From 4bfd864f10b68b71482b35c818559068ef8d5797 Mon Sep 17 00:00:00 2001 From: Thomas Voss Date: Wed, 27 Nov 2024 20:54:24 +0100 Subject: doc: Add RFC documents --- doc/rfc/rfc4872.txt | 2635 +++++++++++++++++++++++++++++++++++++++++++++++++++ 1 file changed, 2635 insertions(+) create mode 100644 doc/rfc/rfc4872.txt (limited to 'doc/rfc/rfc4872.txt') diff --git a/doc/rfc/rfc4872.txt b/doc/rfc/rfc4872.txt new file mode 100644 index 0000000..f656505 --- /dev/null +++ b/doc/rfc/rfc4872.txt @@ -0,0 +1,2635 @@ + + + + + + +Network Working Group J.P. Lang, Ed. +Request for Comments: 4872 Sonos +Updates: 3471 Y. Rekhter, Ed. +Category: Standards Track Juniper + D. Papadimitriou, Ed. + Alcatel + May 2007 + + + RSVP-TE Extensions in Support of End-to-End + Generalized Multi-Protocol Label Switching (GMPLS) Recovery + +Status of This Memo + + This document specifies an Internet standards track protocol for the + Internet community, and requests discussion and suggestions for + improvements. Please refer to the current edition of the "Internet + Official Protocol Standards" (STD 1) for the standardization state + and status of this protocol. Distribution of this memo is unlimited. + +Copyright Notice + + Copyright (C) The IETF Trust (2007). + +Abstract + + This document describes protocol-specific procedures and extensions + for Generalized Multi-Protocol Label Switching (GMPLS) Resource + ReSerVation Protocol - Traffic Engineering (RSVP-TE) signaling to + support end-to-end Label Switched Path (LSP) recovery that denotes + protection and restoration. A generic functional description of + GMPLS recovery can be found in a companion document, RFC 4426. + +Table of Contents + + 1. Introduction .....................................................3 + 2. Conventions Used in This Document ...............................5 + 3. Relationship to Fast Reroute (FRR) ..............................5 + 4. Definitions .....................................................6 + 4.1. LSP Identification .........................................6 + 4.2. Recovery Attributes ........................................7 + 4.2.1. LSP Status ..........................................7 + 4.2.2. LSP Recovery ........................................8 + 4.3. LSP Association ............................................9 + 5. 1+1 Unidirectional Protection ...................................9 + 5.1. Identifiers ...............................................10 + + + + + +Lang, et al. Standards Track [Page 1] + +RFC 4872 RSVP-TE Extensions for E2E GMPLS Recovery May 2007 + + + 6. 1+1 Bidirectional Protection ...................................10 + 6.1. Identifiers ...............................................11 + 6.2. End-to-End Switchover Request/Response ....................11 + 7. 1:1 Protection with Extra-Traffic ..............................13 + 7.1. Identifiers ...............................................14 + 7.2. End-to-End Switchover Request/Response ....................15 + 7.3. 1:N (N > 1) Protection with Extra-Traffic .................16 + 8. Rerouting without Extra-Traffic ................................17 + 8.1. Identifiers ...............................................19 + 8.2. Signaling Primary LSPs ....................................19 + 8.3. Signaling Secondary LSPs ..................................19 + 9. Shared-Mesh Restoration ........................................20 + 9.1. Identifiers ...............................................22 + 9.2. Signaling Primary LSPs ....................................22 + 9.3. Signaling Secondary LSPs ..................................23 + 10. LSP Preemption ................................................23 + 11. (Full) LSP Rerouting ..........................................25 + 11.1. Identifiers ..............................................25 + 11.2. Signaling Reroutable LSPs ................................26 + 12. Reversion .....................................................26 + 13. Recovery Commands .............................................29 + 14. PROTECTION Object .............................................31 + 14.1. Format ...................................................31 + 14.2. Processing ...............................................33 + 15. PRIMARY_PATH_ROUTE Object .....................................33 + 15.1. Format ...................................................34 + 15.2. Subobjects ...............................................34 + 15.3. Applicability ............................................35 + 15.4. Processing ...............................................36 + 16. ASSOCIATION Object ............................................37 + 16.1. Format ...................................................37 + 16.2. Processing ...............................................38 + 17. Updated RSVP Message Formats ..................................39 + 18. Security Considerations .......................................40 + 19. IANA Considerations ...........................................41 + 20. Acknowledgments ...............................................43 + 21. References ....................................................43 + 21.1. Normative References .....................................43 + 21.2. Informative References ...................................44 + 22. Contributors ..................................................45 + + + + + + + + + + + +Lang, et al. Standards Track [Page 2] + +RFC 4872 RSVP-TE Extensions for E2E GMPLS Recovery May 2007 + + +1. Introduction + + Generalized Multi-Protocol Label Switching (GMPLS) extends MPLS to + include support for Layer-2 Switch Capable (L2SC), Time-Division + Multiplex (TDM), Lambda Switch Capable (LSC), and Fiber Switch + Capable (FSC) interfaces. GMPLS recovery uses control plane + mechanisms (i.e., signaling, routing, and link management mechanisms) + to support data plane fault recovery. Note that the analogous (data + plane) fault detection mechanisms are required to be present in + support of the control plane mechanisms. In this document, the term + "recovery" is generically used to denote both protection and + restoration; the specific terms "protection" and "restoration" are + only used when differentiation is required. The subtle distinction + between protection and restoration is made based on the resource + allocation done during the recovery phase (see [RFC4427]). + + A functional description of GMPLS recovery is provided in [RFC4426] + and should be considered as a companion document. The present + document describes the protocol-specific procedures for GMPLS RSVP- + TE (Resource ReSerVation Protocol - Traffic Engineering) signaling + (see [RFC3473]) to support end-to-end recovery. End-to-end recovery + refers to the recovery of an entire LSP from its head-end (ingress + node endpoint) to its tail-end (egress node endpoint). With end-to- + end recovery, working LSPs are assumed to be resource-disjoint (where + a resource is a link, node, or Shared Risk Link Group (SRLG)) in the + network so that they do not share any failure probability, but this + is not mandatory. With respect to a given set of network resources, + a pair of working/protecting LSPs SHOULD be resource disjoint in case + of dedicated recovery type (see below). On the other hand, in case + of shared recovery (see below), a group of working LSPs SHOULD be + mutually resource-disjoint in order to allow for a (single and + commonly) shared protecting LSP, itself resource-disjoint from each + of the working LSPs. Note that resource disjointness is a necessary + (but not sufficient) condition to ensure LSP recoverability. + + The present document addresses four types of end-to-end LSP recovery: + 1) 1+1 (unidirectional/bidirectional) protection, 2) 1:N (N >= 1) LSP + protection with extra-traffic, 3) pre-planned LSP rerouting without + extra-traffic (including shared mesh), and 4) full LSP rerouting. + + 1) The simplest notion of end-to-end LSP protection is 1+1 + unidirectional protection. Using this type of protection, a + protecting LSP is signaled over a dedicated resource-disjoint + alternate path to protect an associated working LSP. Normal + traffic is simultaneously sent on both LSPs and a selector is used + at the egress node to receive traffic from one of the LSPs. If a + failure occurs along one of the LSPs, the egress node selects the + + + + +Lang, et al. Standards Track [Page 3] + +RFC 4872 RSVP-TE Extensions for E2E GMPLS Recovery May 2007 + + + traffic from the valid LSP. No coordination is required between + the end nodes when a failure/switchover occurs. + + In 1+1 bidirectional protection, a protecting LSP is signaled over + a dedicated resource-disjoint alternate path to protect the + working LSP. Normal traffic is simultaneously sent on both LSPs + (in both directions), and a selector is used at both + ingress/egress nodes to receive traffic from the same LSP. This + requires coordination between the end-nodes when switching to the + protecting LSP. + + 2) In 1:N (N >= 1) protection with extra-traffic, the protecting LSP + is a fully provisioned and resource-disjoint LSP from the N + working LSPs, that allows for carrying extra-traffic. The N + working LSPs MAY be mutually resource-disjoint. Coordination + between end-nodes is required when switching from one of the + working LSPs to the protecting LSP. As the protecting LSP is + fully provisioned, default operations during protection switching + are specified for a protecting LSP carrying extra-traffic, but + this is not mandatory. Note that M:N protection is out of scope + of this document (though mechanisms it defines may be extended to + cover it). + + 3) Pre-planned LSP rerouting (or restoration) relies on the + establishment between the same pair of end-nodes of a working LSP + and a protecting LSP that is link/node/SRLG disjoint from the + working one. Here, the recovery resources for the protecting LSP + are pre-reserved but explicit action is required to activate + (i.e., commit resource allocation at the data plane) a specific + protecting LSP instantiated during the (pre-)provisioning phase. + Since the protecting LSP is not "active" (i.e., fully + instantiated), it cannot carry any extra-traffic. This does not + mean that the corresponding resources cannot be used by other + LSPs. Therefore, this mechanism protects against working LSP(s) + failure(s) but requires activation of the protecting LSP after + working LSP failure occurrence. This requires restoration + signaling along the protecting path. "Shared-mesh" restoration + can be seen as a particular case of pre-planned LSP rerouting that + reduces the recovery resource requirements by allowing multiple + protecting LSPs to share common link and node resources. The + recovery resources are pre-reserved but explicit action is + required to activate (i.e., commit resource allocation at the data + plane) a specific protecting LSP instantiated during the (pre-) + provisioning phase. This procedure requires restoration signaling + along the protecting path. + + + + + + +Lang, et al. Standards Track [Page 4] + +RFC 4872 RSVP-TE Extensions for E2E GMPLS Recovery May 2007 + + + Note that in both cases, bandwidth pre-reserved for a protecting + (but not activated) LSP can be made available for carrying extra + traffic. LSPs for extra-traffic (with lower holding priority than + the protecting LSP) can then be established using the bandwidth + pre-reserved for the protecting LSP. Also, any lower priority LSP + that use the pre-reserved resources for the protecting LSP(s) must + be preempted during the activation of the protecting LSP. + + 4) Full LSP rerouting (or restoration) switches normal traffic to an + alternate LSP that is not even partially established until after + the working LSP failure occurs. The new alternate route is + selected at the LSP head-end node, it may reuse resources of the + failed LSP at intermediate nodes and may include additional + intermediate nodes and/or links. + + Crankback signaling (see [CRANK]) and LSP segment recovery (see + [RFC4873]) are further detailed in dedicated companion documents. + +2. 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]. + + In addition, the reader is assumed to be familiar with the + terminology used in [RFC3945], [RFC3471], [RFC3473] and referenced as + well as in [RFC4427] and [RFC4426]. + +3. Relationship to Fast Reroute (FRR) + + There is no impact to RSVP-TE Fast Reroute (FRR) [RFC4090] introduced + by end-to-end GMPLS recovery i.e., it is possible to use either + method defined in FRR with end-to-end GMPLS recovery. + + The objects used and/or newly introduced by end-to-end recovery will + be ignored by [RFC4090] conformant implementations, and FRR can + operate on a per LSP basis as defined in [RFC4090]. + + + + + + + + + + + + + + +Lang, et al. Standards Track [Page 5] + +RFC 4872 RSVP-TE Extensions for E2E GMPLS Recovery May 2007 + + +4. Definitions + +4.1. LSP Identification + + This section reviews terms previously defined in [RFC2205], + [RFC3209], and [RFC3473]. LSP tunnels are identified by a + combination of the SESSION and SENDER_TEMPLATE objects (see also + [RFC3209]). The relevant fields are as follows: + + IPv4 (or IPv6) tunnel endpoint address + + IPv4 (or IPv6) address of the egress node for the tunnel. + + Tunnel ID + + A 16-bit identifier used in the SESSION that remains constant + over the life of the tunnel. + + Extended Tunnel ID + + A 32-bit (or 16-byte) identifier used in the SESSION that + remains constant over the life of the tunnel. Normally set to + all zeros. Ingress nodes that wish to narrow the scope of a + SESSION to the ingress-egress pair MAY place their IPv4 (or + IPv6) address here as a globally unique identifier. + + IPv4 (or IPv6) tunnel sender address + + IPv4 (or IPv6) address for a sender node. + + LSP ID + + A 16-bit identifier used in the SENDER_TEMPLATE and FILTER_SPEC + that can be changed to allow a sender to share resources with + itself. + + The first three fields are carried in the SESSION object (Path and + Resv message) and constitute the basic identification of the LSP + tunnel. + + The last two fields are carried in the SENDER_TEMPLATE (Path message) + and FILTER_SPEC objects (Resv message). The LSP ID is used to + differentiate LSPs that belong to the same LSP Tunnel (as identified + by its Tunnel ID). + + + + + + + +Lang, et al. Standards Track [Page 6] + +RFC 4872 RSVP-TE Extensions for E2E GMPLS Recovery May 2007 + + +4.2. Recovery Attributes + + The recovery attributes include all the parameters that determine the + status of an LSP within the recovery scheme to which it is + associated. These attributes are part of the PROTECTION object + introduced in Section 14. + +4.2.1. LSP Status + + The following bits are used in determining resource allocation and + status of the LSP within the group of LSPs forming the protected + entity: + + - S (Secondary) bit: enables distinction between primary and + secondary LSPs. A primary LSP is a fully established LSP for which + the resource allocation has been committed at the data plane (i.e., + full cross-connection has been performed). Both working and + protecting LSPs can be primary LSPs. A secondary LSP is an LSP + that has been provisioned in the control plane only, and for which + resource selection MAY have been done but for which the resource + allocation has not been committed at the data plane (for instance, + no cross-connection has been performed). Therefore, a secondary + LSP is not immediately available to carry any traffic (thus + requiring additional signaling to be available). A secondary LSP + can only be a protecting LSP. The (data plane) resources allocated + for a secondary LSP MAY be used by other LSPs until the primary LSP + fails over to the secondary LSP. + + - P (Protecting) bit: enables distinction between working and + protecting LSPs. A working LSP must be a primary LSP whilst a + protecting LSP can be either a primary or a secondary LSP. When + protecting LSP(s) are associated with working LSP(s), one also + refers to the latter as protected LSPs. + + Note: The combination "secondary working" is not valid (only + protecting LSPs can be secondary LSPs). Working LSPs are always + primary LSPs (i.e., fully established) whilst primary LSPs can be + either working or protecting LSPs. + + - O (Operational) bit: this bit is set when a protecting LSP is + carrying the normal traffic after protection switching (i.e., + applies only in case of dedicated LSP protection or LSP protection + with extra-traffic; see Section 4.2.2). + + In this document, the PROTECTION object uses as a basis the + PROTECTION object defined in [RFC3471] and [RFC3473] and defines + additional fields within it. The fields defined in [RFC3471] and + [RFC3473] are unchanged by this document. + + + +Lang, et al. Standards Track [Page 7] + +RFC 4872 RSVP-TE Extensions for E2E GMPLS Recovery May 2007 + + +4.2.2. LSP Recovery + + The following classification is used to distinguish the LSP + Protection Type with which LSPs can be associated at end-nodes (a + distinct value is associated with each Protection Type in the + PROTECTION object; see Section 14): + + - Full LSP Rerouting: set if a primary working LSP is dynamically + recoverable using (non pre-planned) head-end rerouting. + + - Pre-planned LSP Rerouting without Extra-traffic: set if a + protecting LSP is a secondary LSP that allows sharing of the pre- + reserved recovery resources between one or more than one + pair. When the secondary LSPs resources are not + pre-reserved for a single pair, this type is + referred to as "shared mesh" recovery. + + - LSP Protection with Extra-traffic: set if a protecting LSP is a + dedicated primary LSP that allows for extra-traffic transport and + thus precludes any sharing of the recovery resources between more + than one pair. This type includes 1:N LSP + protection with extra-traffic. + + - Dedicated LSP Protection: set if a protecting LSP does not allow + sharing of the recovery resources nor the transport of extra- + traffic (implying in the present context, duplication of the signal + over both working and protecting LSPs as in 1+1 dedicated + protection). Note also that this document makes a distinction + between 1+1 unidirectional and bidirectional dedicated LSP + protection. + + For LSP protection, in particular, when the data plane provides + automated protection-switching capability (see for instance ITU-T + [G.841] Recommendation), a Notification (N) bit is defined in the + PROTECTION object. It allows for distinction between protection + switching signaling via the control plane or the data plane. + + Note: this document assumes that Protection Type values have end-to- + end significance and that the same value is sent over the protected + and the protecting path. In this context, shared-mesh (for instance) + appears from the end-nodes perspective as being simply an LSP + rerouting without extra-traffic services. The net result of this is + that a single bit (the S bit alone) does not allow determining + whether resource allocation should be performed with respect to the + status of the LSP within the protected entity. The introduction of + the P bit solves this problem unambiguously. These bits MUST be + processed on a hop-by-hop basis (independently of the LSP Protection + Type context). This allows for an easier implementation of reversion + + + +Lang, et al. Standards Track [Page 8] + +RFC 4872 RSVP-TE Extensions for E2E GMPLS Recovery May 2007 + + + signaling (see Section 12) but also facilitates the transparent + delivery of protected services since any intermediate node is not + required to know the semantics associated with the incoming LSP + Protection Type value. + +4.3. LSP Association + + The ASSOCIATION object, introduced in Section 16, is used to + associate the working and protecting LSPs. + + When used for signaling the working LSP, the Association ID of the + ASSOCIATION object (see Section 16) identifies the protecting LSP. + When used for signaling the protecting LSP, this field identifies the + LSP protected by the protecting LSP. + +5. 1+1 Unidirectional Protection + + One of the simplest notions of end-to-end LSP protection is 1+1 + unidirectional protection. + + Consider the following network topology: + + A---B---C---D + \ / + E---F---G + + The paths [A,B,C,D] and [A,E,F,G,D] are node and link disjoint, + ignoring the ingress/egress nodes A and D. A 1+1 protected path is + established from A to D over [A,B,C,D] and [A,E,F,G,D], and traffic + is transmitted simultaneously over both component paths (i.e., LSPs). + + During the provisioning phase, both LSPs are fully instantiated (and + thus activated) so that no resource sharing can be done along the + protecting LSP (nor can any extra-traffic be transported). It is + also RECOMMENDED to set the N bit since no protection-switching + signaling is assumed in this case. + + When a failure occurs (say, at node B) and is detected at end-node D, + the receiver at D selects the normal traffic from the other LSP. + From this perspective, 1+1 unidirectional protection can be seen as + an uncoordinated protection-switching mechanism acting independently + at both endpoints. Also, for the LSP under failure condition, it is + RECOMMENDED to not set the Path_State_Removed Flag of the ERROR_SPEC + object (see [RFC3473]) upon PathErr message generation. + + Note: it is necessary that both paths are SRLG disjoint to ensure + recoverability; otherwise, a single failure may impact both working + and protecting LSPs. + + + +Lang, et al. Standards Track [Page 9] + +RFC 4872 RSVP-TE Extensions for E2E GMPLS Recovery May 2007 + + +5.1. Identifiers + + To simplify association operations, both LSPs belong to the same + session. Thus, the SESSION object MUST be the same for both LSPs. + The LSP ID, however, MUST be different to distinguish between the two + LSPs. + + A new PROTECTION object (see Section 14) is included in the Path + message. This object carries the desired end-to-end LSP Protection + Type -- in this case, "1+1 Unidirectional". This LSP Protection Type + value is applicable to both uni- and bidirectional LSPs. + + To allow distinguishing the working LSP (from which the signal is + taken) from the protecting LSP, the working LSP is signaled by + setting in the PROTECTION object the S bit to 0, the P bit to 0, and + in the ASSOCIATION object, the Association ID to the protecting + LSP_ID. The protecting LSP is signaled by setting in the PROTECTION + object the S bit to 0, the P bit to 1, and in the ASSOCIATION object, + the Association ID to the associated protected LSP_ID. + + After protection switching completes, and after reception of the + PathErr message, to keep track of the LSP from which the signal is + taken, the protecting LSP SHOULD be signaled with the O bit set. The + formerly working LSP MAY be signaled with the A bit set in the + ADMIN_STATUS object (see [RFC3473]). This process assumes the tail- + end node has notified the head-end node that traffic selection + switchover has occurred. + +6. 1+1 Bidirectional Protection + + 1+1 bidirectional protection is a scheme that provides end-to-end + protection for bidirectional LSPs. + + Consider the following network topology: + + A---B---C---D + \ / + E---F---G + + The LSPs [A,B,C,D] and [A,E,F,G,D] are node and link disjoint, + ignoring the ingress/egress nodes A and D. A bidirectional LSP is + established from A to D over each path, and traffic is transmitted + simultaneously over both LSPs. In this scheme, both endpoints must + receive traffic over the same LSP. Note also that both LSPs are + fully instantiated (and thus activated) so that no resource sharing + can be done along the protection path (nor can any extra-traffic be + transported). + + + + +Lang, et al. Standards Track [Page 10] + +RFC 4872 RSVP-TE Extensions for E2E GMPLS Recovery May 2007 + + + When a failure is detected by one or both endpoints of the LSP, both + endpoints must select traffic from the other LSP. This action must + be coordinated between node A and D. From this perspective, 1+1 + bidirectional protection can be seen as a coordinated protection- + switching mechanism between both endpoints. + + Note: it is necessary that both paths are SRLG disjoint to ensure + recoverability; otherwise, a single failure may impact both working + and protecting LSPs. + +6.1. Identifiers + + To simplify association operations, both LSPs belong to the same + session. Thus, the SESSION object MUST be the same for both LSPs. + The LSP ID, however, MUST be different to distinguish between the two + LSPs. + + A new PROTECTION object (see Section 14) is included in the Path + message. This object carries the desired end-to-end LSP Protection + Type -- in this case, "1+1 Bidirectional". This LSP Protection Type + value is only applicable to bidirectional LSPs. + + It is also desirable to allow distinguishing the working LSP (from + which the signal is taken) from the protecting LSP. This is achieved + for the working LSP by setting in the PROTECTION object the S bit to + 0, the P bit to 0, and in the ASSOCIATION object, the Association ID + to the protecting LSP_ID. The protecting LSP is signaled by setting + in the PROTECTION object the S bit to 0, the P bit to 1, and in the + ASSOCIATION object the Association ID to the associated protected + LSP_ID. + +6.2. End-to-End Switchover Request/Response + + To coordinate the switchover between endpoints, an end-to-end + switchover request/response exchange is needed since a failure + affecting one of the LSPs results in both endpoints switching to the + other LSP (resulting in receiving traffic from the other LSP) in + their respective directions. + + The procedure is as follows: + + 1. If an end-node (A or D) detects the failure of the working LSP + (or a degradation of signal quality over the working LSP) or + receives a Notify message including its SESSION object within + the (see [RFC3473]), and the + new error code/sub-code "Notify Error/ LSP Locally Failed" in + the (IF_ID)_ERROR_SPEC object, it MUST begin receiving on the + protecting LSP. Note that the or is also present in the Notify message that resolves + any ambiguity and race condition since identifying (together + with the SESSION object) the LSP under failure condition. + + Note: (IF_ID)_ERROR_SPEC indicates that either the + ERROR_SPEC (C-Type 1/2) or the ERROR_SPEC (C-Type 3/4, + defined in [RFC3473]) can be used. + + This node MUST reliably send a Notify message, including the + MESSAGE_ID object, to the other end-node (D or A, respectively) + with the new error code/sub-code "Notify Error/LSP Failure" + (Switchover Request) indicating the failure of the working LSP. + This Notify message MUST be sent with the ACK_Desired flag set + in the MESSAGE_ID object to request the receiver to send an + acknowledgment for the message (see [RFC2961]). + + This (switchover request) Notify message MAY indicate the + identity of the failed link or any other relevant information + using the IF_ID ERROR_SPEC object (see [RFC3473]). In this + case, the IF_ID ERROR_SPEC object replaces the ERROR_SPEC + object in the Notify message; otherwise, the corresponding + (data plane) information SHOULD be received in the + PathErr/ResvErr message. + + 2. Upon receipt of the (switchover request) Notify message, the + end-node (D or A, respectively) MUST begin receiving from the + protecting LSP. + + This node MUST reliably send a Notify message, including the + MESSAGE_ID object, to the other end-node (A or D, + respectively). This (switchover response) Notify message MUST + also include a MESSAGE_ID_ACK object to acknowledge reception + of the (switchover request) Notify message. + + This (switchover response) Notify message MAY indicate the + identity of the failed link or any other relevant information + using the IF_ID ERROR_SPEC object (see [RFC3473]). + + Note: upon receipt of the (switchover response) Notify message, + the end-node (A or D, respectively) MUST send an Ack message to + the other end-node to acknowledge its reception. + + Since the intermediate nodes (B, C, E, F, and G) are assumed to be + GMPLS RSVP-TE signaling capable, each node adjacent to the failure + MAY generate a Notify message directed either to the LSP head-end + (upstream direction), or the LSP tail-end (downstream direction), or + even both. Therefore, it is expected that these LSP terminating + nodes (that MAY also detect the failure of the LSP from the data + + + +Lang, et al. Standards Track [Page 12] + +RFC 4872 RSVP-TE Extensions for E2E GMPLS Recovery May 2007 + + + plane) provide either the right correlation mechanism to avoid + repetition of the above procedure or just discard subsequent Notify + messages corresponding to the same Session. In addition, for the LSP + under failure condition, it is RECOMMENDED to not set the Path_State_ + Removed Flag of the ERROR_SPEC object (see [RFC3473]) upon PathErr + message generation. + + After protection switching completes (step 2), and after reception of + the PathErr message, to keep track of the LSP from which the signal + is taken, the protecting LSP SHOULD be signaled with the O bit set. + The formerly working LSP MAY be signaled with the A bit set in the + ADMIN_STATUS object (see [RFC3473]). + + Note: when the N bit is set, the end-to-end switchover request/ + response exchange described above only provides control plane + coordination (no actions are triggered at the data plane level). + +7. 1:1 Protection with Extra-Traffic + + The most common case of end-to-end 1:N protection is to establish, + between the same endpoints, an end-to-end working LSP (thus, N = 1) + and a dedicated end-to-end protecting LSP that are mutually link/ + node/SRLG disjoint. This protects against working LSP failure(s). + + The protecting LSP is used for switchover when the working LSP fails. + GMPLS RSVP-TE signaling allows for the pre-provisioning of protecting + LSPs by indicating in the Path message (in the PROTECTION object; see + Section 14) that the LSPs are of type protecting. Here, working and + protecting LSPs are signaled as primary LSPs; both are fully + instantiated during the provisioning phase. + + Although the resources for the protecting LSP are pre-allocated, + preemptable traffic may be carried end-to-end using this LSP. Thus, + the protecting LSP is capable of carrying extra-traffic with the + caveat that this traffic will be preempted if the working LSP fails. + + The setup of the working LSP SHOULD indicate that the LSP head-end + and tail-end node wish to receive Notify messages using the NOTIFY + REQUEST object. The node upstream to the failure (upstream in terms + of the direction an Path message traverses) SHOULD send a Notify + message to the LSP head-end node, and the node downstream to the + failure SHOULD send an Notify message to the LSP tail-end node. Upon + receipt of the Notify messages, both the end-nodes MUST switch the + (normal) traffic from the working LSP to the pre-configured + protecting LSP (see Section 7.2). Moreover, some coordination is + required if extra-traffic is carried over the end-to-end protecting + + + + + +Lang, et al. Standards Track [Page 13] + +RFC 4872 RSVP-TE Extensions for E2E GMPLS Recovery May 2007 + + + LSP. Note that if the working and the protecting LSP are established + between the same end-nodes, no further notification is required to + indicate that the working LSPs are no longer protected. + + Consider the following topology: + + A---B---C---D + \ / + E---F---G + + The working LSP [A,B,C,D] could be protected by the protecting LSP + [A,E,F,G,D]. Both LSPs are fully instantiated (resources are + allocated for both working and protecting LSPs) and no resource + sharing can be done along the protection path since the primary + protecting LSP can carry extra-traffic. + + Note: it is necessary that both paths are SRLG disjoint to ensure + recoverability; otherwise, a single failure may impact both working + and protecting LSPs. + +7.1. Identifiers + + To simplify association operations, both LSPs belong to the same + session. Thus, the SESSION object MUST be the same for both LSPs. + The LSP ID, however, MUST be different to distinguish between the + protected LSP carrying working traffic and the protecting LSP that + can carry extra-traffic. + + A new PROTECTION object (see Section 14) is included in the Path + message used to set up the two LSPs. This object carries the desired + end-to-end LSP Protection Type -- in this case, "1:N Protection with + Extra-Traffic". This LSP Protection Type value is applicable to both + uni- and bidirectional LSPs. + + The working LSP is signaled by setting in the new PROTECTION object + the S bit to 0, the P bit to 0, and in the ASSOCIATION object, the + Association ID to the protecting LSP_ID. + + The protecting LSP is signaled by setting in the new PROTECTION + object the S bit to 0, the P bit to 1, and in the ASSOCIATION object, + the Association ID to the associated protected LSP_ID. + + + + + + + + + + +Lang, et al. Standards Track [Page 14] + +RFC 4872 RSVP-TE Extensions for E2E GMPLS Recovery May 2007 + + +7.2. End-to-End Switchover Request/Response + + To coordinate the switchover between endpoints, an end-to-end + switchover request/response is needed such that the affected LSP is + moved to the protecting LSP. Protection switching from the working + to the protecting LSP (implying preemption of extra-traffic carried + over the protecting LSP) must be initiated by one of the end-nodes (A + or D). + + The procedure is as follows: + + 1. If an end-node (A or D) detects the failure of the working LSP + (or a degradation of signal quality over the working LSP) or + receives a Notify message including its SESSION object within + the (see [RFC3473]), and the + new error code/sub-code "Notify Error/LSP Locally Failed" in + the (IF_ID)_ERROR_SPEC object, it disconnects the extra-traffic + from the protecting LSP. Note that the or + is also present in the Notify message that + resolves any ambiguity and race condition since identifying + (together with the SESSION object) the LSP under failure + condition. + + This node MUST reliably send a Notify message, including the + MESSAGE_ID object, to the other end-node (D or A, respectively) + with the new error code/sub-code "Notify Error/LSP Failure" + (Switchover Request) indicating the failure of the working LSP. + This Notify message MUST be sent with the ACK_Desired flag set + in the MESSAGE_ID object to request the receiver to send an + acknowledgment for the message (see [RFC2961]). + + This (switchover request) Notify message MAY indicate the + identity of the failed link or any other relevant information + using the IF_ID ERROR_SPEC object (see [RFC3473]). In this + case, the IF_ID ERROR_SPEC object replaces the ERROR_SPEC + object in the Notify message; otherwise, the corresponding + (data plane) information SHOULD be received in the + PathErr/ResvErr message. + + 2. Upon receipt of the (switchover request) Notify message, the + end-node (D or A, respectively) MUST disconnect the extra- + traffic from the protecting LSP and begin sending/receiving + normal traffic out/from the protecting LSP. + + This node MUST reliably send a Notify message, including the + MESSAGE_ID object, to the other end-node (A or D, + respectively). This (switchover response) Notify message MUST + + + + +Lang, et al. Standards Track [Page 15] + +RFC 4872 RSVP-TE Extensions for E2E GMPLS Recovery May 2007 + + + also include a MESSAGE_ID_ACK object to acknowledge reception + of the (switchover request) Notify message. + + This (switchover response) Notify message MAY indicate the + identity of the failed link or any other relevant information + using the IF_ID ERROR_SPEC object (see [RFC3473]). + + Note: since the Notify message generated by the other end-node + (A or D, respectively) is distinguishable from the one + generated by an intermediate node, there is no possibility of + connecting the extra-traffic to the working LSP due to the + receipt of a Notify message from an intermediate node. + + 3. Upon receipt of the (switchover response) Notify message, the + end-node (A or D, respectively) MUST begin receiving normal + traffic from or sending normal traffic out the protecting LSP. + + This node MUST also send an Ack message to the other end-node + (D or A, respectively) to acknowledge the reception of the + (switchover response) Notify message. + + Note 1: a 2-phase protection-switching signaling is used in the + present context; a 3-phase signaling (see [RFC4426]) that would imply + a notification message, a switchover request, and a switchover + response messages is not considered here. Also, when the protecting + LSPs do not carry extra-traffic, protection-switching signaling (as + defined in Section 6.2) MAY be used instead of the procedure + described in this section. + + Note 2: when the N bit is set, the above end-to-end switchover + request/response exchange only provides control plane coordination + (no actions are triggered at the data plane level). + + After protection switching completes (step 3), and after reception of + the PathErr message, to keep track of the LSP from which the normal + traffic is taken, the protecting LSP SHOULD be signaled with the O + bit set. In addition, the formerly working LSP MAY be signaled with + the A bit set in the ADMIN_STATUS object (see [RFC3473]). + +7.3. 1:N (N > 1) Protection with Extra-Traffic + + 1:N (N > 1) protection with extra-traffic assumes that the fully + provisioned protecting LSP is resource-disjoint from the N working + LSPs. This protecting LSP thereby allows for carrying extra-traffic. + Note that the N working LSPs and the protecting LSP are all between + the same pair of endpoints. In addition, the N working LSPs + (considered as identical in terms of traffic parameters) MAY be + + + + +Lang, et al. Standards Track [Page 16] + +RFC 4872 RSVP-TE Extensions for E2E GMPLS Recovery May 2007 + + + mutually resource-disjoint. Coordination between end-nodes is + required when switching from one of the working to the protecting + LSP. + + Each working LSP is signaled with both S bit and P bit set to 0. The + LSP Protection Type is set to 0x04 (1:N Protection with Extra- + Traffic) during LSP setup. Each Association ID points to the + protecting LSP ID. + + The protecting LSP (carrying extra-traffic) is signaled with the S + bit set to 0 and the P bit set to 1. The LSP Protection Type is set + to 0x04 (1:N Protection with Extra-Traffic) during LSP setup. The + Association ID MUST be set by default to the LSP ID of the protected + LSP corresponding to N = 1. + + Any signaling procedure applicable to 1:1 protection with extra- + traffic equally applies to 1:N protection with extra-traffic. + +8. Rerouting without Extra-Traffic + + End-to-end (pre-planned) rerouting without extra-traffic relies on + the establishment between the same pair of end-nodes of a working LSP + and a protecting LSP that is link/node/SRLG disjoint from the working + LSP. However, in this case the protecting LSP is not fully + instantiated; thus, it cannot carry any extra-traffic (note that this + does not mean that the corresponding resources cannot be used by + other LSPs). Therefore, this mechanism protects against working LSP + failure(s) but requires activation of the protecting LSP after + failure occurrence. + + Signaling is performed by indicating in the Path message (in the + PROTECTION object; see Section 14) that the LSPs are of type working + and protecting, respectively. Protecting LSPs are used for fast + switchover when working LSPs fail. In this case, working and + protecting LSPs are signaled as primary LSP and secondary LSP, + respectively. Thus, only the working LSP is fully instantiated + during the provisioning phase, and for the protecting LSPs, no + resources are committed at the data plane level (they are pre- + reserved at the control plane level only). The setup of the working + LSP SHOULD indicate (using the NOTIFY REQUEST object as specified in + Section 4 of [RFC3473]) that the LSP head-end node (and possibly the + tail-end node) wish to receive a Notify message upon LSP failure + occurrence. Upon receipt of the Notify message, the head-end node + MUST switch the (normal) traffic from the working LSP to the + protecting LSP after its activation. Note that since the working and + the protecting LSPs are established between the same end-nodes, no + further notification is required to indicate that the working LSPs + are without protection. + + + +Lang, et al. Standards Track [Page 17] + +RFC 4872 RSVP-TE Extensions for E2E GMPLS Recovery May 2007 + + + To make bandwidth pre-reserved for a protecting (but not activated) + LSP available for extra-traffic, this bandwidth could be included in + the advertised Unreserved Bandwidth at priority lower (means + numerically higher) than the Holding Priority of the protecting LSP. + In addition, the Max LSP Bandwidth field in the Interface Switching + Capability Descriptor sub-TLV should reflect the fact that the + bandwidth pre-reserved for the protecting LSP is available for extra + traffic. LSPs for extra-traffic then can be established using the + bandwidth pre-reserved for the protecting LSP by setting (in the Path + message) the Setup Priority field of the SESSION_ATTRIBUTE object to + X (where X is the Setup Priority of the protecting LSP), and the + Holding Priority field to at least X+1. Also, if the resources pre- + reserved for the protecting LSP are used by lower-priority LSPs, + these LSPs MUST be preempted when the protecting LSP is activated + (see Section 10). + + Consider the following topology: + + A---B---C---D + \ / + E---F---G + + The working LSP [A,B,C,D] could be protected by the protecting LSP + [A,E,F,G,D]. Only the protected LSP is fully instantiated (resources + are only allocated for the working LSP). Therefore, the protecting + LSP cannot carry any extra-traffic. When a failure is detected on + the working LSP (say, at B), the error is propagated and/or notified + (using a Notify message with the new error code/sub-code "Notify + Error/LSP Locally Failed" in the (IF_ID)_ERROR_SPEC object) to the + ingress node (A). Upon reception, the latter activates the secondary + protecting LSP instantiated during the (pre-)provisioning phase. + This requires: + + (1) the ability to identify a "secondary protecting LSP" (hereby + called the "secondary LSP") used to recover another primary + working LSP (hereby called the "protected LSP") + (2) the ability to associate the secondary LSP with the protected + LSP + (3) the capability to activate a secondary LSP after failure + occurrence. + + In the following subsections, these features are described in more + detail. + + + + + + + + +Lang, et al. Standards Track [Page 18] + +RFC 4872 RSVP-TE Extensions for E2E GMPLS Recovery May 2007 + + +8.1. Identifiers + + To simplify association operations, both LSPs (i.e., the protected + and the secondary LSPs) belong to the same session. Thus, the + SESSION object MUST be the same for both LSPs. The LSP ID, however, + MUST be different to distinguish between the protected LSP carrying + working traffic and the secondary LSP that cannot carry extra- + traffic. + + A new PROTECTION object (see Section 14) is used to set up the two + LSPs. This object carries the desired end-to-end LSP Protection Type + (in this case, "Rerouting without Extra-Traffic"). This LSP + Protection Type value is applicable to both uni- and bidirectional + LSPs. + +8.2. Signaling Primary LSPs + + The new PROTECTION object is included in the Path message during + signaling of the primary working LSP, with the end-to-end LSP + Protection Type value set to "Rerouting without Extra-Traffic". + + Primary working LSPs are signaled by setting in the new PROTECTION + object the S bit to 0, the P bit to 0, and in the ASSOCIATION object, + the Association ID to the associated secondary protecting LSP_ID. + +8.3. Signaling Secondary LSPs + + The new PROTECTION object is included in the Path message during + signaling of secondary protecting LSPs, with the end-to-end LSP + Protection Type value set to "Rerouting without Extra-Traffic". + + Secondary protecting LSPs are signaled by setting in the new + PROTECTION object the S bit and the P bit to 1, and in the + ASSOCIATION object, the Association ID to the associated primary + working LSP_ID, which MUST be known before signaling of the secondary + LSP. + + With this setting, the resources for the secondary LSP SHOULD be + pre-reserved, but not committed at the data plane level, meaning that + the internals of the switch need not be established until explicit + action is taken to activate this secondary LSP. Activation of a + secondary LSP is done using a modified Path message with the S bit + set to 0 in the PROTECTION object. At this point, the link and node + resources must be allocated for this LSP that becomes a primary LSP + (ready to carry normal traffic). + + + + + + +Lang, et al. Standards Track [Page 19] + +RFC 4872 RSVP-TE Extensions for E2E GMPLS Recovery May 2007 + + + From [RFC3945], the secondary LSP is set up with resource pre- + reservation but with or without label pre-selection (both allowing + sharing of the recovery resources). In the former case (defined as + the default), label allocation during secondary LSP signaling does + not require any specific procedure compared to [RFC3473]. However, + in the latter case, label (and thus resource) re-allocation MAY occur + during the secondary LSP activation. This means that during the LSP + activation phase, labels MAY be reassigned (with higher precedence + over existing label assignment; see also [RFC3471]). + + Note: under certain circumstances (e.g., when pre-reserved protecting + resources are used by lower-priority LSPs), it MAY be desirable to + perform the activation of the secondary LSP in the upstream direction + (Resv trigger message) instead of using the default downstream + activation. In this case, any mis-ordering and any mis- + interpretation between a refresh Resv (along the lower-priority LSP) + and a trigger Resv message (along the secondary LSP) MUST be avoided + at any intermediate node. For this purpose, upon reception of the + Path message, the egress node MAY include the PROTECTION object in + the Resv message. The latter is then processed on a hop-by-hop basis + to activate the secondary LSP until reaching the ingress node. The + PROTECTION object included in the Path message MUST be set as + specified in this section. In this case, the PROTECTION object with + the S bit MUST be set to 0 and included in the Resv message sent in + the upstream direction. The upstream activation behavior SHOULD be + configurable on a local basis. Details concerning lower-priority LSP + preemption upon secondary LSP activation are provided in Section 10. + +9. Shared-Mesh Restoration + + An approach to reduce recovery resource requirements is to have + protection LSPs sharing network resources when the working LSPs that + they protect are physically (i.e., link, node, SRLG, etc.) disjoint. + This mechanism is referred to as shared mesh restoration and is + described in [RFC4426]. Shared-mesh restoration can be seen as a + particular case of pre-planned LSP rerouting (see Section 8) that + reduces the recovery resource requirements by allowing multiple + protecting LSPs to share common link and node resources. Here also, + the recovery resources for the protecting LSPs are pre-reserved + during the provisioning phase, thus an explicit signaling action is + required to activate (i.e., commit resource allocation at the data + plane) a specific protecting LSP instantiated during the (pre-) + provisioning phase. This requires restoration signaling along the + protecting LSP. + + To make bandwidth pre-reserved for a protecting (but not activated) + LSP, available for extra-traffic this bandwidth could be included in + the advertised Unreserved Bandwidth at priority lower (means + + + +Lang, et al. Standards Track [Page 20] + +RFC 4872 RSVP-TE Extensions for E2E GMPLS Recovery May 2007 + + + numerically higher) than the Holding Priority of the protecting LSP. + In addition, the Max LSP Bandwidth field in the Interface Switching + Capability Descriptor sub-TLV should reflect the fact that the + bandwidth pre-reserved for the protecting LSP is available for extra + traffic. LSPs for extra-traffic then can be established using the + bandwidth pre-reserved for the protecting LSP by setting (in the Path + message) the Setup Priority field of the SESSION_ATTRIBUTE object to + X (where X is the Setup Priority of the protecting LSP) and the + Holding Priority field to at least X+1. Also, if the resources pre- + reserved for the protecting LSP are used by lower priority LSPs, + these LSPs MUST be preempted when the protecting LSP is activated + (see Section 10). Further, if the recovery resources are shared + between multiple protecting LSPs, the corresponding working LSPs + head-end nodes must be informed that they are no longer protected + when the protecting LSP is activated to recover the normal traffic + for the working LSP under failure. + + Consider the following topology: + + A---B---C---D + \ / + E---F---G + / \ + H---I---J---K + + The working LSPs [A,B,C,D] and [H,I,J,K] could be protected by + [A,E,F,G,D] and [H,E,F,G,K], respectively. Per [RFC3209], in order + to achieve resource sharing during the signaling of these protecting + LSPs, they must have the same Tunnel Endpoint Address (as part of + their SESSION object). However, these addresses are not the same in + this example. Resource sharing along E, F, and G can only be + achieved if the nodes E, F, and G recognize that the LSP Protection + Type of the secondary LSP is set to "Rerouting without Extra-Traffic" + (see PROTECTION object, Section 14) and acts accordingly. In this + case, the protecting LSPs are not merged (which is useful since the + paths diverge at G), but the resources along E, F, G can be shared. + + When a failure is detected on one of the working LSPs (say, at B), + the error is propagated and/or notified (using a Notify message with + the new error code/sub-code "Notify Error/LSP Locally Failed" in the + (IF_ID)_ERROR_SPEC object) to the ingress node (A). Upon reception, + the latter activates the secondary protecting LSP (see Section 8). + At this point, it is important that a failure on the other LSP (say, + at J) does not cause the other ingress (H) to send the data down the + protecting LSP since the resources are already in use. This can be + achieved by node E using the following procedure. When the capacity + is first reserved for the protecting LSP, E should verify that the + LSPs being protected ([A,B,C,D] and [H,I,J,K], respectively) do not + + + +Lang, et al. Standards Track [Page 21] + +RFC 4872 RSVP-TE Extensions for E2E GMPLS Recovery May 2007 + + + share any common resources. Then, when a failure occurs (say, at B) + and the protecting LSP [A,E,F,G,D] is activated, E should notify H + that the resources for the protecting LSP [H,E,F,G,K] are no longer + available. + + The following subsections detail how shared mesh restoration can be + implemented in an interoperable fashion using GMPLS RSVP-TE + extensions (see [RFC3473]). This includes: + + (1) the ability to identify a "secondary protecting LSP" (hereby + called the "secondary LSP") used to recover another primary + working LSP (hereby called the "protected LSP") + (2) the ability to associate the secondary LSP with the protected + LSP + (3) the capability to include information about the resources used + by the protected LSP while instantiating the secondary LSP. + (4) the capability to instantiate during the provisioning phase + several secondary LSPs in an efficient manner. + (5) the capability to activate a secondary LSP after failure + occurrence. + + In the following subsections, these features are described in detail. + +9.1. Identifiers + + To simplify association operations, both LSPs (i.e., the protected + and the secondary LSPs) belong to the same session. Thus, the + SESSION object MUST be the same for both LSPs. The LSP ID, however, + MUST be different to distinguish between the protected LSP carrying + working traffic and the secondary LSP that cannot carry extra- + traffic. + + A new PROTECTION object (see Section 14) is used to set up the two + LSPs. This object carries the desired end-to-end LSP Protection Type + -- in this case, "Rerouting without Extra-Traffic". This LSP + Protection Type value is applicable to both uni- and bidirectional + LSPs. + +9.2. Signaling Primary LSPs + + The new PROTECTION object is included in the Path message during + signaling of the primary working LSPs, with the end-to-end LSP + Protection Type value set to "Rerouting without Extra-Traffic". + + Primary working LSPs are signaled by setting in the new PROTECTION + object the S bit to 0, the P bit to 0, and in the ASSOCIATION object, + the Association ID to the associated secondary protecting LSP_ID. + + + + +Lang, et al. Standards Track [Page 22] + +RFC 4872 RSVP-TE Extensions for E2E GMPLS Recovery May 2007 + + +9.3. Signaling Secondary LSPs + + The new PROTECTION object is included in the Path message during + signaling of the secondary protecting LSPs, with the end-to-end LSP + Protection Type value set to "Rerouting without Extra-Traffic". + + Secondary protecting LSPs are signaled by setting in the new + PROTECTION object the S bit and the P bit to 1, and in the + ASSOCIATION object, the Association ID to the associated primary + working LSP_ID, which MUST be known before signaling of the secondary + LSP. Moreover, the Path message used to instantiate the secondary + LSP SHOULD include at least one PRIMARY_PATH_ROUTE object (see + Section 15) that further allows for recovery resource sharing at each + intermediate node along the secondary path. + + With this setting, the resources for the secondary LSP SHOULD be + pre-reserved, but not committed at the data plane level, meaning that + the internals of the switch need not be established until explicit + action is taken to activate this LSP. Activation of a secondary LSP + is done using a modified Path message with the S bit set to 0 in the + PROTECTION object. At this point, the link and node resources must + be allocated for this LSP that becomes a primary LSP (ready to carry + normal traffic). + + From [RFC3945], the secondary LSP is set up with resource pre- + reservation but with or without label pre-selection (both allowing + sharing of the recovery resources). In the former case (defined as + the default), label allocation during secondary LSP signaling does + not require any specific procedure compared to [RFC3473]. However, + in the latter case, label (and thus resource) re-allocation MAY occur + during the secondary LSP activation. This means that, during the LSP + activation phase, labels MAY be reassigned (with higher precedence + over existing label assignment; see also [RFC3471]). + +10. LSP Preemption + + When protecting resources are only pre-reserved for the secondary + LSPs, they MAY be used to set up lower-priority LSPs. In this case, + these resources MUST be preempted when the protecting LSP is + activated. An additional condition raises from misconnection + avoidance between the secondary protecting LSP being activated and + the low-priority LSP(s) being preempted. Procedure to be applied + when the secondary protecting LSP (i.e., the preempting LSP) Path + message reaches a node using the resources for lower-priority LSP(s) + (i.e., preempted LSP(s)) is as follows: + + + + + + +Lang, et al. Standards Track [Page 23] + +RFC 4872 RSVP-TE Extensions for E2E GMPLS Recovery May 2007 + + + 1. De-allocate resources to be used by the preempting LSP and release + the cross-connection. Note that if the preempting LSP is + bidirectional, these resources may come from one or two lower- + priority LSPs, and if from two LSPs, they may be uni- or bi- + directional. The preempting node SHOULD NOT send the Path message + before the de-allocation of resources has completed since this may + lead to the downstream path becoming misconnected if the + downstream node is able to reassign the resources more quickly. + + 2. Send PathTear and PathErr messages with the new error code/sub- + code "Policy Control failure/Hard preempted" and the + Path_State_Removed flag set for the preempted LSP(s). + + 3. Reserve the preempted resources for the protecting LSP. The + preempting node MUST NOT cross-connect the upstream resources of a + bidirectional preempting LSP. + + 4. Send the Path message. + + 5. Upon reception of a trigger Resv message from the downstream node, + cross-connect the downstream path resources, and if the preempting + LSP is bidirectional, perform cross-connection for the upstream + path resources. + + Note that step 1 may cause alarms to be raised for the preempted LSP. + If alarm suppression is desired, the preempting node MAY insert the + following steps before step 1. + + 1a. Before de-allocating resources, send a Resv message, including an + ADMIN_STATUS object, to disable alarms for the preempted LSP. + 1b. Receive a Path message indicating that alarms are disabled. + + At the downstream node (with respect to the preempting LSP), the + processing is RECOMMENDED to be as follows: + + 1. Receive PathTear (and/or PathErr) message for the preempted + LSP(s). + + 2a. Release the resources associated with the LSP on the interface to + the preempting LSP, remove any cross-connection, and release all + other resources associated with the preempted LSP. + 2b. Forward the PathTear (and/or PathErr) message per [RFC3473]. + + 3. Receive the Path message for the preempting LSP and process as + normal, forwarding it to the downstream node. + + 4. Receive the Resv message for the preempting LSP and process as + normal, forwarding it to the upstream node. + + + +Lang, et al. Standards Track [Page 24] + +RFC 4872 RSVP-TE Extensions for E2E GMPLS Recovery May 2007 + + +11. (Full) LSP Rerouting + + LSP rerouting, on the other hand, switches normal traffic to an + alternate LSP that is fully established only after failure + occurrence. The new (alternate) route is selected at the LSP head- + end and may reuse intermediate nodes included in the original route; + it may also include additional intermediate nodes. For strict-hop + routing, TE requirements can be directly applied to the route + computation, and the failed node or link can be avoided. However, if + the failure occurred within a loose-routed hop, the head-end node may + not have enough information to reroute the LSP around the failure. + Crankback signaling (see [CRANK]) and route exclusion techniques (see + [RFC4874]) MAY be used in this case. + + The alternate route MAY be either computed on demand (that is, when + the failure occurs; this is referred to as full LSP rerouting) or + pre-computed and stored for use when the failure is reported. The + latter offers faster restoration time. There is, however, a risk + that the alternate route will become out of date through other + changes in the network; this can be mitigated to some extent by + periodic recalculation of idle alternate routes. + + (Full) LSP rerouting will be initiated by the head-end node that has + either detected the LSP failure or received a Notify message and/or a + PathErr message with the new error code/sub-code "Notify Error/LSP + Locally Failed" for this LSP. The new LSP resources can be + established using the make-before-break mechanism, where the new LSP + is set up before the old LSP is torn down. This is done by using the + mechanisms of the SESSION_ATTRIBUTE object and the Shared-Explicit + (SE) reservation style (see [RFC3209]). Both the new and old LSPs + can share resources at common nodes. + + Note that the make-before-break mechanism is not used to avoid + disruption to the normal traffic flow (the latter has already been + broken by the failure that is being repaired). However, it is + valuable to retain the resources allocated on the original LSP that + will be reused by the new alternate LSP. + +11.1. Identifiers + + The Tunnel Endpoint Address, Tunnel ID, Extended Tunnel ID, and + Tunnel Sender Address uniquely identify both the old and new LSPs. + Only the LSP_ID value differentiates the old from the new alternate + LSP. The new alternate LSP is set up before the old LSP is torn down + using Shared-Explicit (SE) reservation style. This ensures that the + new (alternate) LSP is established without double-counting resource + requirements along common segments. + + + + +Lang, et al. Standards Track [Page 25] + +RFC 4872 RSVP-TE Extensions for E2E GMPLS Recovery May 2007 + + + The alternate LSP MAY be set up before any failure occurrence with + SE-style resource reservation, the latter shares the same Tunnel End + Point Address, Tunnel ID, Extended Tunnel ID, and Tunnel Sender + Address with the original LSP (i.e., only the LSP ID value MUST be + different). + + In both cases, the Association ID of the ASSOCIATION object MUST be + set to the LSP ID value of the signaled LSP. + +11.2. Signaling Reroutable LSPs + + A new PROTECTION object is included in the Path message during + signaling of dynamically reroutable LSPs, with the end-to-end LSP + Protection Type value set to "Full Rerouting". These LSPs that can + be either uni- or bidirectional are signaled by setting in the + PROTECTION object the S bit to 0, the P bit to 0, and the Association + ID value to the LSP_ID value of the signaled LSP. Any specific + action to be taken during the provisioning phase is up to the end- + node local policy. + + Note: when the end-to-end LSP Protection Type is set to + "Unprotected", both S and P bit MUST be set to 0, and the LSP SHOULD + NOT be rerouted at the head-end node after failure occurrence. The + Association_ID value MUST be set to the LSP_ID value of the signaled + LSP. This does not mean that the Unprotected LSP cannot be re- + established for other reasons such as path re-optimization and + bandwidth adjustment driven by policy conditions. + +12. Reversion + + Reversion refers to a recovery switching operation, where the normal + traffic returns to (or remains on) the working LSP when it has + recovered from the failure. Reversion implies that resources remain + allocated to the LSP that was originally routed over them even after + a failure. It is important to have mechanisms that allow reversion + to be performed with minimal service disruption and reconfiguration. + + For "1+1 bidirectional Protection", reversion to the recovered LSP + occurs by using the following sequence: + + 1. Clear the A bit of the ADMIN_STATUS object if set for the + recovered LSP. + + 2. Then, apply the method described below to switch normal traffic + back from the protecting to the recovered LSP. This is performed + by using the new error code/sub-code "Notify Error/LSP Recovered" + (Switchback Request). + + + + +Lang, et al. Standards Track [Page 26] + +RFC 4872 RSVP-TE Extensions for E2E GMPLS Recovery May 2007 + + + The procedure is as follows: + + 1) The initiating (source) node sends the normal traffic onto both + the working and the protecting LSPs. Once completed, the + source node sends reliably a Notify message to the destination + with the new error code/sub-code "Notify Error/LSP Recovered" + (Switchback Request). This Notify message includes the + MESSAGE_ID object. The ACK_Desired flag MUST be set in this + object to request the receiver to send an acknowledgment for + the message (see [RFC2961]). + + 2) Upon receipt of this message, the destination selects the + traffic from the working LSP. At the same time, it transmits + the traffic onto both the working and protecting LSP. + + The destination then sends reliably a Notify message to the + source confirming the completion of the operation. This + message includes the MESSAGE_ID_ACK object to acknowledge + reception of the received Notify message. This Notify message + also includes the MESSAGE_ID object. The ACK_Desired flag MUST + be set in this object to request the receiver to send an + acknowledgment for the message (see [RFC2961]). + + 3) When the source node receives this Notify message, it switches + to receive traffic from the working LSP. + + The source node then sends an Ack message to the destination + node confirming that the LSP has been reverted. + + 3. Finally, clear the O bit of the PROTECTION object sent over the + protecting LSP. + + For "1:N Protection with Extra-traffic", reversion to the recovered + LSP occurs by using the following sequence: + + 1. Clear the A bit of the ADMIN_STATUS object if set for the + recovered LSP. + + 2. Then, apply the method described below to switch normal traffic + back from the protecting to the recovered LSP. This is performed + by using the new error code/sub-code "Notify Error/LSP Recovered" + (Switchback Request). + + The procedure is as follows: + + 1) The initiating (source) node sends the normal traffic onto both + the working and the protecting LSPs. Once completed, the + source node sends reliably a Notify message to the destination + + + +Lang, et al. Standards Track [Page 27] + +RFC 4872 RSVP-TE Extensions for E2E GMPLS Recovery May 2007 + + + with the new error code/sub-code "Notify Error/LSP Recovered" + (Switchback Request). This Notify message includes the + MESSAGE_ID object. The ACK_Desired flag MUST be set in this + object to request the receiver to send an acknowledgment for + the message (see [RFC2961]). + + 2) Upon receipt of this message, the destination selects the + traffic from the working LSP. At the same time, it transmits + the traffic onto both the working and protecting LSP. + + The destination then sends reliably a Notify message to the + source confirming the completion of the operation. This + message includes the MESSAGE_ID_ACK object to acknowledge + reception of the received Notify message. This Notify message + also includes the MESSAGE_ID object. The ACK_Desired flag MUST + be set in this object to request the receiver to send an + acknowledgment for the message (see [RFC2961]). + + 3) When the source node receives this Notify message, it switches + to receive traffic from the working LSP, and stops transmitting + traffic on the protecting LSP. + + The source node then sends an Ack message to the destination + node confirming that the LSP has been reverted. + + 4) Upon receipt of this message, the destination node stops + transmitting traffic along the protecting LSP. + + 3. Finally, clear the O bit of the PROTECTION object sent over the + protecting LSP. + + For "Rerouting without Extra-traffic" (including the shared recovery + case), reversion implies that the formerly working LSP has not been + torn down by the head-end node upon PathErr message reception, i.e., + the head-end node kept refreshing the working LSP under failure + condition. This ensures that the exact same resources are retrieved + after reversion switching (except if the working LSP required re- + signaling). Re-activation is performed using the following sequence: + + 1. Clear the A bit of the ADMIN_STATUS object if set for the + recovered LSP. + + 2. Then, apply the method described below to switch normal traffic + back from the protecting to the recovered LSP. This is performed + by using the new error code/sub-code "Notify Error/LSP Recovered" + (Switchback Request). + + + + + +Lang, et al. Standards Track [Page 28] + +RFC 4872 RSVP-TE Extensions for E2E GMPLS Recovery May 2007 + + + The procedure is as follows: + + 1) The initiating (source) node sends the normal traffic onto both + the working and the protecting LSPs. Once completed, the + source node sends reliably a Notify message to the destination + with the new error code/sub-code "Notify Error/LSP Recovered" + (Switchback Request). This Notify message includes the + MESSAGE_ID object. The ACK_Desired flag MUST be set in this + object to request the receiver to send an acknowledgment for + the message (see [RFC2961]). + + 2) Upon receipt of this message, the destination selects the + traffic from the working LSP. At the same time, it transmits + the traffic onto both the working and protecting LSP. + + The destination then sends reliably a Notify message to the + source confirming the completion of the operation. This + message includes the MESSAGE_ID_ACK object to acknowledge + reception of the received Notify message. This Notify message + also includes the MESSAGE_ID object. The ACK_Desired flag MUST + be set in this object to request the receiver to send an + acknowledgment for the message (see [RFC2961]). + + 3) When the source node receives this Notify message, it switches + to receive traffic from the working LSP, and stops transmitting + traffic on the protecting LSP. + + The source node then sends an Ack message to the destination + node confirming that the LSP has been reverted. + + 4) Upon receipt of this message, the destination node stops + transmitting traffic along the protecting LSP. + + 3. Finally, de-activate the protecting LSP by setting the S bit to 1 + in the PROTECTION object sent over the protecting LSP. + +13. Recovery Commands + + This section specifies the control plane behavior when using several + commands (see [RFC4427]) that can be used to influence the recovery + operations. + + A. Lockout of recovery LSP: + + The Lockout (L) bit of the ADMIN_STATUS object is used following the + rules defined in Section 8 of [RFC3471] and Section 7 of [RFC3473]. + The L bit must be set together with the Reflect (R) bit in the + ADMIN_STATUS object sent in the Path message. Upon reception of the + + + +Lang, et al. Standards Track [Page 29] + +RFC 4872 RSVP-TE Extensions for E2E GMPLS Recovery May 2007 + + + Resv message with the L bit set, this forces the recovery LSP to be + temporarily unavailable to transport traffic (either normal or + extra-traffic). Unlock is performed by clearing the L bit, following + the rules defined in Section 7 of [RFC3473]. This procedure is only + applicable when the LSP Protection Type Flag is set to either 0x04 + (1:N Protection with Extra-Traffic), or 0x08 (1+1 Unidirectional + Protection), or 0x10 (1+1 Bidirectional Protection). + + The updated format of the ADMIN_STATUS object to include the L bit is + as follows: + + 0 1 2 3 + 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | Length | Class-Num(196)| C-Type (1) | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + |R| Reserved |L|I|C|T|A|D| + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + + Lockout (L): 1 bit + + When set, forces the recovery LSP to be temporarily unavailable + to transport traffic (either normal or extra traffic). + + The R (Reflect), T (Testing), A (Administratively down), and D + (Deletion in progress) bits are defined in [RFC3471]. The C (Call + control) bit is defined in [GMPLS-CALL], and the I (Inhibit alarm + communication) bit in [RFC4783]. + + B. Lockout of normal traffic: + + The O bit of the PROTECTION object is set to 1 to force the recovery + LSP to be temporarily unavailable to transport normal traffic. This + operation MUST NOT occur unless the working LSP is carrying the + normal traffic. Unlock is performed by clearing the O bit over the + protecting LSP. This procedure is only applicable when the LSP + Protection Type Flag is set to either 0x04 (1:N Protection with + Extra-Traffic), or 0x08 (1+1 Unidirectional Protection), or 0x10 (1+1 + Bidirectional Protection). + + C. Forced switch for normal traffic: + + Recovery signaling is initiated that switches normal traffic to the + recovery LSP following the procedures defined in Section 6, 7, 8, and + 9. + + + + + + +Lang, et al. Standards Track [Page 30] + +RFC 4872 RSVP-TE Extensions for E2E GMPLS Recovery May 2007 + + + D. Requested switch for normal traffic: + + Recovery signaling is initiated that switches normal traffic to the + recovery LSP following the procedures defined in Section 6, 7, 8, and + 9. This happens unless a fault condition exists on other LSPs or + spans (including the recovery LSP), or a switch command of equal or + higher priority is in effect. + + E. Requested switch for recovery LSP: + + Recovery signaling is initiated that switches normal traffic to the + working LSP following the procedure defined in Section 12. This + request is executed except if a fault condition exists on the working + LSP or an equal or higher priority switch command is in effect. + +14. PROTECTION Object + + This section describes the extensions to the PROTECTION object to + broaden its applicability to end-to-end LSP recovery. + +14.1. Format + + The format of the PROTECTION Object (Class-Num = 37, C-Type = 2) is + as follows: + + 0 1 2 3 + 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | Length | Class-Num(37) | C-Type (2) | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + |S|P|N|O| Reserved | LSP Flags | Reserved | Link Flags| + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | Reserved | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + + Secondary (S): 1 bit + + When set to 1, this bit indicates that the requested LSP is a + secondary LSP. When set to 0 (default), it indicates that the + requested LSP is a primary LSP. + + Protecting (P): 1 bit + + When set to 1, this bit indicates that the requested LSP is a + protecting LSP. When set to 0 (default), it indicates that the + requested LSP is a working LSP. The combination, S set to 1 + with P set to 0 is not valid. + + + + +Lang, et al. Standards Track [Page 31] + +RFC 4872 RSVP-TE Extensions for E2E GMPLS Recovery May 2007 + + + Notification (N): 1 bit + + When set to 1, this bit indicates that the control plane + message exchange is only used for notification during + protection switching. When set to 0 (default), it indicates + that the control plane message exchanges are used for + protection-switching purposes. The N bit is only applicable + when the LSP Protection Type Flag is set to either 0x04 (1:N + Protection with Extra-Traffic), or 0x08 (1+1 Unidirectional + Protection), or 0x10 (1+1 Bidirectional Protection). The N bit + MUST be set to 0 in any other case. + + Operational (O): 1 bit + + When set to 1, this bit indicates that the protecting LSP is + carrying the normal traffic after protection switching. The O + bit is only applicable when the P bit is set to 1, and the LSP + Protection Type Flag is set to either 0x04 (1:N Protection with + Extra-Traffic), or 0x08 (1+1 Unidirectional Protection) or 0x10 + (1+1 Bidirectional Protection). The O bit MUST be set to 0 in + any other case. + + Reserved: 5 bits + + This field is reserved. It MUST be set to zero on transmission + and MUST be ignored on receipt. These bits SHOULD be passed + through unmodified by transit nodes. + + LSP (Protection Type) Flags: 6 bits + + Indicates the desired end-to-end LSP recovery type. A value of + 0 implies that the LSP is "Unprotected". Only one value SHOULD + be set at a time. The following values are defined. All other + values are reserved. + + 0x00 Unprotected + 0x01 (Full) Rerouting + 0x02 Rerouting without Extra-Traffic + 0x04 1:N Protection with Extra-Traffic + 0x08 1+1 Unidirectional Protection + 0x10 1+1 Bidirectional Protection + + Reserved: 10 bits + + This field is reserved. It MUST be set to zero on transmission + and MUST be ignored on receipt. These bits SHOULD be passed + through unmodified by transit nodes. + + + + +Lang, et al. Standards Track [Page 32] + +RFC 4872 RSVP-TE Extensions for E2E GMPLS Recovery May 2007 + + + Link Flags: 6 bits + + Indicates the desired link protection type (see [RFC3471]). + + Reserved field: 32 bits + + Encoding of this field is detailed in [RFC4873]. + +14.2. Processing + + Intermediate and egress nodes processing a Path message containing a + PROTECTION object MUST verify that the requested LSP Protection Type + can be satisfied by the incoming interface. If it cannot, the node + MUST generate a PathErr message, with the new error code/sub-code + "Routing problem/Unsupported LSP Protection". + + Intermediate nodes processing a Path message containing a PROTECTION + object with the LSP Protection Type 0x02 (Rerouting without Extra- + Traffic) value set and a PRIMARY_PATH_ROUTE object (see Section 15) + MUST verify that the requested LSP Protection Type can be supported + by the outgoing interface. If it cannot, the node MUST generate a + PathErr message with the new error code/sub-code "Routing + problem/Unsupported LSP Protection". + +15. PRIMARY_PATH_ROUTE Object + + The PRIMARY_PATH_ROUTE object (PPRO) is defined to inform nodes along + the path of a secondary protecting LSP about which resources + (link/nodes) are being used by the associated primary protected LSP + (as specified by the Association ID field). If the LSP Protection + Type value is set to 0x02 (Rerouting without Extra-Traffic), this + object SHOULD be present in the Path message for the pre-provisioning + of the secondary protecting LSP to enable recovery resource sharing + between one or more secondary protecting LSPs (see Section 9). This + document does not assume or preclude any other usage for this object. + + PRIMARY_PATH_ROUTE objects carry information extracted from the + EXPLICIT ROUTE object and/or the RECORD ROUTE object of the primary + working LSPs they protect. Selection of the PPRO content is up to + local policy of the head-end node that initiates the request. + Therefore, the information included in these objects can be used as + policy-based admission control to ensure that recovery resources are + only shared between secondary protecting LSPs whose associated + primary LSPs have link/node/SRLG disjoint paths. + + + + + + + +Lang, et al. Standards Track [Page 33] + +RFC 4872 RSVP-TE Extensions for E2E GMPLS Recovery May 2007 + + +15.1. Format + + The primary path route is specified via the PRIMARY_PATH_ROUTE object + (PPRO). The Primary Path Route Class Number (Class-Num) of form + 0bbbbbbb 38. + + Currently one C-Type (Class-Type) is defined, Type 1, Primary Path + Route. The PRIMARY_PATH_ROUTE object has the following format: + + Class-Num = 38 (of the form 0bbbbbbb), C-Type = 1 + + 0 1 2 3 + 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | | + // (Subobjects) // + | | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + + The contents of a PRIMARY_PATH_ROUTE object are a series of + variable-length data items called subobjects (see Section 15.3). + + To signal a secondary protecting LSP, the Path message MAY include + one or multiple PRIMARY_PATH_ROUTE objects, where each object is + meaningful. The latter is useful when a given secondary protecting + LSP must be link/node/SRLG disjoint from more than one primary LSP + (i.e., is protecting more than one primary LSP). + +15.2. Subobjects + + The PRIMARY_PATH_ROUTE object is defined as a list of variable-length + data items called subobjects. These subobjects are derived from the + subobjects of the EXPLICIT ROUTE and/or RECORD ROUTE object of the + primary working LSP(s). + + Each subobject has its own length field. The length contains the + total length of the subobject in bytes, including the Type and Length + fields. The length MUST always be a multiple of 4, and at least 4. + + The following subobjects are currently defined for the + PRIMARY_PATH_ROUTE object: + + - Sub-Type 1: IPv4 Address (see [RFC3209]) + - Sub-Type 2: IPv6 Address (see [RFC3209]) + - Sub-Type 3: Label (see [RFC3473]) + - Sub-Type 4: Unnumbered Interface (see [RFC3477]) + + + + + +Lang, et al. Standards Track [Page 34] + +RFC 4872 RSVP-TE Extensions for E2E GMPLS Recovery May 2007 + + + An empty PPRO with no subobjects is considered illegal. If there is + no first subobject, the corresponding Path message is also in error, + and the receiving node SHOULD return a PathErr message with the new + error code/sub-code "Routing Problem/Bad PRIMARY_PATH_ROUTE object". + + Note: an intermediate node processing a PPRO can derive SRLG + identifiers from the local IGP-TE database using its Type 1, 2, or 4 + subobject values as pointers to the corresponding TE Links (assuming + each of them has an associated SRLG TE attribute). + +15.3. Applicability + + The PRIMARY_PATH_ROUTE object MAY only be used when all GMPLS nodes + along the path support the PRIMARY_PATH_ROUTE object and a secondary + protecting LSP is being requested. The PRIMARY_PATH_ROUTE object is + assigned a class value of the form 0bbbbbbb. Receiving GMPLS nodes + along the path that do not support this object MUST return a PathErr + message with the "Unknown Object Class" error code (see [RFC2205]). + + Also, the following restrictions MUST be applied with respect to the + PPRO usage: + + - PPROs MAY only be included in Path messages when signaling + secondary protecting LSPs (S bit = 1 and P bit = 1) and when the + LSP Protection Type value is set to 0x02 (without Rerouting Extra- + Traffic) in the PROTECTION object (see Section 14). + + - PRROs SHOULD be present in the Path message for the pre- + provisioning of the secondary protecting LSP to enable recovery + resource sharing between one or more secondary protecting LSPs (see + Section 15.4). + + - PPROs MUST NOT be used in any other conditions. In particular, if + a PPRO is received when the S bit is set to 0 in the PROTECTION + object, the receiving node MUST return a PathErr message with the + new error code/sub-code "Routing Problem/PRIMARY_PATH_ROUTE object + not applicable". + + - Crossed exchanges of PPROs over primary LSPs are forbidden (i.e., + their usage is restricted to a single set of protected LSPs). + + - The PPRO's content MUST NOT include subobjects coming from other + PPROs. In particular, received PPROs MUST NOT be reused to + establish other working or protecting LSPs. + + + + + + + +Lang, et al. Standards Track [Page 35] + +RFC 4872 RSVP-TE Extensions for E2E GMPLS Recovery May 2007 + + +15.4. Processing + + The PPRO enables sharing recovery resources between a given secondary + protecting LSP and one or more secondary protecting LSPs if their + corresponding primary working LSPs have mutually (link/node/SRLG) + disjoint paths. Consider a node N through which n secondary + protecting LSPs (say, P[1],...,P[n]) have already been established + that protect n primary working LSPs (say, P'[1],...,P'[n]). Suppose + also that these n secondary working LSPs share a given outgoing link + resource (say r). + + Now, suppose that node N receives a Path message for an additional + secondary protecting LSP (say, Q, protecting Q'). The PPRO carried + by this Path message is processed as follows: + + - N checks whether the primary working LSPs P'[1],...,P'[n] + associated with the LSPs P[1],...,P[n], respectively, have any + link, node, and SLRG in common with the primary working Q' + (associated with Q) by comparing the stored PPRO subobjects + associated with P'[1],...,P'[n] with the PPRO subobjects associated + with Q' received in the Path message. + + - If this is the case, N SHOULD NOT attempt to share the outgoing + link resource r between P[1],...,P[n] and Q. However, upon local + policy decision, N MAY allocate another available (shared) link + other than r for use by Q. If this is not the case (upon the local + policy decision that no other link is allowed to be allocated for + Q) or if no other link is available for Q, N SHOULD return a + PathErr message with the new error code/sub-code "Admission Control + Failure/LSP Admission Failure". + + - Otherwise (if P'[1],...,P'[n] and Q' are fully disjoint), the link + r selected by N for the LSP Q MAY be exactly the same as the one + selected for the LSPs P[1],...,P[n]. This happens after verifying + (from the node's local policy) that the selected link r can be + shared between these LSPs. If this is not the case (for instance, + the sharing ratio has reached its maximum for that link), and if + upon local policy decision, no other link is allowed to be + allocated for Q, N SHOULD return a PathErr message with the error + code/sub-code "Admission Control Failure/Requested Bandwidth + Unavailable" (see [RFC2205]). Otherwise (if no other link is + available), N SHOULD return a PathErr message with the new error + code/sub-code "Admission Control Failure/LSP Admission Failure". + + Note that the process, through which m out of the n (m =< n) + secondary protecting LSPs' PPROs may be selected on a local basis to + perform the above comparison and subsequent link selection, is out of + scope of this document. + + + +Lang, et al. Standards Track [Page 36] + +RFC 4872 RSVP-TE Extensions for E2E GMPLS Recovery May 2007 + + +16. ASSOCIATION Object + + The ASSOCIATION object is used to associate LSPs with each other. In + the context of end-to-end LSP recovery, the association MUST only + identify LSPs that support the same Tunnel ID as well as the same + tunnel sender address and tunnel endpoint address. The Association + Type, Association Source, and Association ID fields of the object + together uniquely identify an association. The object uses an object + class number of the form 11bbbbbb to ensure compatibility with non- + supporting nodes. + + The ASSOCIATION object is used to associate LSPs with each other. + +16.1. Format + + The IPv4 ASSOCIATION object (Class-Num of the form 11bbbbbb with + value = 199, C-Type = 1) has the format: + + 0 1 2 3 + 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | Length | Class-Num(199)| C-Type (1) | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | Association Type | Association ID | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | IPv4 Association Source | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + + The IPv6 ASSOCIATION object (Class-Num of the form 11bbbbbb with + value = 199, C-Type = 2) has the format: + + 0 1 2 3 + 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | Length | Class-Num(199)| C-Type (2) | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | Association Type | Association ID | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | | + | IPv6 Association Source | + | | + | | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + + + + + + + + +Lang, et al. Standards Track [Page 37] + +RFC 4872 RSVP-TE Extensions for E2E GMPLS Recovery May 2007 + + + Association Type: 16 bits + + Indicates the type of association being identified. Note that + this value is considered when determining association. The + following are values defined in this document. + + Value Type + ----- ---- + 0 Reserved + 1 Recovery (R) + + Association ID: 16 bits + + A value assigned by the LSP head-end. When combined with the + Association Type and Association Source, this value uniquely + identifies an association. + + Association Source: 4 or 16 bytes + + An IPv4 or IPv6 address, respectively, that is associated to + the node that originated the association. + +16.2. Processing + + In the end-to-end LSP recovery context, the ASSOCIATION object is + used to associate a recovery LSP with the LSP(s) it is protecting or + a protected LSP(s) with its recovery LSP. The object is carried in + Path messages. More than one object MAY be carried in a single Path + message. + + Transit nodes MUST transmit, without modification, any received + ASSOCIATION object in the corresponding outgoing Path message. + + An ASSOCIATION object with an Association Type set to the value + "Recovery" is used to identify an LSP-Recovery-related association. + Any node associating a recovery LSP MUST insert an ASSOCIATION object + with the following setting: + + - The Association Type MUST be set to the value "Recovery" in the + Path message of the recovery LSP. + + - The (IPv4/IPv6) Association Source MUST be set to the tunnel sender + address of the LSP being protected. + + + + + + + + +Lang, et al. Standards Track [Page 38] + +RFC 4872 RSVP-TE Extensions for E2E GMPLS Recovery May 2007 + + + - The Association ID MUST be set to the LSP ID of the LSP being + protected by this LSP or the LSP protecting this LSP. If unknown, + this value is set to its own signaled LSP_ID value (default). + Also, the value of the Association ID MAY change during the + lifetime of the LSP. + + Terminating nodes use received ASSOCIATION object(s) with the + Association Type set to the value "Recovery" to associate a recovery + LSP with its matching working LSP. This information is used to bind + the appropriate working and recovery LSPs together. Such nodes MUST + ensure that the received Path messages, including ASSOCIATION + object(s), are processed with the appropriate PROTECTION object + settings, if present (see Section 14 for PROTECTION object + processing). Otherwise, this node MUST return a PathErr message with + the new error code/sub-code "LSP Admission Failure/Bad Association + Type". Similarly, terminating nodes receiving a Path message with a + + PROTECTION object requiring association between working and recovery + LSPs MUST include an ASSOCIATION object. Otherwise, such nodes MUST + return a PathErr message with the new error code/sub-code "Routing + Problem/PROTECTION object not Applicable". + +17. Updated RSVP Message Formats + + This section presents the RSVP message-related formats as modified by + this document. Unmodified RSVP message formats are not listed. + + The format of a Path message is as follows: + + ::= [ ] + [ [ | ] ... ] + [ ] + + + [ ] + + [ ] + [ ... ] + [ ] + [ ... ] + [ ] + [ ... ] + [ ... ] + [ ... ] + + + The format of the for unidirectional and + bidirectional LSPs is not modified by the present document. + + + +Lang, et al. Standards Track [Page 39] + +RFC 4872 RSVP-TE Extensions for E2E GMPLS Recovery May 2007 + + + The format of a Resv message is as follows: + + ::= [ ] + [ [ | ] ... ] + [ ] + + + [ ] [ ] + [ ] + [ ] + [ ] + [ ... ] +