CCAMP Working Group Xian Zhang Internet Draft Haomian Zheng, Ed. Intended Status: Informational Huawei Rakesh Gandhi, Ed. Zafar Ali Gabriele Maria Galimberti Cisco Systems, Inc. Pawel Brzozowski ADVA Optical Expires: March 12, 2015 September 12, 2014 RSVP-TE Signaling Procedure for GMPLS Restoration and Resource Sharing- based LSP Setup/Teardown draft-zhang-ccamp-gmpls-resource-sharing-proc-02 Abstract In transport networks, there are requirements where Generalized Multi-Protocol Label Switching (GMPLS) end-to-end recovery scheme needs to employ restoration Label Switched Path (LSP) while keeping resources for the working and/or restoration LSPs reserved in the network after the failure occurs. This document reviews how the LSP association is to be provided using Resource Reservation Protocol - Traffic Engineering (RSVP-TE) signaling in the context of GMPLS end-to-end recovery when using restoration LSP where failed LSP is not torn down. In addition, this document compliments existing standards by explaining the missing pieces of information during the RSVP-TE signaling procedure in support of resource sharing-based LSP setup/teardown in GMPLS- controlled circuit networks. No new procedures or mechanisms are defined by this document, and it is strictly informative in nature. Status of this Memo This Internet-Draft is submitted to IETF in full conformance with the provisions of BCP 78 and BCP 79. Internet-Drafts are working documents of the Internet Engineering Task Force (IETF), its areas, and its working groups. Note that other groups may also distribute working documents as Internet- Drafts. Zhang, et al Expires March 2015 [Page 1] draft-zhang-ccamp-gmpls-resource-sharing-proc September 2014 Internet-Drafts are draft documents valid for a maximum of six months and may be updated, replaced, or obsoleted by other documents at any time. It is inappropriate to use Internet-Drafts as reference material or to cite them other than as "work in progress." The list of current Internet-Drafts can be accessed at http://www.ietf.org/ietf/1id-abstracts.txt. The list of Internet-Draft Shadow Directories can be accessed at http://www.ietf.org/shadow.html. This Internet-Draft will expire on March 12th, 2015. Copyright Notice Copyright (c) 2014 IETF Trust and the persons identified as the document authors. All rights reserved. This document is subject to BCP 78 and the IETF Trust's Legal Provisions Relating to IETF Documents (http://trustee.ietf.org/license-info) in effect on the date of publication of this document. Please review these documents carefully, as they describe your rights and restrictions with respect to this document. Code Components extracted from this document must include Simplified BSD License text as described in Section 4.e of the Trust Legal Provisions and are provided without warranty as described in the Simplified BSD License. Table of Contents 1. Introduction ................................................ 3 2. Problem Statement ........................................... 4 2.1. GMPLS Restoration ....................................... 5 2.1.1. 1+R Restoration .................................... 5 2.1.2. 1+1+R Restoration .................................. 5 2.2. Resource Sharing-based LSP Setup/Teardown ............... 6 3. RSVP-TE Signaling For Restoration LSP Association ............ 7 4. RSVP-TE Signaling Procedure For Resource Sharing During LSP Setup/Teardown ................................................. 8 4.1. LSPs with the Identical Tunnel ID ....................... 8 4.1.1. LSP Setup ......................................... 9 4.1.2. LSP Reversion ..................................... 11 4.1.3. LSP Re-optimization Setup and Reversion ........... 13 Zhang, et al. Expires March 2015 [Page 2] draft-zhang-ccamp-gmpls-resource-sharing-proc September 2014 4.2. LSPs with Different Tunnel IDs ......................... 13 5. Security Considerations ..................................... 14 6. IANA Considerations ........................................ 14 7. Acknowledgement ............................................ 14 8. References ................................................. 14 8.1. Normative References ................................... 14 8.2. Informative References ................................. 15 9. Authors' Addresses ......................................... 16 1. Introduction Generalized Multiprotocol Label Switching (GMPLS) [RFC3945] defines a set of protocols, including Open Shortest Path First - Traffic Engineering (OSPF-TE) [RFC4203] and Resource ReserVation Protocol - Traffic Engineering (RSVP-TE) [RFC3473]. These protocols can be used to create Label Switched Paths (LSPs) in a number of deployment scenarios with various transport technologies. The GMPLS protocol set extends MPLS, which supports only Packet Switch Capable (PSC) and Layer 2 Switch Capable interfaces (L2SC), to also cater for interfaces capable of Time Division Multiplexing (TDM), Lambda Switching and Fiber Switching. These switching technologies provide several protection schemes [RFC4426][RFC4427] (e.g., 1+1, 1:N and M:N). Resource Reservation Protocol - Traffic Engineering (RSVP-TE) signaling has been extended to support various GMPLS recovery schemes [RFC4872][RFC4873], to establish Label Switched Paths (LSPs), typically for working LSP and protecting LSP. [RFC4427] Section 7 specifies various schemes for GMPLS recovery. In GMPLS recovery schemes generally considered, restoration LSP is signaled after the failure has been detected and notified on the working LSP. In non-revertive recovery mode, working LSP is assumed to be removed from the network before restoration LSP is signaled. For revertive recovery mode, a restoration LSP is signaled while working LSP and/or protecting LSP are not torn down in control plane due to a failure. In transport networks, as working LSPs are typically signaled over a nominal path, service providers would like to keep resources associated with the working LSPs reserved. This is to make sure that the service (working LSP) can use the nominal path when the failure is repaired to provide deterministic behaviour and guaranteed Service Level Agreement (SLA). Consequently, revertive recovery mode is usually preferred by recovery schemes used in transport networks. The Make-Before-Break (MBB) exploiting the Shared-Explicit (SE) reservation style can be employed in MPLS networks to avoid double Zhang, et al. Expires March 2015 [Page 3] draft-zhang-ccamp-gmpls-resource-sharing-proc September 2014 booking of resource during the process of LSP reoptimization as specified in [RFC3209]. This method is also used in GMPLS-controlled networks [RFC4872] [RFC4873] for end-to-end and segment recoveries of LSPs. This was further generalized to support resource sharing oriented applications in MPLS networks as well as non-LSP contexts, as specified in [RFC6780]. Due to the fact that the features of GMPLS-controlled networks (specifically for TDM, LSC and FSC), are not identical to that of the MPLS networks, additional considerations for resource sharing based LSP association are needed. As defined in [RFC4872] and being considered in this document, "fully dynamic rerouting switches normal traffic to an alternate LSP that is not even partially established only 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." During the signaling procedure for resource sharing based LSP setup/teardown, the behaviors of the nodes along the path may be different from that in the MPLS networks as well as the effect it may have on the traffic delivery. As described in [RFC6689], ASSOCIATION object is used to identify the LSPs for restoration using association type "Recovery" [RFC4872] and for resource sharing using association type "Resource Sharing" [RFC4873]. This document reviews the signaling procedure for resource sharing- based LSP setup/teardown for GMPLS-based circuit networks. This includes the node behavior description, besides clarifying some un- discussed points for this process. Two typical examples mentioned in this document are LSP restoration and LSP re-optimization, where it is desirable to share resources. This document does not define any RSVP-TE signaling extensions. If necessary, discussions may be provided to identify potential extensions to the existing RSVP-TE protocol. It is expected that the extensions, if there are any, will be addressed in separate documents. 2. Problem Statement GMPLS restoration schemes and resource sharing-based LSP setup/teardown are described in this section. Zhang, et al. Expires March 2015 [Page 4] draft-zhang-ccamp-gmpls-resource-sharing-proc September 2014 2.1. GMPLS Restoration 2.1.1. 1+R Restoration One example of the recovery scheme considered in this document is 1+R recovery. The 1+R recovery is exemplified in Figure 1. In this example, working LSP on path A-B-C-Z is pre-established. Typically after a failure detection and notification on the working LSP, a second LSP on path A-H-I-J-Z is established as a restoration LSP. Unlike protection LSP, restoration LSP is signaled per need basis. A --- B --- C --- Z \ / H --- I --- J Figure 1: An example of 1+R recovery scheme During failure switchover with 1+R recovery scheme, in general, working LSP resources are not released and working and restoration LSPs coexist in the network. Nonetheless, working and restoration LSPs can share network resources. Typically when failure is recovered on the working LSP, restoration LSP is no longer required and torn down (e.g., revertive mode). 2.1.2. 1+1+R Restoration Another example of the recovery scheme considered in this document is 1+1+R. In 1+1+R, a restoration LSP is signaled for the working LSP and/or the protecting LSP after the failure has been detected and notified on the working LSP or the protecting LSP. The 1+1+R recovery is exemplified in Figure 2. D --- E --- F / \ A --- B --- C --- Z \ / H --- I --- J Figure 2: An example of 1+1+R recovery scheme Zhang, et al. Expires March 2015 [Page 5] draft-zhang-ccamp-gmpls-resource-sharing-proc September 2014 In this example, working LSP on path A-B-C-Z and protecting LSP on path A-D-E-F-Z are pre-established. After a failure detection and notification on a working LSP or protecting LSP, a third LSP on path A-H-I-J-Z is established as a restoration LSP. The restoration LSP in this case provides protection against a second order failure. Restoration LSP is torn down when the failure on the working or protecting LSP is repaired. [RFC4872] Section 14 defines PROTECTION object for GMPLS recovery signaling. As defined, the PROTECTION object is used to identify primary and secondary LSPs using S bit and protecting and working LSPs using P bit. Furthermore, [RFC4872] defines the usage of ASSOCIATION object for associating GMPLS working and protecting LSPs. [RFC6689] Section 2.2 reviews the procedure for providing LSP associations for GMPLS end-to-end recovery and covers the schemes where the failed working LSP and/or protecting LSP are torn down. This document reviews how the LSP association is to be provided for GMPLS end-to-end recovery when using restoration LSP where working and protecting LSP resources are kept reserved in the network after the failure. 2.2. Resource Sharing-based LSP Setup/Teardown +-----+ +------+ | F +------+ G +-------+ +--+--+ +------+ | | | | | +-----+ +-----+ +--+--+ +-----+ +--+--+ | A +----+ B +-----+ C +--X---+ D +-----+ E | +-----+ +-----+ +-----+ +-----+ +-----+ Figure 3: A Simple OTN Network Using the network shown in Figure 3 as an example, LSP1 (A-B-C-D-E) is the working LSP and it allows for resource sharing when the LSP is dynamically rerouted due to link failure. Upon detecting the failure of a link along the LSP1, e.g. Link C-D, node A needs to decide to which alternative path it will establish to reroute the traffic. In this case, A-B-C-F-G-E is chosen as the alternative path and the resource on the path segment A-B-C is re-used by this to-be- established path. Since this is an OTN network, different from packet-switching network, the label has a mapping into the data plane Zhang, et al. Expires March 2015 [Page 6] draft-zhang-ccamp-gmpls-resource-sharing-proc September 2014 resource used and also the nodes along the path needs to send triggering commands to data plane nodes for setting up cross- connection accordingly during the RSVP-TE signaling process. So, the following issues are left un-described in the existing standards for resource sharing based LSP setup/teardown in GMPLS-controlled circuit networks: o The purpose of using SE can still be fulfilled? As described in [RFC3209], the purpose of make before break (MBB) is to "not disrupt traffic or adversely impact network operations while TE tunnel rerouting is in progress". Due to the nature of the GMPLS- controlled circuit networks, the first point may not be able to be fulfilled under certain scenarios. Thus, the name "make before break" may no longer holds true and worth discussion. o Is the current defined MBB method sufficient in support of resource shared-based LSP setup/teardown? In [RFC3209], the MBB method assumes the old and new LSPs share the same tunnel ID (i.e., sharing the same source and destination nodes). [RFC4873] does not impose this constraint but limit the resource sharing usage in LSP recoveries only. [RFC6780] generalizes the resource sharing application, based on the ASSOCIATION object, to be useful in MPLS networks as well as in non-LSP association such as Voice Call Waiting. Recently, there are also requirements to generalize resource sharing of LSP with different tunnel IDs, such as the one mentioned in [PCEP-RSO] and LSPs with LSP-stitching across multi-domains. Thus, how the signaling process can make intermediate nodes be aware of this resource sharing constraint and behavior accordingly is an issue that needs to be described and discussed. o Other issues such as what is the reservation style assigned to the original LSP, and what is the node behavior during the traffic reversion, in the GMPLS-controlled circuit networks, are missing and should be clarified. 3. RSVP-TE Signaling For Restoration LSP Association Where GMPLS end-to-end recovery scheme needs to employ restoration LSP while keeping resources for the working and/or protecting LSPs reserved in the network after the failure, restoration LSP is signaled with ASSOCIATION object that has association type set to "Recovery" [RFC4872] with the association ID set to the LSP ID of the LSP it is restoring. For example, when a restoration LSP is signaled for a working LSP, the ASSOCIATION object in the restoration LSP Zhang, et al. Expires March 2015 [Page 7] draft-zhang-ccamp-gmpls-resource-sharing-proc September 2014 contains the association ID set to the LSP ID of the working LSP. Similarly, when a restoration LSP is signaled for a protecting LSP, the ASSOCIATION object in the restoration LSP contains the association ID set to the LSP ID of the protecting LSP. The procedure for signaling the PROTECTION object is specified in [RFC4872]. Specifically, restoration LSP being used as a working LSP is signaled with P bit cleared and being used as a protecting LSP is signaled with P bit set. As discussed in Section 1 of this document, [RFC6689] Section 2.2 reviews the procedure for providing LSP associations for the GMPLS end-to-end recovery scheme using restoration LSP where the failed working LSP and/or protecting LSP are torn down. 4. RSVP-TE Signaling Procedure For Resource Sharing During LSP Setup/Teardown For LSP restoration upon failure, as explained in Section 11 of [RFC4872], the purpose of using MBB is to re-use existing resource. Thus, the behavior of the intermediate nodes during rerouting process will not impact on traffic since it has been interrupted due to the already broken working LSP. However, for the following two cases, the behavior of intermediate nodes may impact the traffic delivery: (1) LSP reversion; (2) LSP optimization. Another dimension that needs separate attention is how to correlate the two LSPs sharing resource. For the ones sharing same tunnel ID, the majority description is provided in existing standards [RFC3209] [RFC4872]. For the LSPs with different Tunnel IDs, signaling procedure is clarified in this section. 4.1. LSPs with Identical Tunnel ID For resource sharing among LSPs with identical tunnel IDs, SE flag and ASSOCIATION object are used together. The former is to enable sharing and the ASSOCIATION object with association type "Resource Sharing" [RFC4873] is to identify the two associated LSPs. As a first step, in order to allow resource sharing, the original LSP setup should explicitly carry the SE flag in the SESSION_ATTRIBUTE object during the initial LSP setup, irrespective of the purpose of resource sharing. The basic signaling procedure for alternative LSP setup has been described by existing standards. In [RFC3209], it describes the Zhang, et al. Expires March 2015 [Page 8] draft-zhang-ccamp-gmpls-resource-sharing-proc September 2014 basic MBB signaling flow for MPLS-TE networks. [RFC4872] adds additional information when using MBB for LSP rerouting. As mentioned before, for LSP setup/teardown in GMPLS-controlled circuit networks, the network elements along the path need to send cross-connection setup/teardown commands to data plane node(s) either during the PATH message forwarding phase or the RESV message forwarding phase. 4.1.1. LSP Setup For LSP restoration, the complete signaling flow processes for both LSP restorations upon failure and LSP reversion upon link failure recovery are described. Table 1: Node Behavior during LSP Restoration Setup ---------+--------------------------------------------------------- Category | Node Behavior during LSP Reversion ---------+--------------------------------------------------------- C1 + Reusing existing resource on both input and output + interfaces. + This type of nodes only needs to book the existing + resource when receiving the PATH message and no cross- + connection setup command is needed when receiving + the RESV message. ---------+--------------------------------------------------------- C2 + Reusing existing resource only on one of the interfaces, + either input or output interfaces and need to use new + resource on the other interface. + This type of nodes needs to book the resource on the + interface where new resource are needed and re-use the + existing resource on the other interface when it receives + the PATH message. Upon receiving the RESV message, it + needs to send the re-configuration the cross-connection + command to its corresponding data plane node. ---------+--------------------------------------------------------- C3 + Using new resource on both interfaces. + This type of nodes needs to book the new resource when + receiving PATH and send the cross-connection setup + command upon receiving RESV. ---------+--------------------------------------------------------- Zhang, et al. Expires March 2015 [Page 9] draft-zhang-ccamp-gmpls-resource-sharing-proc September 2014 For LSP rerouting upon working LSP failure, using the network shown in Figure 3 as an example. Working LSP: A-B-C-D-E Restoration LSP: A-B-C-F-G-E The restoration LSP may be calculated by the head end nodes or a Path Computation Element (PCE) [RFC4655]. Assume that the cross- connection configuration command is sent by the control plane nodes during the RESV forwarding phrase, the node behavior for setting up the alternative LSP can be categorized into the three categories shown in Table 1. +---+ +---+ +---+ +---+ +---+ +---+ | A | | B | | C | | F | | G | | E | +-+-+ +-+-+ +-+-+ +-+-+ +-+-+ +-+-+ | | | | | | | PATH | | | | | C1 +----------X+ C1 | | | | | | | | | | | | PATH | | | | | +----------X+ C2 | | | | | | PATH | | | | | +----------X+ C3 | | | | | | PATH | | | | | +----------X|C3 | | | | | | PATH | | | | | +------------X+ C3 | | | | | | | | | | | RESV | | | | | C3+X------------+ C3 | | | | RESV | | | | | C3 +X----------+ | | | | RESV | | | | | C2+X----------+ | | | | RESV | | | | | C1 +X----------+ | | | | RESV | | | | | C1 +X----------+ | | | | | | Figure 4: Restoration LSP Setup Signaling Procedure Zhang, et al. Expires March 2015 [Page 10] draft-zhang-ccamp-gmpls-resource-sharing-proc September 2014 As shown in Figure 4, depending on whether the resource is re-used or not, the node behaviors differ. This deviates from normal LSP setup since some nodes do not need to re-configure the cross-connection, and thus should not be viewed as an error. Also, the judgment whether the control plane node needs to send a cross-connection setup/modification command to its corresponding data plane node(s) relies on the check whether the following two cases holds true: (1) the PATH message received include a SE reservation style; (2) the PATH message identifies a LSP that sharing the same tunnel ID as the LSP to share resource with. For the second point, the processing rules and configuration of ASSOCATION object defined in [RFC4872] are followed. 4.1.2. LSP Reversion If the LSP rerouting is revertive, which is a common requirement in transport networks [LSP-restoration], the traffic will be reverted to the working LSP if its failure is recovered. The three types of nodes classified above also have different behaviors during the process for tearing down the alternative LSP, as explained in Table 2. Table 2: Node Behavior during LSP Reversion ---------+--------------------------------------------------------- Category | Node Behavior during LSP Reversion ---------+--------------------------------------------------------- D1 + Resource reused on both interfaces. + When receiving PATH-TEAR, it only deletes the alternative + LSP state info in the control plane without changing the + cross-connection. ---------+---------------------------------------------------------- D2 + Resource reused on only one interface. + When receiving PATH-TEAR, it deletes the alternative path + state information in the control plane as well as release + the resource on the interface that is not re-used between + the working and Restoration LSP. ---------+---------------------------------------------------------- D3 + No resources are reused. + When receiving PATH-TEAR, it deletes the state information + related to the alternative LSP as well as tears down the + cross-connection to release the resource. ---------+---------------------------------------------------------- Zhang, et al. Expires March 2015 [Page 11] draft-zhang-ccamp-gmpls-resource-sharing-proc September 2014 It is worth noting there are both interruptions during the rerouting and reverting procedure. Note that before the working LSP failure recovers, the LSP in the control plane is still running and also it views the data plane resource still belongs to the working LSP. However, the re-used resource also belongs to the alternative LSP and these resources are actually used by the alternative LSP. So when the working LSP recovers, it needs to fresh the signaling messages to re-establish the working LSP cross-connection. The process would be similar to that shown in Figure 4, but running along the nodes on the working LSP path (i.e., A-B-C-D-E). Note this will interrupt the traffic delivery on the alternative LSP (i.e., Making the working LSP While Breaking the alternative LSP). This point is different from that of the MPLS networks. If no traffic interruption is mandated, mechanisms to ensure that the traffic can still be delivered should be employed and is outside the scope of this document. Figure 5 shows the signaling process of the alternative LSP teardown during the LSP reversion. Similar to that of the alternative LSP setup process, the nodes may not need to reconfigure the cross- connection and the rationale is similar to that described above. For alarm-free LSP deletion in optical networks, the mechanisms described in Section 6 of [RFC4208] should be followed. +---+ +---+ +---+ +---+ +---+ +---+ | A | | B | | C | | F | | G | | E | +-+-+ +-+-+ +-+-+ +-+-+ +-+-+ +-+-+ | | | | | | | PATHTEAR | | | | | D1 +----------X+ D1 | | | | | | | | | | | | PATHTEAR | | | | | +----------X+ D2 | | | | | | PATHTEAR | | | | | +----------X+ D3 | | | | | | PATHTEAR | | | | | +----------X|D3 | | | | | | PATHTEAR | | | | | +------------X+ D3 | | | | | | Figure 5: Tear-down of Alternative LSP for LSP Reversion Zhang, et al. Expires March 2015 [Page 12] draft-zhang-ccamp-gmpls-resource-sharing-proc September 2014 4.1.3. LSP Re-optimization Setup and Reversion For LSP re-optimization where the new LSP and old LSPs share resource, the signaling flow for new LSP setup and old LSP teardown is similar to that are shown in Figure 4 and 5. The issue that should be noted is the traffic will be disrupted if the new path setup process changes the cross-connection configuration of the nodes along the old LSP. If no traffic interruption is desirable, it should either ensure that the old and new LSP does not share the resource other than the source and destination nodes or using other mechanisms. This is out the scope of this document. 4.2. LSPs with Different Tunnel IDs For two LSPs with different Tunnel IDs, the ASSOCIATION object is used to both specify they are sharing resource (by setting ASSOCIATION type as "Resource Sharing" (value 2) as well as identify these correlated LSPs. There are two types: (1) sharing the common nodes, such as segment recovery, the source and destination nodes of the segment recovery LSP is the intermediate nodes along the working LSPs; (2) resource sharing is used in a generalized context (such as multi-layer or multi-domain networks); it may result in either sharing source nodes in common, or destination nodes in common, or non end points in common, if viewed from one domain's perspective. The path computation can either be performed by the source node or edge nodes for the path/path segment or carried out by the PCE, such as the one explained in [PCEP-RSO]. This document does not impose any constraint with regard to path computation. In [RFC4873], it only considers resource sharing for LSP segment recovery. The ASSOCIATION object configuration is limited. [RFC6780] extends the usage of ASSOCIATION objects to cover generalized resource sharing applications. The extended ASSOCIATION object is primarily defined for MPLS-TP, but it can be applied in a wider scope [RFC6780]. It can be used in the second types mentioned above. The configuration and processing rules of extended ASSOCIATION object defined in [RFC6780] should be obeyed. The only issue that need pay attention to is that uniqueness of LSP association for the second type should be guaranteed when crossing the layer or domain boundary. The mechanisms for how to ensure this are outside of the scope of this document. Other than this, the signaling flow for this type of resource sharing is similar to description provided in Section 4.1.1. Similar to what Zhang, et al. Expires March 2015 [Page 13] draft-zhang-ccamp-gmpls-resource-sharing-proc September 2014 is discussed in previous sections, the traffic delivery may be interrupted. Depending on whether the short traffic interruption is acceptable or not, additional mechanisms may needed and are outside of the scope of this document. 5. Security Considerations This document reviews procedures defined in [RFC4872] and [RFC6689] and does not define any new procedure. This document does not incur any new security issues other than those already covered in [RFC3209] [RFC4872] [RFC4873] and [RFC6780]. 6. IANA Considerations This informational document does not make any requests for IANA action. 7. Acknowledgement The authors would like to thank George Swallow for the discussions on the GMPLS restoration. 8. References 8.1. Normative References [RFC3209] D. Awduche et al, "RSVP-TE: Extensions to RSVP for LSP Tunnels", RFC3209, December 2001. [RFC3473] L. Berger, Ed., "Generalized Multi-Protocol Label Switching (GMPLS) Signaling Resource ReserVation Protocol-Traffic Engineering (RSVP-TE) Extensions", RFC 3473, January 2003. [RFC3945] Mannie, E., "Generalized Multi-Protocol Label Switching (GMPLS) Architecture", RFC 3945, October 2004. [RFC4203] Kompella, K., and Rekhter, Y., "OSPF Extensions in Support of Generalized Multi-Protocol Label Switching (GMPLS)", RFC 4203, October 2005. [RFC4872] J.P. Lang et al, "RSVP-TE Extensions in Support of End- to-End Generalized Multi-Protocol Label Switching (GMPLS) Recovery", RFC4872, May 2007. Zhang, et al. Expires March 2015 [Page 14] draft-zhang-ccamp-gmpls-resource-sharing-proc September 2014 [RFC4873] L. Berger et al, "GMPLS Segment Recovery", RFC4873, May 2007. [RFC6689] L. Berger, "Usage of the RSVP ASSOCIATION Object", RFC 6689, July 2012. [RFC6780] L. Berger et al, "RSVP ASSOCIATION Object Extensions", RFC6780, October 2012. 8.2. Informative References [PCEP-RSO] X. Zhang, et al, "Extensions to Path Computation Element Protocol (PCEP) to Support Resource Sharing-based Path Computation", work in progress, February 2014. [RFC4426] Lang, J., Rajagopalan, B., and Papadimitriou, D., "Generalized Multiprotocol Label Switching (GMPLS) Recovery Functional Specification", RFC 4426, March 2006. [RFC4427] Mannie, E., and Papadimitriou, D., "Recovery (Protection and Restoration) Terminology for Generalized Multi- Protocol Label Switching, RFC 4427, March 2006. [RFC4655] A. Farrel et al, "A Path Computation Element (PCE)-Based Architecture", RFC4655, August 2006. [RFC4208] Swallow, G., Drake, J., Ishimatsu, H., Rekhter, Y., "Generalized Multiprotocol Label Switching (GMPLS) User-Network Interface (UNI): Resource ReserVation Protocol-Traffic Engineering (RSVP-TE) Support for the Overlay Model", RFC4208, October 2005. Zhang, et al. Expires March 2015 [Page 15] draft-zhang-ccamp-gmpls-resource-sharing-proc September 2014 9. Authors' Addresses Xian Zhang Huawei Technologies F3-1-B R&D Center, Huawei Base Bantian, Longgang District Shenzhen 518129 P.R.China Email: zhang.xian@huawei.com Haomian Zheng (editor) Huawei Technologies F3-1-B R&D Center, Huawei Base Bantian, Longgang District Shenzhen 518129 P.R.China Email: zhenghaomian@huawei.com Rakesh Gandhi (editor) Cisco Systems, Inc. Email: rgandhi@cisco.com Zafar Ali Cisco Systems, Inc. Email: zali@cisco.com Gabriele Maria Galimberti Cisco Systems, Inc. Email: ggalimbe@cisco.com Pawel Brzozowski ADVA Optical Email PBrzozowski@advaoptical.com Zhang, et al. Expires March 2015 [Page 16]