
[RFC5392] Chen, M., Zhang, R., and Duan, X., "OSPF Extensions
in Support of Inter-Autonomous System (AS) MPLS and
GMPLS Traffic Engineering", RFC 5392, January 2009.
[TP-FWK] Bocci, M., Ed., Et al, "A Framework for MPLS in
Transport Networks", work in Progress,
draft-ietf-mpls-tp-framework-02, July 2009.
[TP-OAM] Busi, I., Ed., Niven-Jenkins, B., Ed., "MPLS-TP OAM
Framework and Overview", work in Progress,
draft-busi-mpls-tp-oam-framework-02, March 2009.
[TP-OAM-REQ] Vigoureux, M., Ward, D, and Betts, M.,
"Requirements for OAM in MPLS Transport
Networks",
draft-ietf-mpls-tp-oam-requirements-02, June
2009.
[TP-SURVIVE] Sprecher, N., et al., "Multiprotocol Label
Switching Transport Profile Survivability
Framework", work in Progress,
draft-sprecher-mpls-tp-survive-fwk-01.txt,
February 2009.
[TP-REQ] Niven-Jenkins, B., Et al, "MPLS-TP Requirements",
work in Progress, draft-ietf-mpls-tp-requirements-09,
June 2009.
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9.2. Informative References
[BFD-MPLS] Aggarwal, R., Kompella, K., Nadeau, T., and
G. Swallow, "BFD For MPLS LSPs",
draft-ietf-bfd-mpls-07 (work in progress), June
2008.
[ITU.G8080.2006] International Telecommunications Union,
"Architecture for the automatically switched
optical network (ASON)", ITU- T Recommendation
G.8080, June 2006.
[ITU.G8080.2008] International Telecommunications Union,
"Architecture for the automatically switched
optical network (ASON) Amendment 1", ITU-T
Recommendation G.8080 Amendment 1, March 2008.
[MPLS-SEC] Fang, L., et al, "Security Framework for MPLS and
GMPLS Networks", work in Progress,
draft-ietf-mpls-mpls-and-gmpls-security-framework-05.txt,
March 2009.
[PC-SCP] Caviglia, D, et al, "RSVP-TE Signaling Extension For
The Conversion Between Permanent Connections And Soft
Permanent Connections In A GMPLS Enabled Transport
Network.", draft-ietf-ccamp-pc-spc-rsvpte-ext-02.txt,
work in progress, October 2008.
[Segmented-PW] Martini, L., Nadeau, T., and Duckett M., "
Segmented Pseaudowire", work in Progress,
draft-ietf-pwe3-segmented-pw-12.txt, June 2009.
[RFC3945] Mannie, E., "Generalized Multi-Protocol Label
Switching (GMPLS) Architecture", RFC 3945, October
2004.
[RFC3985] Bryant, S. and P. Pate, "Pseudo Wire Emulation Edge-
to-Edge (PWE3) Architecture", RFC 3985, March 2005.
[RFC3270] Le Faucheur, F., et al, "Multi-Protocol Label
Switching (MPLS) Support of Differentiated
Services", RFC3270, May 2002.
[RFC4139] Papadimitriou, D., et al, "Requirements for
Generalized MPLS (GMPLS) Signaling Usage and
Extensions for Automatically Switched Optical
Network (ASON)", RFC4139, July 2005.
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[RFC4208] Swallow, G., Drake, J., Ishimatsu, H., and Rekhter,
Y., "Generalized Multi-Protocol Label Switching
(GMPLS) User-Network Interface (UNI): Resource
ReserVation Protocol-Traffic Engineering (RSVP-TE)
Support for the Overlay Model", RFC 4206, October
2005.
[RFC4258] Brungard, D., et al, "Requirements for Generalized
Multi-Protocol Label Switching (GMPLS) Routing for
the Automatically Switched Optical Network (ASON)",
RFC4258, November 2005.
[RFC4379] Kompella, K. and G. Swallow, "Detecting
Multi-Protocol Label Switched (MPLS) Data Plane
Failures", RFC 4379, February 2006.
[RFC4427] Mannie, E., Papadimitriou, D., "Recovery (Protection
and Restoration) Terminology for Generalized
Multi-Protocol Label Switching (GMPLS)", RFC4427,
March 2006.
[RFC4553] Vainshtein, A., Ed., and Stein, YJ., Ed.,"Structure-
Agnostic Time Division Multiplexing (TDM) over Packet
(SAToP)", RFC 4553, June 2006.
[RFC4618] Martini, L., Rosen, E., Heron, G., and Malis, A.,
"Encapsulation Methods for Transport of PPP/High-
Level Data Link Control (HDLC) over MPLS Networks",
RFC 4618, September 2006.
[RFC4619] Martini, L., Ed., Kawa, C., Ed., and Malis, A., Ed.,
"Encapsulation Methods for Transport of Frame Relay
over Multiprotocol Label Switching (MPLS) Networks",
September 2006.
[RFC4816] Malis, A., Martini, L., Brayley, J., and Walsh, T.,
"Pseudowire Emulation Edge-to-Edge (PWE3)
Asynchronous Transfer Mode (ATM) Transparent Cell
Transport Service", RFC 4816, February 2007.
[RFC5085] Nadeau, T. and C. Pignataro, "Pseudowire Virtual
Circuit Connectivity Verification (VCCV): A Control
Channel for Pseudowires", RFC 5085, December 2007.
[RFC5493] Caviglia, D., et al, "Requirements for the
Conversion between Permanent Connections and
Switched Connections in a Generalized Multiprotocol
Label Switching (GMPLS) Network", RFC 5493, April
2009.
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[MS-PW] Bocci, M., and Bryant, B., "An Architecture for
Multi-Segment Pseudowire Emulation Edge-to-Edge",
work in Progress, draft-ietf-pwe3-ms-pw-arch-06.txt,
February 2009.
[VCCV-BFD] Nadeau, T. and C. Pignataro, "Bidirectional
Forwarding Detection (BFD) for the Pseudowire
Virtual Circuit Connectivity Verification (VCCV)",
draft-ietf-pwe3-vccv-bfd-06 (work in progress),
July 2009.
10. Authors' Addresses
Loa Andersson (editor)
Redback Networks
Phone: +46 8 632 77 14
Email: loa@pi.nu
Lou Berger (editor)
LabN Consulting, L.L.C.
Phone: +1-301-468-9228
Email: lberger@labn.net
Luyuan Fang (editor)
Cisco Systems, Inc.
300 Beaver Brook Road
Boxborough, MA 01719
USA
Email: lufang@cisco.com
Nabil Bitar (editor)
Verizon,
40 Sylvan Rd.,
Waltham, MA 02451
Email: nabil.n.bitar@verizon.com
Attila Takacs
Ericsson
1. Laborc u.
Budapest, HUNGARY 1037
Email: attila.takacs@ericsson.com
Martin Vigoureux
Alcatel-Lucent
Email: martin.vigoureux@alcatel-lucent.fr
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