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/rfc4428.txt | 2635 +++++++++++++++++++++++++++++++++++++++++++++++++++ 1 file changed, 2635 insertions(+) create mode 100644 doc/rfc/rfc4428.txt (limited to 'doc/rfc/rfc4428.txt') diff --git a/doc/rfc/rfc4428.txt b/doc/rfc/rfc4428.txt new file mode 100644 index 0000000..2cf0284 --- /dev/null +++ b/doc/rfc/rfc4428.txt @@ -0,0 +1,2635 @@ + + + + + + +Network Working Group D. Papadimitriou, Ed. +Request for Comments: 4428 Alcatel +Category: Informational E. Mannie, Ed. + Perceval + March 2006 + + + Analysis of Generalized Multi-Protocol Label Switching (GMPLS)-based + Recovery Mechanisms (including Protection and Restoration) + +Status of This Memo + + This memo provides information for the Internet community. It does + not specify an Internet standard of any kind. Distribution of this + memo is unlimited. + +Copyright Notice + + Copyright (C) The Internet Society (2006). + +Abstract + + This document provides an analysis grid to evaluate, compare, and + contrast the Generalized Multi-Protocol Label Switching (GMPLS) + protocol suite capabilities with the recovery mechanisms currently + proposed at the IETF CCAMP Working Group. A detailed analysis of + each of the recovery phases is provided using the terminology defined + in RFC 4427. This document focuses on transport plane survivability + and recovery issues and not on control plane resilience and related + aspects. + +Table of Contents + + 1. Introduction ....................................................3 + 2. Contributors ....................................................4 + 3. Conventions Used in this Document ...............................5 + 4. Fault Management ................................................5 + 4.1. Failure Detection ..........................................5 + 4.2. Failure Localization and Isolation .........................8 + 4.3. Failure Notification .......................................9 + 4.4. Failure Correlation .......................................11 + 5. Recovery Mechanisms ............................................11 + 5.1. Transport vs. Control Plane Responsibilities ..............11 + 5.2. Technology-Independent and Technology-Dependent + Mechanisms ................................................12 + 5.2.1. OTN Recovery .......................................12 + 5.2.2. Pre-OTN Recovery ...................................13 + 5.2.3. SONET/SDH Recovery .................................13 + + + +Papadimitriou & Mannie Informational [Page 1] + +RFC 4428 GMPLS Recovery Mechanisms March 2006 + + + 5.3. Specific Aspects of Control Plane-Based Recovery + Mechanisms ................................................14 + 5.3.1. In-Band vs. Out-Of-Band Signaling ..................14 + 5.3.2. Uni- vs. Bi-Directional Failures ...................15 + 5.3.3. Partial vs. Full Span Recovery .....................17 + 5.3.4. Difference between LSP, LSP Segment and + Span Recovery ......................................18 + 5.4. Difference between Recovery Type and Scheme ...............19 + 5.5. LSP Recovery Mechanisms ...................................21 + 5.5.1. Classification .....................................21 + 5.5.2. LSP Restoration ....................................23 + 5.5.3. Pre-Planned LSP Restoration ........................24 + 5.5.4. LSP Segment Restoration ............................25 + 6. Reversion ......................................................26 + 6.1. Wait-To-Restore (WTR) .....................................26 + 6.2. Revertive Mode Operation ..................................26 + 6.3. Orphans ...................................................27 + 7. Hierarchies ....................................................27 + 7.1. Horizontal Hierarchy (Partitioning) .......................28 + 7.2. Vertical Hierarchy (Layers) ...............................28 + 7.2.1. Recovery Granularity ...............................30 + 7.3. Escalation Strategies .....................................30 + 7.4. Disjointness ..............................................31 + 7.4.1. SRLG Disjointness ..................................32 + 8. Recovery Mechanisms Analysis ...................................33 + 8.1. Fast Convergence (Detection/Correlation and + Hold-off Time) ............................................34 + 8.2. Efficiency (Recovery Switching Time) ......................34 + 8.3. Robustness ................................................35 + 8.4. Resource Optimization .....................................36 + 8.4.1. Recovery Resource Sharing ..........................37 + 8.4.2. Recovery Resource Sharing and SRLG Recovery ........39 + 8.4.3. Recovery Resource Sharing, SRLG + Disjointness and Admission Control .................40 + 9. Summary and Conclusions ........................................42 + 10. Security Considerations .......................................43 + 11. Acknowledgements ..............................................43 + 12. References ....................................................44 + 12.1. Normative References .....................................44 + 12.2. Informative References ...................................44 + + + + + + + + + + + +Papadimitriou & Mannie Informational [Page 2] + +RFC 4428 GMPLS Recovery Mechanisms March 2006 + + +1. Introduction + + This document provides an analysis grid to evaluate, compare, and + contrast the Generalized MPLS (GMPLS) protocol suite capabilities + with the recovery mechanisms proposed at the IETF CCAMP Working + Group. The focus is on transport plane survivability and recovery + issues and not on control-plane-resilience-related aspects. Although + the recovery mechanisms described in this document impose different + requirements on GMPLS-based recovery protocols, the protocols' + specifications will not be covered in this document. Though the + concepts discussed are technology independent, this document + implicitly focuses on SONET [T1.105]/SDH [G.707], Optical Transport + Networks (OTN) [G.709], and pre-OTN technologies, except when + specific details need to be considered (for instance, in the case of + failure detection). + + A detailed analysis is provided for each of the recovery phases as + identified in [RFC4427]. These phases define the sequence of generic + operations that need to be performed when a LSP/Span failure (or any + other event generating such failures) occurs: + + - Phase 1: Failure Detection + - Phase 2: Failure Localization (and Isolation) + - Phase 3: Failure Notification + - Phase 4: Recovery (Protection or Restoration) + - Phase 5: Reversion (Normalization) + + Together, failure detection, localization, and notification phases + are referred to as "fault management". Within a recovery domain, the + entities involved during the recovery operations are defined in + [RFC4427]; these entities include ingress, egress, and intermediate + nodes. The term "recovery mechanism" is used to cover both + protection and restoration mechanisms. Specific terms such as + "protection" and "restoration" are used only when differentiation is + required. Likewise the term "failure" is used to represent both + signal failure and signal degradation. + + In addition, when analyzing the different hierarchical recovery + mechanisms including disjointness-related issues, a clear distinction + is made between partitioning (horizontal hierarchy) and layering + (vertical hierarchy). In order to assess the current GMPLS protocol + capabilities and the potential need for further extensions, the + dimensions for analyzing each of the recovery mechanisms detailed in + this document are introduced. This document concludes by detailing + the applicability of the current GMPLS protocol building blocks for + recovery purposes. + + + + + +Papadimitriou & Mannie Informational [Page 3] + +RFC 4428 GMPLS Recovery Mechanisms March 2006 + + +2. Contributors + + This document is the result of the CCAMP Working Group Protection and + Restoration design team joint effort. Besides the editors, the + following are the authors that contributed to the present memo: + + Deborah Brungard (AT&T) + 200 S. Laurel Ave. + Middletown, NJ 07748, USA + + EMail: dbrungard@att.com + + + Sudheer Dharanikota + + EMail: sudheer@ieee.org + + + Jonathan P. Lang (Sonos) + 506 Chapala Street + Santa Barbara, CA 93101, USA + + EMail: jplang@ieee.org + + + Guangzhi Li (AT&T) + 180 Park Avenue, + Florham Park, NJ 07932, USA + + EMail: gli@research.att.com + + + Eric Mannie + Perceval + Rue Tenbosch, 9 + 1000 Brussels + Belgium + + Phone: +32-2-6409194 + EMail: eric.mannie@perceval.net + + + Dimitri Papadimitriou (Alcatel) + Francis Wellesplein, 1 + B-2018 Antwerpen, Belgium + + EMail: dimitri.papadimitriou@alcatel.be + + + + +Papadimitriou & Mannie Informational [Page 4] + +RFC 4428 GMPLS Recovery Mechanisms March 2006 + + + Bala Rajagopalan + Microsoft India Development Center + Hyderabad, India + + EMail: balar@microsoft.com + + + Yakov Rekhter (Juniper) + 1194 N. Mathilda Avenue + Sunnyvale, CA 94089, USA + + EMail: yakov@juniper.net + +3. 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]. + + Any other recovery-related terminology used in this document conforms + to that defined in [RFC4427]. The reader is also assumed to be + familiar with the terminology developed in [RFC3945], [RFC3471], + [RFC3473], [RFC4202], and [RFC4204]. + +4. Fault Management + +4.1. Failure Detection + + Transport failure detection is the only phase that cannot be achieved + by the control plane alone because the latter needs a hook to the + transport plane in order to collect the related information. It has + to be emphasized that even if failure events themselves are detected + by the transport plane, the latter, upon a failure condition, must + trigger the control plane for subsequent actions through the use of + GMPLS signaling capabilities (see [RFC3471] and [RFC3473]) or Link + Management Protocol capabilities (see [RFC4204], Section 6). + + Therefore, by definition, transport failure detection is transport + technology dependent (and so exceptionally, we keep here the + "transport plane" terminology). In transport fault management, + distinction is made between a defect and a failure. Here, the + discussion addresses failure detection (persistent fault cause). In + the technology-dependent descriptions, a more precise specification + will be provided. + + As an example, SONET/SDH (see [G.707], [G.783], and [G.806]) provides + supervision capabilities covering: + + + + +Papadimitriou & Mannie Informational [Page 5] + +RFC 4428 GMPLS Recovery Mechanisms March 2006 + + + - Continuity: SONET/SDH monitors the integrity of the continuity of a + trail (i.e., section or path). This operation is performed by + monitoring the presence/absence of the signal. Examples are Loss + of Signal (LOS) detection for the physical layer, Unequipped (UNEQ) + Signal detection for the path layer, Server Signal Fail Detection + (e.g., AIS) at the client layer. + + - Connectivity: SONET/SDH monitors the integrity of the routing of + the signal between end-points. Connectivity monitoring is needed + if the layer provides flexible connectivity, either automatically + (e.g., cross-connects) or manually (e.g., fiber distribution + frame). An example is the Trail (i.e., section or path) Trace + Identifier used at the different layers and the corresponding Trail + Trace Identifier Mismatch detection. + + - Alignment: SONET/SDH checks that the client and server layer frame + start can be correctly recovered from the detection of loss of + alignment. The specific processes depend on the signal/frame + structure and may include: (multi-)frame alignment, pointer + processing, and alignment of several independent frames to a common + frame start in case of inverse multiplexing. Loss of alignment is + a generic term. Examples are loss of frame, loss of multi-frame, + or loss of pointer. + + - Payload type: SONET/SDH checks that compatible adaptation functions + are used at the source and the destination. Normally, this is done + by adding a payload type identifier (referred to as the "signal + label") at the source adaptation function and comparing it with the + expected identifier at the destination. For instance, the payload + type identifier is compared with the corresponding mismatch + detection. + + - Signal Quality: SONET/SDH monitors the performance of a signal. + For instance, if the performance falls below a certain threshold, a + defect -- excessive errors (EXC) or degraded signal (DEG) -- is + detected. + + The most important point is that the supervision processes and the + corresponding failure detection (used to initiate the recovery + phase(s)) result in either: + + - Signal Degrade (SD): A signal indicating that the associated data + has degraded in the sense that a degraded defect condition is + active (for instance, a dDEG declared when the Bit Error Rate + exceeds a preset threshold). Or + + + + + + +Papadimitriou & Mannie Informational [Page 6] + +RFC 4428 GMPLS Recovery Mechanisms March 2006 + + + - Signal Fail (SF): A signal indicating that the associated data has + failed in the sense that a signal interrupting near-end defect + condition is active (as opposed to the degraded defect). + + In Optical Transport Networks (OTN), equivalent supervision + capabilities are provided at the optical/digital section layers + (i.e., Optical Transmission Section (OTS), Optical Multiplex Section + (OMS) and Optical channel Transport Unit (OTU)) and at the + optical/digital path layers (i.e., Optical Channel (OCh) and Optical + channel Data Unit (ODU)). Interested readers are referred to the + ITU-T Recommendations [G.798] and [G.709] for more details. + + The above are examples that illustrate cases where the failure + detection and reporting entities (see [RFC4427]) are co-located. The + following example illustrates the scenario where the failure + detecting and reporting entities (see [RFC4427]) are not co-located. + + In pre-OTN networks, a failure may be masked by intermediate O-E-O + based Optical Line System (OLS), preventing a Photonic Cross-Connect + (PXC) from detecting upstream failures. In such cases, failure + detection may be assisted by an out-of-band communication channel, + and failure condition may be reported to the PXC control plane. This + can be provided by using [RFC4209] extensions that deliver IP + message-based communication between the PXC and the OLS control + plane. Also, since PXCs are independent of the framing format, + failure conditions can only be triggered either by detecting the + absence of the optical signal or by measuring its quality. These + mechanisms are generally less reliable than electrical (digital) + ones. Both types of detection mechanisms are outside the scope of + this document. If the intermediate OLS supports electrical (digital) + mechanisms, using the LMP communication channel, these failure + conditions are reported to + + the PXC and subsequent recovery actions are performed as described in + Section 5. As such, from the control plane viewpoint, this mechanism + turns the OLS-PXC-composed system into a single logical entity, thus + having the same failure management mechanisms as any other O-E-O + capable device. + + More generally, the following are typical failure conditions in + SONET/SDH and pre-OTN networks: + + - Loss of Light (LOL)/Loss of Signal (LOS): Signal Failure (SF) + condition where the optical signal is not detected any longer on + the receiver of a given interface. + + - Signal Degrade (SD): detection of the signal degradation over + a specific period of time. + + + +Papadimitriou & Mannie Informational [Page 7] + +RFC 4428 GMPLS Recovery Mechanisms March 2006 + + + - For SONET/SDH payloads, all of the above-mentioned supervision + capabilities can be used, resulting in SD or SF conditions. + + In summary, the following cases apply when considering the + communication between the detecting and reporting entities: + + - Co-located detecting and reporting entities: both the detecting and + reporting entities are on the same node (e.g., SONET/SDH equipment, + Opaque cross-connects, and, with some limitations, Transparent + cross-connects, etc.) + + - Non-co-located detecting and reporting entities: + + o with in-band communication between entities: entities are + physically separated, but the transport plane provides in-band + communication between them (e.g., Server Signal Failures such as + Alarm Indication Signal (AIS), etc.) + + o with out-of-band communication between entities: entities are + physically separated, but an out-of-band communication channel is + provided between them (e.g., using [RFCF4204]). + +4.2. Failure Localization and Isolation + + Failure localization provides information to the deciding entity + about the location (and so the identity) of the transport plane + entity that detects the LSP(s)/span(s) failure. The deciding entity + can then make an accurate decision to achieve finer grained recovery + switching action(s). Note that this information can also be included + as part of the failure notification (see Section 4.3). + + In some cases, this accurate failure localization information may be + less urgent to determine if it requires performing more time- + consuming failure isolation (see also Section 4.4). This is + particularly the case when edge-to-edge LSP recovery is performed + based on a simple failure notification (including the identification + of the working LSPs under failure condition). Note that "edge" + refers to a sub-network end-node, for instance. In this case, a more + accurate localization and isolation can be performed after recovery + of these LSPs. + + Failure localization should be triggered immediately after the fault + detection phase. This operation can be performed at the transport + plane and/or (if the operation is unavailable via the transport + plane) the control plane level where dedicated signaling messages can + be used. When performed at the control plane level, a protocol such + as LMP (see [RFC4204], Section 6) can be used for failure + localization purposes. + + + +Papadimitriou & Mannie Informational [Page 8] + +RFC 4428 GMPLS Recovery Mechanisms March 2006 + + +4.3. Failure Notification + + Failure notification is used 1) to inform intermediate nodes that an + LSP/span failure has occurred and has been detected and 2) to inform + the deciding entities (which can correspond to any intermediate or + end-point of the failed LSP/span) that the corresponding service is + not available. In general, these deciding entities will be the ones + making the appropriate recovery decision. When co-located with the + recovering entity, these entities will also perform the corresponding + recovery action(s). + + Failure notification can be provided either by the transport or by + the control plane. As an example, let us first briefly describe the + failure notification mechanism defined at the SONET/SDH transport + plane level (also referred to as maintenance signal supervision): + + - AIS (Alarm Indication Signal) occurs as a result of a failure + condition such as Loss of Signal and is used to notify downstream + nodes (of the appropriate layer processing) that a failure has + occurred. AIS performs two functions: 1) inform the intermediate + nodes (with the appropriate layer monitoring capability) that a + failure has been detected and 2) notify the connection end-point + that the service is no longer available. + + For a distributed control plane supporting one (or more) failure + notification mechanism(s), regardless of the mechanism's actual + implementation, the same capabilities are needed with more (or less) + information provided about the LSPs/spans under failure condition, + their detailed statuses, etc. + + The most important difference between these mechanisms is related to + the fact that transport plane notifications (as defined today) would + directly initiate either a certain type of protection switching (such + as those described in [RFC4427]) via the transport plane or + restoration actions via the management plane. + + On the other hand, using a failure notification mechanism through the + control plane would provide the possibility of triggering either a + protection or a restoration action via the control plane. This has + the advantage that a control-plane-recovery-responsible entity does + not necessarily have to be co-located with a transport + maintenance/recovery domain. A control plane recovery domain can be + defined at entities not supporting a transport plane recovery. + + Moreover, as specified in [RFC3473], notification message exchanges + through a GMPLS control plane may not follow the same path as the + LSP/spans for which these messages carry the status. In turn, this + ensures a fast, reliable (through acknowledgement and the use of + + + +Papadimitriou & Mannie Informational [Page 9] + +RFC 4428 GMPLS Recovery Mechanisms March 2006 + + + either a dedicated control plane network or disjoint control + channels), and efficient (through the aggregation of several LSP/span + statuses within the same message) failure notification mechanism. + + The other important properties to be met by the failure notification + mechanism are mainly the following: + + - Notification messages must provide enough information such that the + most efficient subsequent recovery action will be taken at the + recovering entities (in most of the recovery types and schemes this + action is even deterministic). Remember here that these entities + can be either intermediate or end-points through which normal + traffic flows. Based on local policy, intermediate nodes may not + use this information for subsequent recovery actions (see for + instance the APS protocol phases as described in [RFC4427]). In + addition, since fast notification is a mechanism running in + collaboration with the existing GMPLS signaling (see [RFC3473]) + that also allows intermediate nodes to stay informed about the + status of the working LSP/spans under failure condition. + + The trade-off here arises when defining what information the + LSP/span end-points (more precisely, the deciding entities) need in + order for the recovering entity to take the best recovery action: + If not enough information is provided, the decision cannot be + optimal (note that in this eventuality, the important issue is to + quantify the level of sub-optimality). If too much information is + provided, the control plane may be overloaded with unnecessary + information and the aggregation/correlation of this notification + information will be more complex and time-consuming to achieve. + Note that a more detailed quantification of the amount of + information to be exchanged and processed is strongly dependent on + the failure notification protocol. + + - If the failure localization and isolation are not performed by one + of the LSP/span end-points or some intermediate points, the points + should receive enough information from the notification message in + order to locate the failure. Otherwise, they would need to (re-) + initiate a failure localization and isolation action. + + - Avoiding so-called notification storms implies that 1) the failure + detection output is correlated (i.e., alarm correlation) and + aggregated at the node detecting the failure(s), 2) the failure + notifications are directed to a restricted set of destinations (in + general the end-points), and 3) failure notification suppression + (i.e., alarm suppression) is provided in order to limit flooding in + case of multiple and/or correlated failures detected at several + locations in the network. + + + + +Papadimitriou & Mannie Informational [Page 10] + +RFC 4428 GMPLS Recovery Mechanisms March 2006 + + + - Alarm correlation and aggregation (at the failure-detecting node) + implies a consistent decision based on the conditions for which a + trade-off between fast convergence (at detecting node) and fast + notification (implying that correlation and aggregation occurs at + receiving end-points) can be found. + +4.4. Failure Correlation + + A single failure event (such as a span failure) can cause multiple + failure (such as individual LSP failures) conditions to be reported. + These can be grouped (i.e., correlated) to reduce the number of + failure conditions communicated on the reporting channel, for both + in-band and out-of-band failure reporting. + + In such a scenario, it can be important to wait for a certain period + of time, typically called failure correlation time, and gather all + the failures to report them as a group of failures (or simply group + failure). For instance, this approach can be provided using LMP-WDM + for pre-OTN networks (see [RFC4209]) or when using Signal + Failure/Degrade Group in the SONET/SDH context. + + Note that a default average time interval during which failure + correlation operation can be performed is difficult to provide since + it is strongly dependent on the underlying network topology. + Therefore, providing a per-node configurable failure correlation time + can be advisable. The detailed selection criteria for this time + interval are outside of the scope of this document. + + When failure correlation is not provided, multiple failure + notification messages may be sent out in response to a single failure + (for instance, a fiber cut). Each failure notification message + contains a set of information on the failed working resources (for + instance, the individual lambda LSP flowing through this fiber). + This allows for a more prompt response, but can potentially overload + the control plane due to a large amount of failure notifications. + +5. Recovery Mechanisms + +5.1. Transport vs. Control Plane Responsibilities + + When applicable, recovery resources are provisioned, for both + protection and restoration, using GMPLS signaling capabilities. + Thus, these are control plane-driven actions (topological and + resource-constrained) that are always performed in this context. + + The following tables give an overview of the responsibilities taken + by the control plane in case of LSP/span recovery: + + + + +Papadimitriou & Mannie Informational [Page 11] + +RFC 4428 GMPLS Recovery Mechanisms March 2006 + + + 1. LSP/span Protection + + - Phase 1: Failure Detection Transport plane + - Phase 2: Failure Localization/Isolation Transport/Control plane + - Phase 3: Failure Notification Transport/Control plane + - Phase 4: Protection Switching Transport/Control plane + - Phase 5: Reversion (Normalization) Transport/Control plane + + Note: in the context of LSP/span protection, control plane actions + can be performed either for operational purposes and/or + synchronization purposes (vertical synchronization between transport + and control plane) and/or notification purposes (horizontal + synchronization between end-nodes at control plane level). This + suggests the selection of the responsible plane (in particular for + protection switching) during the provisioning phase of the + protected/protection LSP. + + 2. LSP/span Restoration + + - Phase 1: Failure Detection Transport plane + - Phase 2: Failure Localization/Isolation Transport/Control plane + - Phase 3: Failure Notification Control plane + - Phase 4: Recovery Switching Control plane + - Phase 5: Reversion (Normalization) Control plane + + Therefore, this document primarily focuses on provisioning of LSP + recovery resources, failure notification mechanisms, recovery + switching, and reversion operations. Moreover, some additional + considerations can be dedicated to the mechanisms associated to the + failure localization/isolation phase. + +5.2. Technology-Independent and Technology-Dependent Mechanisms + + The present recovery mechanisms analysis applies to any circuit- + oriented data plane technology with discrete bandwidth increments + (like SONET/SDH, G.709 OTN, etc.) being controlled by a GMPLS-based + distributed control plane. + + The following sub-sections are not intended to favor one technology + versus another. They list pro and cons for each technology in order + to determine the mechanisms that GMPLS-based recovery must deliver to + overcome their cons and make use of their pros in their respective + applicability context. + +5.2.1. OTN Recovery + + OTN recovery specifics are left for further consideration. + + + + +Papadimitriou & Mannie Informational [Page 12] + +RFC 4428 GMPLS Recovery Mechanisms March 2006 + + +5.2.2. Pre-OTN Recovery + + Pre-OTN recovery specifics (also referred to as "lambda switching") + present mainly the following advantages: + + - They benefit from a simpler architecture, making it more suitable + for mesh-based recovery types and schemes (on a per-channel basis). + + - Failure suppression at intermediate node transponders, e.g., use of + squelching, implies that failures (such as LoL) will propagate to + edge nodes. Thus, edge nodes will have the possibility to initiate + recovery actions driven by upper layers (vs. use of non-standard + masking of upstream failures). + + The main disadvantage is the lack of interworking due to the large + amount of failure management (in particular failure notification + protocols) and recovery mechanisms currently available. + + Note also, that for all-optical networks, combination of recovery + with optical physical impairments is left for a future release of + this document because corresponding detection technologies are under + specification. + +5.2.3. SONET/SDH Recovery + + Some of the advantages of SONET [T1.105]/SDH [G.707], and more + generically any Time Division Multiplexing (TDM) transport plane + recovery, are that they provide: + + - Protection types operating at the data plane level that are + standardized (see [G.841]) and can operate across protected domains + and interwork (see [G.842]). + + - Failure detection, notification, and path/section Automatic + Protection Switching (APS) mechanisms. + + - Greater control over the granularity of the TDM LSPs/links that can + be recovered with respect to coarser optical channel (or whole + fiber content) recovery switching + + Some of the limitations of the SONET/SDH recovery are: + + - Limited topological scope: Inherently the use of ring topologies, + typically, dedicated Sub-Network Connection Protection (SNCP) or + shared protection rings, has reduced flexibility and resource + efficiency with respect to the (somewhat more complex) meshed + recovery. + + + + +Papadimitriou & Mannie Informational [Page 13] + +RFC 4428 GMPLS Recovery Mechanisms March 2006 + + + - Inefficient use of spare capacity: SONET/SDH protection is largely + applied to ring topologies, where spare capacity often remains + idle, making the efficiency of bandwidth usage a real issue. + + - Support of meshed recovery requires intensive network management + development, and the functionality is limited by both the network + elements and the capabilities of the element management systems + (thus justifying the development of GMPLS-based distributed + recovery mechanisms.) + +5.3. Specific Aspects of Control Plane-Based Recovery Mechanisms + +5.3.1. In-Band vs. Out-Of-Band Signaling + + The nodes communicate through the use of IP terminating control + channels defining the control plane (transport) topology. In this + context, two classes of transport mechanisms can be considered here: + in-fiber or out-of-fiber (through a dedicated physically diverse + control network referred to as the Data Communication Network or + DCN). The potential impact of the usage of an in-fiber (signaling) + transport mechanism is briefly considered here. + + In-fiber transport mechanisms can be further subdivided into in-band + and out-of-band. As such, the distinction between in-fiber in-band + and in-fiber out-of-band signaling reduces to the consideration of a + logically- versus physically-embedded control plane topology with + respect to the transport plane topology. In the scope of this + document, it is assumed that at least one IP control channel between + each pair of adjacent nodes is continuously available to enable the + exchange of recovery-related information and messages. Thus, in + either case (i.e., in-band or out-of-band) at least one logical or + physical control channel between each pair of nodes is always + expected to be available. + + Therefore, the key issue when using in-fiber signaling is whether one + can assume independence between the fault-tolerance capabilities of + control plane and the failures affecting the transport plane + (including the nodes). Note also that existing specifications like + the OTN provide a limited form of independence for in-fiber signaling + by dedicating a separate optical supervisory channel (OSC, see + [G.709] and [G.874]) to transport the overhead and other control + traffic. For OTNs, failure of the OSC does not result in failing the + optical channels. Similarly, loss of the control channel must not + result in failing the data channels (transport plane). + + + + + + + +Papadimitriou & Mannie Informational [Page 14] + +RFC 4428 GMPLS Recovery Mechanisms March 2006 + + +5.3.2. Uni- vs. Bi-Directional Failures + + The failure detection, correlation, and notification mechanisms + (described in Section 4) can be triggered when either a uni- + directional or a bi-directional LSP/Span failure occurs (or a + combination of both). As illustrated in Figures 1 and 2, two + alternatives can be considered here: + + 1. Uni-directional failure detection: the failure is detected on the + receiver side, i.e., it is detected by only the downstream node to + the failure (or by the upstream node depending on the failure + propagation direction, respectively). + + 2. Bi-directional failure detection: the failure is detected on the + receiver side of both downstream node AND upstream node to the + failure. + + Notice that after the failure detection time, if only control-plane- + based failure management is provided, the peering node is unaware of + the failure detection status of its neighbor. + + ------- ------- ------- ------- + | | | |Tx Rx| | | | + | NodeA |----...----| NodeB |xxxxxxxxx| NodeC |----...----| NodeD | + | |----...----| |---------| |----...----| | + ------- ------- ------- ------- + + t0 >>>>>>> F + + t1 x <---------------x + Notification + t2 <--------...--------x x--------...--------> + Up Notification Down Notification + + Figure 1: Uni-directional failure detection + + + + + + + + + + + + + + + + +Papadimitriou & Mannie Informational [Page 15] + +RFC 4428 GMPLS Recovery Mechanisms March 2006 + + + ------- ------- ------- ------- + | | | |Tx Rx| | | | + | NodeA |----...----| NodeB |xxxxxxxxx| NodeC |----...----| NodeD | + | |----...----| |xxxxxxxxx| |----...----| | + ------- ------- ------- ------- + + t0 F <<<<<<< >>>>>>> F + + t1 x <-------------> x + Notification + t2 <--------...--------x x--------...--------> + Up Notification Down Notification + + Figure 2: Bi-directional failure detection + + After failure detection, the following failure management operations + can be subsequently considered: + + - Each detecting entity sends a notification message to the + corresponding transmitting entity. For instance, in Figure 1, node + C sends a notification message to node B. In Figure 2, node C + sends a notification message to node B while node B sends a + notification message to node C. To ensure reliable failure + notification, a dedicated acknowledgement message can be returned + back to the sender node. + + - Next, within a certain (and pre-determined) time window, nodes + impacted by the failure occurrences may perform their correlation. + In case of uni-directional failure, node B only receives the + notification message from node C, and thus the time for this + operation is negligible. In case of bi-directional failure, node B + has to correlate the received notification message from node C with + the corresponding locally detected information (and node C has to + do the same with the message from node B). + + - After some (pre-determined) period of time, referred to as the + hold-off time, if the local recovery actions (see Section 5.3.4) + were not successful, the following occurs. In case of uni- + directional failure and depending on the directionality of the LSP, + node B should send an upstream notification message (see [RFC3473]) + to the ingress node A. Node C may send a downstream notification + message (see [RFC3473]) to the egress node D. However, in that + case, only node A would initiate an edge to edge recovery action. + Node A is referred to as the "master", and node D is referred to as + the "slave", per [RFC4427]. Note that the other LSP end-node (node + D in this case) may be optionally notified using a downstream + notification message (see [RFC3473]). + + + + +Papadimitriou & Mannie Informational [Page 16] + +RFC 4428 GMPLS Recovery Mechanisms March 2006 + + + In case of bi-directional failure, node B should send an upstream + notification message (see [RFC3473]) to the ingress node A. Node C + may send a downstream notification message (see [RFC3473]) to the + egress node D. However, due to the dependence on the LSP + directionality, only ingress node A would initiate an edge-to-edge + recovery action. Note that the other LSP end-node (node D in this + case) should also be notified of this event using a downstream + notification message (see [RFC3473]). For instance, if an LSP + directed from D to A is under failure condition, only the + notification message sent from node C to D would initiate a + recovery action. In this case, per [RFC4427], the deciding and + recovering node D is referred to as the "master", while node A is + referred to as the "slave" (i.e., recovering only entity). + + Note: The determination of the master and the slave may be based + either on configured information or dedicated protocol capability. + + In the above scenarios, the path followed by the upstream and + downstream notification messages does not have to be the same as the + one followed by the failed LSP (see [RFC3473] for more details on the + notification message exchange). The important point concerning this + mechanism is that either the detecting/reporting entity (i.e., nodes + B and C) is also the deciding/recovery entity or the + detecting/reporting entity is simply an intermediate node in the + subsequent recovery process. One refers to local recovery in the + former case, and to edge-to-edge recovery in the latter one (see also + Section 5.3.4). + +5.3.3. Partial vs. Full Span Recovery + + When a given span carries more than one LSP or LSP segment, an + additional aspect must be considered. In case of span failure, the + LSPs it carries can be recovered individually, as a group (aka bulk + LSP recovery), or as independent sub-groups. When correlation time + windows are used and simultaneous recovery of several LSPs can be + performed using a single request, the selection of this mechanism + would be triggered independently of the failure notification + granularity. Moreover, criteria for forming such sub-groups are + outside of the scope of this document. + + Additional complexity arises in the case of (sub-)group LSP recovery. + Between a given pair of nodes, the LSPs that a given (sub-)group + contains may have been created from different source nodes (i.e., + initiator) and directed toward different destination nodes. + Consequently the failure notification messages following a bi- + directional span failure that affects several LSPs (or the whole + group of LSPs it carries) are not necessarily directed toward the + same initiator nodes. In particular, these messages may be directed + + + +Papadimitriou & Mannie Informational [Page 17] + +RFC 4428 GMPLS Recovery Mechanisms March 2006 + + + to both the upstream and downstream nodes to the failure. Therefore, + such span failure may trigger recovery actions to be performed from + both sides (i.e., from both the upstream and the downstream nodes to + the failure). In order to facilitate the definition of the + corresponding recovery mechanisms (and their sequence), one assumes + here as well that, per [RFC4427], the deciding (and recovering) + entity (referred to as the "master") is the only initiator of the + recovery of the whole LSP (sub-)group. + +5.3.4. Difference between LSP, LSP Segment and Span Recovery + + The recovery definitions given in [RFC4427] are quite generic and + apply for link (or local span) and LSP recovery. The major + difference between LSP, LSP Segment and span recovery is related to + the number of intermediate nodes that the signaling messages have to + travel. Since nodes are not necessarily adjacent in the case of LSP + (or LSP Segment) recovery, signaling message exchanges from the + reporting to the deciding/recovery entity may have to cross several + intermediate nodes. In particular, this applies to the notification + messages due to the number of hops separating the location of a + failure occurrence from its destination. This results in an + additional propagation and forwarding delay. Note that the former + delay may in certain circumstances be non-negligible; e.g., in a + copper out-of-band network, the delay is approximately 1 ms per + 200km. + + Moreover, the recovery mechanisms applicable to end-to-end LSPs and + to the segments that may compose an end-to-end LSP (i.e., edge-to- + edge recovery) can be exactly the same. However, one expects in the + latter case, that the destination of the failure notification message + will be the ingress/egress of each of these segments. Therefore, + using the mechanisms described in Section 5.3.2, failure notification + messages can be exchanged first between terminating points of the LSP + segment, and after expiration of the hold-off time, between + terminating points of the end-to-end LSP. + + Note: Several studies provide quantitative analysis of the relative + performance of LSP/span recovery techniques. [WANG] for instance, + provides an analysis grid for these techniques showing that dynamic + LSP restoration (see Section 5.5.2) performs well under medium + network loads, but suffers performance degradations at higher loads + due to greater contention for recovery resources. LSP restoration + upon span failure, as defined in [WANG], degrades at higher loads + because paths around failed links tend to increase the hop count of + the affected LSPs and thus consume additional network resources. + Also, performance of LSP restoration can be enhanced by a failed + working LSP's source node that initiates a new recovery attempt if an + initial attempt fails. A single retry attempt is sufficient to + + + +Papadimitriou & Mannie Informational [Page 18] + +RFC 4428 GMPLS Recovery Mechanisms March 2006 + + + produce large increases in the restoration success rate and ability + to initiate successful LSP restoration attempts, especially at high + loads, while not adding significantly to the long-term average + recovery time. Allowing additional attempts produces only small + additional gains in performance. This suggests using additional + (intermediate) crankback signaling when using dynamic LSP restoration + (described in Section 5.5.2 - case 2). Details on crankback + signaling are outside the scope of this document. + +5.4. Difference between Recovery Type and Scheme + + [RFC4427] defines the basic LSP/span recovery types. This section + describes the recovery schemes that can be built using these recovery + types. In brief, a recovery scheme is defined as the combination of + several ingress-egress node pairs supporting a given recovery type + (from the set of the recovery types they allow). Several examples + are provided here to illustrate the difference between recovery types + such as 1:1 or M:N, and recovery schemes such as (1:1)^n or (M:N)^n + (referred to as shared-mesh recovery). + + 1. (1:1)^n with recovery resource sharing + + The exponent, n, indicates the number of times a 1:1 recovery type is + applied between at most n different ingress-egress node pairs. Here, + at most n pairs of disjoint working and recovery LSPs/spans share a + common resource at most n times. Since the working LSPs/spans are + mutually disjoint, simultaneous requests for use of the shared + (common) resource will only occur in case of simultaneous failures, + which are less likely to happen. + + For instance, in the common (1:1)^2 case, if the 2 recovery LSPs in + the group overlap the same common resource, then it can handle only + single failures; any multiple working LSP failures will cause at + least one working LSP to be denied automatic recovery. Consider for + instance the following topology with the working LSPs A-B-C and F-G-H + and their respective recovery LSPs A-D-E-C and F-D-E-H that share a + common D-E link resource. + + A---------B---------C + \ / + \ / + D-------------E + / \ + / \ + F---------G---------H + + + + + + +Papadimitriou & Mannie Informational [Page 19] + +RFC 4428 GMPLS Recovery Mechanisms March 2006 + + + 2. (M:N)^n with recovery resource sharing + + The (M:N)^n scheme is documented here for the sake of completeness + only (i.e., it is not mandated that GMPLS capabilities support this + scheme). The exponent, n, indicates the number of times an M:N + recovery type is applied between at most n different ingress-egress + node pairs. So the interpretation follows from the previous case, + except that here disjointness applies to the N working LSPs/spans and + to the M recovery LSPs/spans while sharing at most n times M common + resources. + + In both schemes, it results in a "group" of sum{n=1}^N N{n} working + LSPs and a pool of shared recovery resources, not all of which are + available to any given working LSP. In such conditions, defining a + metric that describes the amount of overlap among the recovery LSPs + would give some indication of the group's ability to handle + simultaneous failures of multiple LSPs. + + For instance, in the simple (1:1)^n case, if n recovery LSPs in a + (1:1)^n group overlap, then the group can handle only single + failures; any simultaneous failure of multiple working LSPs will + cause at least one working LSP to be denied automatic recovery. But + if one considers, for instance, a (2:2)^2 group in which there are + two pairs of overlapping recovery LSPs, then two LSPs (belonging to + the same pair) can be simultaneously recovered. The latter case can + be illustrated by the following topology with 2 pairs of working LSPs + A-B-C and F-G-H and their respective recovery LSPs A-D-E-C and + F-D-E-H that share two common D-E link resources. + + A========B========C + \\ // + \\ // + D =========== E + // \\ + // \\ + F========G========H + + Moreover, in all these schemes, (working) path disjointness can be + enforced by exchanging information related to working LSPs during the + recovery LSP signaling. Specific issues related to the combination + of shared (discrete) bandwidth and disjointness for recovery schemes + are described in Section 8.4.2. + + + + + + + + + +Papadimitriou & Mannie Informational [Page 20] + +RFC 4428 GMPLS Recovery Mechanisms March 2006 + + +5.5. LSP Recovery Mechanisms + +5.5.1. Classification + + The recovery time and ratio of LSPs/spans depend on proper recovery + LSP provisioning (meaning pre-provisioning when performed before + failure occurrence) and the level of overbooking of recovery + resources (i.e., over-provisioning). A proper balance of these two + operations will result in the desired LSP/span recovery time and + ratio when single or multiple failures occur. Note also that these + operations are mostly performed during the network planning phases. + + The different options for LSP (pre-)provisioning and overbooking are + classified below to structure the analysis of the different recovery + mechanisms. + + 1. Pre-Provisioning + + Proper recovery LSP pre-provisioning will help to alleviate the + failure of the working LSPs (due to the failure of the resources that + carry these LSPs). As an example, one may compute and establish the + recovery LSP either end-to-end or segment-per-segment, to protect a + working LSP from multiple failure events affecting link(s), node(s) + and/or SRLG(s). The recovery LSP pre-provisioning options are + classified as follows in the figure below: + + (1) The recovery path can be either pre-computed or computed on- + demand. + + (2) When the recovery path is pre-computed, it can be either pre- + signaled (implying recovery resource reservation) or signaled + on-demand. + + (3) When the recovery resources are pre-signaled, they can be either + pre-selected or selected on-demand. + + Recovery LSP provisioning phases: + + + + + + + + + + + + + + +Papadimitriou & Mannie Informational [Page 21] + +RFC 4428 GMPLS Recovery Mechanisms March 2006 + + + (1) Path Computation --> On-demand + | + | + --> Pre-Computed + | + | + (2) Signaling --> On-demand + | + | + --> Pre-Signaled + | + | + (3) Resource Selection --> On-demand + | + | + --> Pre-Selected + + Note that these different options lead to different LSP/span recovery + times. The following sections will consider the above-mentioned + pre-provisioning options when analyzing the different recovery + mechanisms. + + 2. Overbooking + + There are many mechanisms available that allow the overbooking of the + recovery resources. This overbooking can be done per LSP (as in the + example mentioned above), per link (such as span protection), or even + per domain. In all these cases, the level of overbooking, as shown + in the below figure, can be classified as dedicated (such as 1+1 and + 1:1), shared (such as 1:N and M:N), or unprotected (and thus + restorable, if enough recovery resources are available). + + Overbooking levels: + + +----- Dedicated (for instance: 1+1, 1:1, etc.) + | + | + + +----- Shared (for instance: 1:N, M:N, etc.) + | + Level of | + Overbooking -----+----- Unprotected (for instance: 0:1, 0:N) + + Also, when using shared recovery, one may support preemptible extra- + traffic; the recovery mechanism is then expected to allow preemption + of this low priority traffic in case of recovery resource contention + during recovery operations. The following sections will consider the + + + + +Papadimitriou & Mannie Informational [Page 22] + +RFC 4428 GMPLS Recovery Mechanisms March 2006 + + + above-mentioned overbooking options when analyzing the different + recovery mechanisms. + +5.5.2. LSP Restoration + + The following times are defined to provide a quantitative estimation + about the time performance of the different LSP restoration + mechanisms (also referred to as LSP re-routing): + + - Path Computation Time: Tc + - Path Selection Time: Ts + - End-to-end LSP Resource Reservation Time: Tr (a delta for resource + selection is also considered, the corresponding total time is then + referred to as Trs) + - End-to-end LSP Resource Activation Time: Ta (a delta for + resource selection is also considered, the corresponding total + time is then referred to as Tas) + + The Path Selection Time (Ts) is considered when a pool of recovery + LSP paths between a given pair of source/destination end-points is + pre-computed, and after a failure occurrence one of these paths is + selected for the recovery of the LSP under failure condition. + + Note: failure management operations such as failure detection, + correlation, and notification are considered (for a given failure + event) as equally time-consuming for all the mechanisms described + below: + + 1. With Route Pre-computation (or LSP re-provisioning) + + An end-to-end restoration LSP is established after the failure(s) + occur(s) based on a pre-computed path. As such, one can define this + as an "LSP re-provisioning" mechanism. Here, one or more (disjoint) + paths for the restoration LSP are computed (and optionally pre- + selected) before a failure occurs. + + No reservation or selection of resources is performed along the + restoration path before failure occurrence. As a result, there is no + guarantee that a restoration LSP is available when a failure occurs. + + The expected total restoration time T is thus equal to Ts + Trs or to + Trs when a dedicated computation is performed for each working LSP. + + 2. Without Route Pre-computation (or Full LSP re-routing) + + An end-to-end restoration LSP is dynamically established after the + failure(s) occur(s). After failure occurrence, one or more + (disjoint) paths for the restoration LSP are dynamically computed and + + + +Papadimitriou & Mannie Informational [Page 23] + +RFC 4428 GMPLS Recovery Mechanisms March 2006 + + + one is selected. As such, one can define this as a complete "LSP + re-routing" mechanism. + + No reservation or selection of resources is performed along the + restoration path before failure occurrence. As a result, there is no + guarantee that a restoration LSP is available when a failure occurs. + + The expected total restoration time T is thus equal to Tc (+ Ts) + + Trs. Therefore, time performance between these two approaches + differs by the time required for route computation Tc (and its + potential selection time, Ts). + +5.5.3. Pre-Planned LSP Restoration + + Pre-planned LSP restoration (also referred to as pre-planned LSP re- + routing) implies that the restoration LSP is pre-signaled. This in + turn implies the reservation of recovery resources along the + restoration path. Two cases can be defined based on whether the + recovery resources are pre-selected. + + 1. With resource reservation and without resource pre-selection + + Before failure occurrence, an end-to-end restoration path is pre- + selected from a set of pre-computed (disjoint) paths. The + restoration LSP is signaled along this pre-selected path to reserve + resources at each node, but these resources are not selected. + + In this case, the resources reserved for each restoration LSP may be + dedicated or shared between multiple restoration LSPs whose working + LSPs are not expected to fail simultaneously. Local node policies + can be applied to define the degree to which these resources can be + shared across independent failures. Also, since a restoration scheme + is considered, resource sharing should not be limited to restoration + LSPs that start and end at the same ingress and egress nodes. + Therefore, each node participating in this scheme is expected to + receive some feedback information on the sharing degree of the + recovery resource(s) that this scheme involves. + + Upon failure detection/notification message reception, signaling is + initiated along the restoration path to select the resources, and to + perform the appropriate operation at each node crossed by the + restoration LSP (e.g., cross-connections). If lower priority LSPs + were established using the restoration resources, they must be + preempted when the restoration LSP is activated. + + Thus, the expected total restoration time T is equal to Tas (post- + failure activation), while operations performed before failure + occurrence take Tc + Ts + Tr. + + + +Papadimitriou & Mannie Informational [Page 24] + +RFC 4428 GMPLS Recovery Mechanisms March 2006 + + + 2. With both resource reservation and resource pre-selection + + Before failure occurrence, an end-to-end restoration path is pre- + selected from a set of pre-computed (disjoint) paths. The + restoration LSP is signaled along this pre-selected path to reserve + AND select resources at each node, but these resources are not + committed at the data plane level. So that the selection of the + recovery resources is committed at the control plane level only, no + cross-connections are performed along the restoration path. + + In this case, the resources reserved and selected for each + restoration LSP may be dedicated or even shared between multiple + restoration LSPs whose associated working LSPs are not expected to + fail simultaneously. Local node policies can be applied to define + the degree to which these resources can be shared across independent + failures. Also, because a restoration scheme is considered, resource + sharing should not be limited to restoration LSPs that start and end + at the same ingress and egress nodes. Therefore, each node + participating in this scheme is expected to receive some feedback + information on the sharing degree of the recovery resource(s) that + this scheme involves. + + Upon failure detection/notification message reception, signaling is + initiated along the restoration path to activate the reserved and + selected resources, and to perform the appropriate operation at each + node crossed by the restoration LSP (e.g., cross-connections). If + lower priority LSPs were established using the restoration resources, + they must be preempted when the restoration LSP is activated. + + Thus, the expected total restoration time T is equal to Ta (post- + failure activation), while operations performed before failure + occurrence take Tc + Ts + Trs. Therefore, time performance between + these two approaches differs only by the time required for resource + selection during the activation of the recovery LSP (i.e., Tas - Ta). + +5.5.4. LSP Segment Restoration + + The above approaches can be applied on an edge-to-edge LSP basis + rather than end-to-end LSP basis (i.e., to reduce the global recovery + time) by allowing the recovery of the individual LSP segments + constituting the end-to-end LSP. + + Also, by using the horizontal hierarchy approach described in Section + 7.1, an end-to-end LSP can be recovered by multiple recovery + mechanisms applied on an LSP segment basis (e.g., 1:1 edge-to-edge + LSP protection in a metro network, and M:N edge-to-edge protection in + the core). These mechanisms are ideally independent and may even use + different failure localization and notification mechanisms. + + + +Papadimitriou & Mannie Informational [Page 25] + +RFC 4428 GMPLS Recovery Mechanisms March 2006 + + +6. Reversion + + Reversion (a.k.a. normalization) is defined as the mechanism allowing + switching of normal traffic from the recovery LSP/span to the working + LSP/span previously under failure condition. Use of normalization is + at the discretion of the recovery domain policy. Normalization may + impact the normal traffic (a second hit) depending on the + normalization mechanism used. + + If normalization is supported, then 1) the LSP/span must be returned + to the working LSP/span when the failure condition clears and 2) the + capability to de-activate (turn-off) the use of reversion should be + provided. De-activation of reversion should not impact the normal + traffic, regardless of whether it is currently using the working or + recovery LSP/span. + + Note: during the failure, the reuse of any non-failed resources + (e.g., LSP and/or spans) belonging to the working LSP/span is under + the discretion of recovery domain policy. + +6.1. Wait-To-Restore (WTR) + + A specific mechanism (Wait-To-Restore) is used to prevent frequent + recovery switching operations due to an intermittent defect (e.g., + Bit Error Rate (BER) fluctuating around the SD threshold). + + First, an LSP/span under failure condition must become fault-free, + e.g., a BER less than a certain recovery threshold. After the + recovered LSP/span (i.e., the previously working LSP/span) meets this + criterion, a fixed period of time shall elapse before normal traffic + uses the corresponding resources again. This duration called Wait- + To-Restore (WTR) period or timer is generally on the order of a few + minutes (for instance, 5 minutes) and should be capable of being set. + The WTR timer may be either a fixed period, or provide for + incrementally longer periods before retrying. An SF or SD condition + on the previously working LSP/span will override the WTR timer value + (i.e., the WTR cancels and the WTR timer will restart). + +6.2. Revertive Mode Operation + + In revertive mode of operation, when the recovery LSP/span is no + longer required, i.e., the failed working LSP/span is no longer in SD + or SF condition, a local Wait-to-Restore (WTR) state will be + activated before switching the normal traffic back to the recovered + working LSP/span. + + During the reversion operation, since this state becomes the highest + in priority, signaling must maintain the normal traffic on the + + + +Papadimitriou & Mannie Informational [Page 26] + +RFC 4428 GMPLS Recovery Mechanisms March 2006 + + + recovery LSP/span from the previously failed working LSP/span. + Moreover, during this WTR state, any null traffic or extra traffic + (if applicable) request is rejected. + + However, deactivation (cancellation) of the wait-to-restore timer may + occur if there are higher priority request attempts. That is, the + recovery LSP/span usage by the normal traffic may be preempted if a + higher priority request for this recovery LSP/span is attempted. + +6.3. Orphans + + When a reversion operation is requested, normal traffic must be + switched from the recovery to the recovered working LSP/span. A + particular situation occurs when the previously working LSP/span + cannot be recovered, so normal traffic cannot be switched back. In + that case, the LSP/span under failure condition (also referred to as + "orphan") must be cleared (i.e., removed) from the pool of resources + allocated for normal traffic. Otherwise, potential de- + synchronization between the control and transport plane resource + usage can appear. Depending on the signaling protocol capabilities + and behavior, different mechanisms are expected here. + + Therefore, any reserved or allocated resources for the LSP/span under + failure condition must be unreserved/de-allocated. Several ways can + be used for that purpose: wait for the clear-out time interval to + elapse, initiate a deletion from the ingress or the egress node, or + trigger the initiation of deletion from an entity (such as an EMS or + NMS) capable of reacting upon reception of an appropriate + notification message. + +7. Hierarchies + + Recovery mechanisms are being made available at multiple (if not all) + transport layers within so-called "IP/MPLS-over-optical" networks. + However, each layer has certain recovery features, and one needs to + determine the exact impact of the interaction between the recovery + mechanisms provided by these layers. + + Hierarchies are used to build scalable complex systems. By hiding + the internal details, abstraction is used as a mechanism to build + large networks or as a technique for enforcing technology, + topological, or administrative boundaries. The same hierarchical + concept can be applied to control the network survivability. Network + survivability is the set of capabilities that allow a network to + restore affected traffic in the event of a failure. Network + survivability is defined further in [RFC4427]. In general, it is + expected that the recovery action is taken by the recoverable + LSP/span closest to the failure in order to avoid the multiplication + + + +Papadimitriou & Mannie Informational [Page 27] + +RFC 4428 GMPLS Recovery Mechanisms March 2006 + + + of recovery actions. Moreover, recovery hierarchies also can be + bound to control plane logical partitions (e.g., administrative or + topological boundaries). Each logical partition may apply different + recovery mechanisms. + + In brief, it is commonly accepted that the lower layers can provide + coarse but faster recovery while the higher layers can provide finer + but slower recovery. Moreover, it is also desirable to avoid similar + layers with functional overlaps in order to optimize network resource + utilization and processing overhead, since repeating the same + capabilities at each layer does not create any added value for the + network as a whole. In addition, even if a lower layer recovery + mechanism is enabled, it does not prevent the additional provision of + a recovery mechanism at the upper layer. The inverse statement does + not necessarily hold; that is, enabling an upper layer recovery + mechanism may prevent the use of a lower layer recovery mechanism. + In this context, this section analyzes these hierarchical aspects + including the physical (passive) layer(s). + +7.1. Horizontal Hierarchy (Partitioning) + + A horizontal hierarchy is defined when partitioning a single-layer + network (and its control plane) into several recovery domains. + Within a domain, the recovery scope may extend over a link (or span), + LSP segment, or even an end-to-end LSP. Moreover, an administrative + domain may consist of a single recovery domain or can be partitioned + into several smaller recovery domains. The operator can partition + the network into recovery domains based on physical network topology, + control plane capabilities, or various traffic engineering + constraints. + + An example often addressed in the literature is the metro-core-metro + application (sometimes extended to a metro-metro/core-core) within a + single transport layer (see Section 7.2). For such a case, an end- + to-end LSP is defined between the ingress and egress metro nodes, + while LSP segments may be defined within the metro or core sub- + networks. Each of these topological structures determines a so- + called "recovery domain" since each of the LSPs they carry can have + its own recovery type (or even scheme). The support of multiple + recovery types and schemes within a sub-network is referred to as a + "multi-recovery capable domain" or simply "multi-recovery domain". + +7.2. Vertical Hierarchy (Layers) + + It is very challenging to combine the different recovery capabilities + available across the path (i.e., switching capable) and section + layers to ensure that certain network survivability objectives are + met for the network-supported services. + + + +Papadimitriou & Mannie Informational [Page 28] + +RFC 4428 GMPLS Recovery Mechanisms March 2006 + + + As a first analysis step, one can draw the following guidelines for + a vertical coordination of the recovery mechanisms: + + - The lower the layer, the faster the notification and switching. + + - The higher the layer, the finer the granularity of the recoverable + entity and therefore the granularity of the recovery resource. + + Moreover, in the context of this analysis, a vertical hierarchy + consists of multiple layered transport planes providing different: + + - Discrete bandwidth granularities for non-packet LSPs such as OCh, + ODUk, STS_SPE/HOVC, and VT_SPE/LOVC LSPs and continuous bandwidth + granularities for packet LSPs. + + - Potential recovery capabilities with different temporal + granularities: ranging from milliseconds to tens of seconds + + Note: based on the bandwidth granularity, we can determine four + classes of vertical hierarchies: (1) packet over packet, (2) packet + over circuit, (3) circuit over packet, and (4) circuit over circuit. + Below we briefly expand on (4) only. (2) is covered in [RFC3386]. (1) + is extensively covered by the MPLS Working Group, and (3) by the PWE3 + Working Group. + + In SONET/SDH environments, one typically considers the VT_SPE/LOVC + and STS SPE/HOVC as independent layers (for example, VT_SPE/LOVC LSP + uses the underlying STS_SPE/HOVC LSPs as links). In OTN, the ODUk + path layers will lie on the OCh path layer, i.e., the ODUk LSPs use + the underlying OCh LSPs as OTUk links. Note here that lower layer + LSPs may simply be provisioned and not necessarily dynamically + triggered or established (control driven approach). In this context, + an LSP at the path layer (i.e., established using GMPLS signaling), + such as an optical channel LSP, appears at the OTUk layer as a link, + controlled by a link management protocol such as LMP. + + The first key issue with multi-layer recovery is that achieving + individual or bulk LSP recovery will be as efficient as the + underlying link (local span) recovery. In such a case, the span can + be either protected or unprotected, but the LSP it carries must be + (at least locally) recoverable. Therefore, the span recovery process + can be either independent when protected (or restorable), or + triggered by the upper LSP recovery process. The former case + requires coordination to achieve subsequent LSP recovery. Therefore, + in order to achieve robustness and fast convergence, multi-layer + recovery requires a fine-tuned coordination mechanism. + + + + + +Papadimitriou & Mannie Informational [Page 29] + +RFC 4428 GMPLS Recovery Mechanisms March 2006 + + + Moreover, in the absence of adequate recovery mechanism coordination + (for instance, a pre-determined coordination when using a hold-off + timer), a failure notification may propagate from one layer to the + next one within a recovery hierarchy. This can cause "collisions" + and trigger simultaneous recovery actions that may lead to race + conditions and, in turn, reduce the optimization of the resource + utilization and/or generate global instabilities in the network (see + [MANCHESTER]). Therefore, a consistent and efficient escalation + strategy is needed to coordinate recovery across several layers. + + One can expect that the definition of the recovery mechanisms and + protocol(s) is technology-independent so that they can be + consistently implemented at different layers; this would in turn + simplify their global coordination. Moreover, as mentioned in + [RFC3386], some looser form of coordination and communication between + (vertical) layers such as a consistent hold-off timer configuration + (and setup through signaling during the working LSP establishment) + can be considered, thereby allowing the synchronization between + recovery actions performed across these layers. + +7.2.1. Recovery Granularity + + In most environments, the design of the network and the vertical + distribution of the LSP bandwidth are such that the recovery + granularity is finer at higher layers. The OTN and SONET/SDH layers + can recover only the whole section or the individual connections they + transports whereas the IP/MPLS control plane can recover individual + packet LSPs or groups of packet LSPs independently of their + granularity. On the other side, the recovery granularity at the + sub-wavelength level (i.e., SONET/SDH) can be provided only when the + network includes devices switching at the same granularity (and thus + not with optical channel level). Therefore, the network layer can + deliver control-plane-driven recovery mechanisms on a per-LSP basis + if and only if these LSPs have their corresponding switching + granularity supported at the transport plane level. + +7.3. Escalation Strategies + + There are two types of escalation strategies (see [DEMEESTER]): + bottom-up and top-down. + + The bottom-up approach assumes that lower layer recovery types and + schemes are more expedient and faster than upper layer ones. + Therefore, we can inhibit or hold off higher layer recovery. + However, this assumption is not entirely true. Consider for instance + a SONET/SDH based protection mechanism (with a protection switching + time of less than 50 ms) lying on top of an OTN restoration mechanism + (with a restoration time of less than 200 ms). Therefore, this + + + +Papadimitriou & Mannie Informational [Page 30] + +RFC 4428 GMPLS Recovery Mechanisms March 2006 + + + assumption should be (at least) clarified as: the lower layer + recovery mechanism is expected to be faster than the upper level one, + if the same type of recovery mechanism is used at each layer. + + Consequently, taking into account the recovery actions at the + different layers in a bottom-up approach: if lower layer recovery + mechanisms are provided and sequentially activated in conjunction + with higher layer ones, the lower layers must have an opportunity to + recover normal traffic before the higher layers do. However, if + lower layer recovery is slower than higher layer recovery, the lower + layer must either communicate the failure-related information to the + higher layer(s) (and allow it to perform recovery), or use a hold-off + timer in order to temporarily set the higher layer recovery action in + a "standby mode". Note that the a priori information exchange + between layers concerning their efficiency is not within the current + scope of this document. Nevertheless, the coordination functionality + between layers must be configurable and tunable. + + For example, coordination between the optical and packet layer + control plane enables the optical layer to perform the failure + management operations (in particular, failure detection and + notification) while giving to the packet layer control plane the + authority to decide and perform the recovery actions. If the packet + layer recovery action is unsuccessful, fallback at the optical layer + can be performed subsequently. + + The top-down approach attempts service recovery at the higher layers + before invoking lower layer recovery. Higher layer recovery is + service selective, and permits "per-CoS" or "per-connection" re- + routing. With this approach, the most important aspect is that the + upper layer should provide its own reliable and independent failure + detection mechanism from the lower layer. + + [DEMEESTER] also suggests recovery mechanisms incorporating a + coordinated effort shared by two adjacent layers with periodic status + updates. Moreover, some of these recovery operations can be pre- + assigned (on a per-link basis) to a certain layer, e.g., a given link + will be recovered at the packet layer while another will be recovered + at the optical layer. + +7.4. Disjointness + + Having link and node diverse working and recovery LSPs/spans does not + guarantee their complete disjointness. Due to the common physical + layer topology (passive), additional hierarchical concepts, such as + the Shared Risk Link Group (SRLG), and mechanisms, such as SRLG + diverse path computation, must be developed to provide complete + working and recovery LSP/span disjointness (see [IPO-IMP] and + + + +Papadimitriou & Mannie Informational [Page 31] + +RFC 4428 GMPLS Recovery Mechanisms March 2006 + + + [RFC4202]). Otherwise, a failure affecting the working LSP/span + would also potentially affect the recovery LSP/span; one refers to + such an event as "common failure". + +7.4.1. SRLG Disjointness + + A Shared Risk Link Group (SRLG) is defined as the set of links + sharing a common risk (such as a common physical resource such as a + fiber link or a fiber cable). For instance, a set of links L belongs + to the same SRLG s, if they are provisioned over the same fiber link + f. + + The SRLG properties can be summarized as follows: + + 1) A link belongs to more than one SRLG if and only if it crosses one + of the resources covered by each of them. + + 2) Two links belonging to the same SRLG can belong individually to + (one or more) other SRLGs. + + 3) The SRLG set S of an LSP is defined as the union of the individual + SRLG s of the individual links composing this LSP. + + SRLG disjointness is also applicable to LSPs: + + The LSP SRLG disjointness concept is based on the following + postulate: an LSP (i.e., a sequence of links and nodes) covers an + SRLG if and only if it crosses one of the links or nodes belonging + to that SRLG. + + Therefore, the SRLG disjointness for LSPs, can be defined as + follows: two LSPs are disjoint with respect to an SRLG s if and + only if they do not cover simultaneously this SRLG s. + + Whilst the SRLG disjointness for LSPs with respect to a set S of + SRLGs, is defined as follows: two LSPs are disjoint with respect + to a set of SRLGs S if and only if the set of SRLGs that are + common to both LSPs is disjoint from set S. + + The impact on recovery is noticeable: SRLG disjointness is a + necessary (but not a sufficient) condition to ensure network + survivability. With respect to the physical network resources, a + working-recovery LSP/span pair must be SRLG-disjoint in case of + dedicated recovery type. On the other hand, in case of shared + recovery, a group of working LSP/spans must be mutually SRLG-disjoint + in order to allow for a (single and common) shared recovery LSP that + is itself SRLG-disjoint from each of the working LSPs/spans. + + + + +Papadimitriou & Mannie Informational [Page 32] + +RFC 4428 GMPLS Recovery Mechanisms March 2006 + + +8. Recovery Mechanisms Analysis + + In order to provide a structured analysis of the recovery mechanisms + detailed in the previous sections, the following dimensions can be + considered: + + 1. Fast convergence (performance): provide a mechanism that + aggregates multiple failures (implying fast failure detection and + correlation mechanisms) and fast recovery decision independently + of the number of failures occurring in the optical network (also + implying a fast failure notification). + + 2. Efficiency (scalability): minimize the switching time required for + LSP/span recovery independently of the number of LSPs/spans being + recovered (this implies efficient failure correlation, fast + failure notification, and time-efficient recovery mechanisms). + + 3. Robustness (availability): minimize the LSP/span downtime + independently of the underlying topology of the transport plane + (this implies a highly responsive recovery mechanism). + + 4. Resource optimization (optimality): minimize the resource + capacity, including LSPs/spans and nodes (switching capacity), + required for recovery purposes; this dimension can also be + referred to as optimizing the sharing degree of the recovery + resources. + + 5. Cost optimization: provide a cost-effective recovery type/scheme. + + However, these dimensions are either outside the scope of this + document (such as cost optimization and recovery path computational + aspects) or mutually conflicting. For instance, it is obvious that + providing a 1+1 LSP protection minimizes the LSP downtime (in case of + failure) while being non-scalable and consuming recovery resource + without enabling any extra-traffic. + + The following sections analyze the recovery phases and mechanisms + detailed in the previous sections with respect to the dimensions + described above in order to assess the GMPLS protocol suite + capabilities and applicability. In turn, this allows the evaluation + of the potential need for further GMPLS signaling and routing + extensions. + + + + + + + + + +Papadimitriou & Mannie Informational [Page 33] + +RFC 4428 GMPLS Recovery Mechanisms March 2006 + + +8.1. Fast Convergence (Detection/Correlation and Hold-off Time) + + Fast convergence is related to the failure management operations. It + refers to the time elapsed between failure detection/correlation and + hold-off time, the point at which the recovery switching actions are + initiated. This point has been detailed in Section 4. + +8.2. Efficiency (Recovery Switching Time) + + In general, the more pre-assignment/pre-planning of the recovery + LSP/span, the more rapid the recovery is. Because protection implies + pre-assignment (and cross-connection) of the protection resources, in + general, protection recovers faster than restoration. + + Span restoration is likely to be slower than most span protection + types; however this greatly depends on the efficiency of the span + restoration signaling. LSP restoration with pre-signaled and pre- + selected recovery resources is likely to be faster than fully dynamic + LSP restoration, especially because of the elimination of any + potential crankback during the recovery LSP establishment. + + If one excludes the crankback issue, the difference between dynamic + and pre-planned restoration depends on the restoration path + computation and selection time. Since computational considerations + are outside the scope of this document, it is up to the vendor to + determine the average and maximum path computation time in different + scenarios and to the operator to decide whether or not dynamic + restoration is advantageous over pre-planned schemes that depend on + the network environment. This difference also depends on the + flexibility provided by pre-planned restoration versus dynamic + restoration. Pre-planned restoration implies a somewhat limited + number of failure scenarios (that can be due, for instance, to local + storage capacity limitation). Dynamic restoration enables on-demand + path computation based on the information received through failure + notification message, and as such, it is more robust with respect to + the failure scenario scope. + + Moreover, LSP segment restoration, in particular, dynamic restoration + (i.e., no path pre-computation, so none of the recovery resource is + pre-reserved) will generally be faster than end-to-end LSP + restoration. However, local LSP restoration assumes that each LSP + segment end-point has enough computational capacity to perform this + operation while end-to-end LSP restoration requires only that LSP + end-points provide this path computation capability. + + Recovery time objectives for SONET/SDH protection switching (not + including time to detect failure) are specified in [G.841] at 50 ms, + taking into account constraints on distance, number of connections + + + +Papadimitriou & Mannie Informational [Page 34] + +RFC 4428 GMPLS Recovery Mechanisms March 2006 + + + involved, and in the case of ring enhanced protection, number of + nodes in the ring. Recovery time objectives for restoration + mechanisms have been proposed through a separate effort [RFC3386]. + +8.3. Robustness + + In general, the less pre-assignment (protection)/pre-planning + (restoration) of the recovery LSP/span, the more robust the recovery + type or scheme is to a variety of single failures, provided that + adequate resources are available. Moreover, the pre-selection of the + recovery resources gives (in the case of multiple failure scenarios) + less flexibility than no recovery resource pre-selection. For + instance, if failures occur that affect two LSPs sharing a common + link along their restoration paths, then only one of these LSPs can + be recovered. This occurs unless the restoration path of at least + one of these LSPs is re-computed, or the local resource assignment is + modified on the fly. + + In addition, recovery types and schemes with pre-planned recovery + resources (in particular, LSP/spans for protection and LSPs for + restoration purposes) will not be able to recover from failures that + simultaneously affect both the working and recovery LSP/span. Thus, + the recovery resources should ideally be as disjoint as possible + (with respect to link, node, and SRLG) from the working ones, so that + any single failure event will not affect both working and recovery + LSP/span. In brief, working and recovery resources must be fully + diverse in order to guarantee that a given failure will not affect + simultaneously the working and the recovery LSP/span. Also, the risk + of simultaneous failure of the working and the recovery LSPs can be + reduced. It is reduced by computing a new recovery path whenever a + failure occurs along one of the recovery LSPs or by computing a new + recovery path and provision the corresponding LSP whenever a failure + occurs along a working LSP/span. Both methods enable the network to + maintain the number of available recovery path constant. + + The robustness of a recovery scheme is also determined by the amount + of pre-reserved (i.e., signaled) recovery resources within a given + shared resource pool: as the sharing degree of recovery resources + increases, the recovery scheme becomes less robust to multiple + LSP/span failure occurrences. Recovery schemes, in particular + restoration, with pre-signaled resource reservation (with or without + pre-selection) should be capable of reserving an adequate amount of + resource to ensure recovery from any specific set of failure events, + such as any single SRLG failure, any two SRLG failures, etc. + + + + + + + +Papadimitriou & Mannie Informational [Page 35] + +RFC 4428 GMPLS Recovery Mechanisms March 2006 + + +8.4. Resource Optimization + + It is commonly admitted that sharing recovery resources provides + network resource optimization. Therefore, from a resource + utilization perspective, protection schemes are often classified with + respect to their degree of sharing recovery resources with the + working entities. Moreover, non-permanent bridging protection types + allow (under normal conditions) for extra-traffic over the recovery + resources. + + From this perspective, the following statements are true: + + 1) 1+1 LSP/Span protection is the most resource-consuming protection + type because it does not allow for any extra traffic. + + 2) 1:1 LSP/span recovery requires dedicated recovery LSP/span + allowing for extra traffic. + + 3) 1:N and M:N LSP/span recovery require 1 (and M, respectively) + recovery LSP/span (shared between the N working LSP/span) allowing + for extra traffic. + + Obviously, 1+1 protection precludes, and 1:1 recovery does not allow + for any recovery LSP/span sharing, whereas 1:N and M:N recovery do + allow sharing of 1 (M, respectively) recovery LSP/spans between N + working LSP/spans. However, despite the fact that 1:1 LSP recovery + precludes the sharing of the recovery LSP, the recovery schemes that + can be built from it (e.g., (1:1)^n, see Section 5.4) do allow + sharing of its recovery resources. In addition, the flexibility in + the usage of shared recovery resources (in particular, shared links) + may be limited because of network topology restrictions, e.g., fixed + ring topology for traditional enhanced protection schemes. + + On the other hand, when using LSP restoration with pre-signaled + resource reservation, the amount of reserved restoration capacity is + determined by the local bandwidth reservation policies. In LSP + restoration schemes with re-provisioning, a pool of spare resources + can be defined from which all resources are selected after failure + occurrence for the purpose of restoration path computation. The + degree to which restoration schemes allow sharing amongst multiple + independent failures is then directly inferred from the size of the + resource pool. Moreover, in all restoration schemes, spare resources + can be used to carry preemptible traffic (thus over preemptible + LSP/span) when the corresponding resources have not been committed + for LSP/span recovery purposes. + + From this, it clearly follows that less recovery resources (i.e., + LSP/spans and switching capacity) have to be allocated to a shared + + + +Papadimitriou & Mannie Informational [Page 36] + +RFC 4428 GMPLS Recovery Mechanisms March 2006 + + + recovery resource pool if a greater sharing degree is allowed. Thus, + the network survivability level is determined by the policy that + defines the amount of shared recovery resources and by the maximum + sharing degree allowed for these recovery resources. + +8.4.1. Recovery Resource Sharing + + When recovery resources are shared over several LSP/Spans, the use of + the Maximum Reservable Bandwidth, the Unreserved Bandwidth, and the + Maximum LSP Bandwidth (see [RFC4202]) provides the information needed + to obtain the optimization of the network resources allocated for + shared recovery purposes. + + The Maximum Reservable Bandwidth is defined as the Maximum Link + Bandwidth but it may be greater in case of link over-subscription. + + The Unreserved Bandwidth (at priority p) is defined as the bandwidth + not yet reserved on a given TE link (its initial value for each + priority p corresponds to the Maximum Reservable Bandwidth). Last, + the Maximum LSP Bandwidth (at priority p) is defined as the smaller + of Unreserved Bandwidth (at priority p) and Maximum Link Bandwidth. + + Here, one generally considers a recovery resource sharing degree (or + ratio) to globally optimize the shared recovery resource usage. The + distribution of the bandwidth utilization per TE link can be inferred + from the per-priority bandwidth pre-allocation. By using the Maximum + LSP Bandwidth and the Maximum Reservable Bandwidth, the amount of + (over-provisioned) resources that can be used for shared recovery + purposes is known from the IGP. + + In order to analyze this behavior, we define the difference between + the Maximum Reservable Bandwidth (in the present case, this value is + greater than the Maximum Link Bandwidth) and the Maximum LSP + Bandwidth per TE link i as the Maximum Shareable Bandwidth or + max_R[i]. Within this quantity, the amount of bandwidth currently + allocated for shared recovery per TE link i is defined as R[i]. Both + quantities are expressed in terms of discrete bandwidth units (and + thus, the Minimum LSP Bandwidth is of one bandwidth unit). + + The knowledge of this information available per TE link can be + exploited in order to optimize the usage of the resources allocated + per TE link for shared recovery. If one refers to r[i] as the actual + bandwidth per TE link i (in terms of discrete bandwidth units) + committed for shared recovery, then the following quantity must be + maximized over the potential TE link candidates: + + sum {i=1}^N [(R{i} - r{i})/(t{i} - b{i})] + + + + +Papadimitriou & Mannie Informational [Page 37] + +RFC 4428 GMPLS Recovery Mechanisms March 2006 + + + or equivalently: sum {i=1}^N [(R{i} - r{i})/r{i}] + + with R{i} >= 1 and r{i} >= 1 (in terms of per component + bandwidth unit) + + In this formula, N is the total number of links traversed by a given + LSP, t[i] the Maximum Link Bandwidth per TE link i, and b[i] the sum + per TE link i of the bandwidth committed for working LSPs and other + recovery LSPs (thus except "shared bandwidth" LSPs). The quantity + [(R{i} - r{i})/r{i}] is defined as the Shared (Recovery) Bandwidth + Ratio per TE link i. In addition, TE links for which R[i] reaches + max_R[i] or for which r[i] = 0 are pruned during shared recovery path + computation as well as TE links for which max_R[i] = r[i] that can + simply not be shared. + + More generally, one can draw the following mapping between the + available bandwidth at the transport and control plane level: + + - ---------- Max Reservable Bandwidth + | ----- ^ + |R ----- | + | ----- | + - ----- |max_R + ----- | + -------- TE link Capacity - ------ | - Maximum TE Link Bandwidth + ----- |r ----- v + ----- <------ b ------> - ---------- Maximum LSP Bandwidth + ----- ----- + ----- ----- + ----- ----- + ----- ----- + ----- ----- <--- Minimum LSP Bandwidth + -------- 0 ---------- 0 + + Note that the above approach does not require the flooding of any per + LSP information or any detailed distribution of the bandwidth + allocation per component link or individual ports or even any per- + priority shareable recovery bandwidth information (using a dedicated + sub-TLV). The latter would provide the same capability as the + already defined Maximum LSP bandwidth per-priority information. This + approach is referred to as a Partial (or Aggregated) Information + Routing as described in [KODIALAM1] and [KODIALAM2]. They show that + the difference obtained with a Full (or Complete) Information Routing + approach (where for the whole set of working and recovery LSPs, the + amount of bandwidth units they use per-link is known at each node and + for each link) is clearly negligible. The Full Information Routing + + + + + +Papadimitriou & Mannie Informational [Page 38] + +RFC 4428 GMPLS Recovery Mechanisms March 2006 + + + approach is detailed in [GLI]. Note also that both approaches rely + on the deterministic knowledge (at different degrees) of the network + topology and resource usage status. + + Moreover, extending the GMPLS signaling capabilities can enhance the + Partial Information Routing approach. It is enhanced by allowing + working-LSP-related information and, in particular, its path + (including link and node identifiers) to be exchanged with the + recovery LSP request. This enables more efficient admission control + at upstream nodes of shared recovery resources, and in particular, + links (see Section 8.4.3). + +8.4.2. Recovery Resource Sharing and SRLG Recovery + + Resource shareability can also be maximized with respect to the + number of times each SRLG is protected by a recovery resource (in + particular, a shared TE link) and methods can be considered for + avoiding contention of the shared recovery resources in case of + single SRLG failure. These methods enable the sharing of recovery + resources between two (or more) recovery LSPs, if their respective + working LSPs are mutually disjoint with respect to link, node, and + SRLGs. Then, a single failure does not simultaneously disrupt + several (or at least two) working LSPs. + + For instance, [BOUILLET] shows that the Partial Information Routing + approach can be extended to cover recovery resource shareability with + respect to SRLG recoverability (i.e., the number of times each SRLG + is recoverable). By flooding this aggregated information per TE + link, path computation and selection of SRLG-diverse recovery LSPs + can be optimized with respect to the sharing of recovery resource + reserved on each TE link. This yields a performance difference of + less than 5%, which is negligible compared to the corresponding Full + Information Flooding approach (see [GLI]). + + For this purpose, additional extensions to [RFC4202] in support of + path computation for shared mesh recovery have been often considered + in the literature. TE link attributes would include, among others, + the current number of recovery LSPs sharing the recovery resources + reserved on the TE link, and the current number of SRLGs recoverable + by this amount of (shared) recovery resources reserved on the TE + link. The latter is equivalent to the current number of SRLGs that + will be recovered by the recovery LSPs sharing the recovery resource + reserved on the TE link. Then, if explicit SRLG recoverability is + considered, a TE link attribute would be added that includes the + explicit list of SRLGs (recoverable by the shared recovery resource + reserved on the TE link) and their respective shareable recovery + bandwidths. The latter information is equivalent to the shareable + recovery bandwidth per SRLG (or per group of SRLGs), which implies + + + +Papadimitriou & Mannie Informational [Page 39] + +RFC 4428 GMPLS Recovery Mechanisms March 2006 + + + that the amount of shareable bandwidth and the number of listed SRLGs + will decrease over time. + + Compared to the case of recovery resource sharing only (regardless of + SRLG recoverability, as described in Section 8.4.1), these additional + TE link attributes would potentially deliver better path computation + and selection (at a distinct ingress node) for shared mesh recovery + purposes. However, due to the lack of evidence of better efficiency + and due to the complexity that such extensions would generate, they + are not further considered in the scope of the present analysis. For + instance, a per-SRLG group minimum/maximum shareable recovery + bandwidth is restricted by the length that the corresponding (sub-) + TLV may take and thus the number of SRLGs that it can include. + Therefore, the corresponding parameter should not be translated into + GMPLS routing (or even signaling) protocol extensions in the form of + TE link sub-TLV. + +8.4.3. Recovery Resource Sharing, SRLG Disjointness and Admission + Control + + Admission control is a strict requirement to be fulfilled by nodes + giving access to shared links. This can be illustrated using the + following network topology: + + A ------ C ====== D + | | | + | | | + | B | + | | | + | | | + ------- E ------ F + + Node A creates a working LSP to D (A-C-D), B creates simultaneously a + working LSP to D (B-C-D) and a recovery LSP (B-E-F-D) to the same + destination. Then, A decides to create a recovery LSP to D (A-E-F- + D), but since the C-D span carries both working LSPs, node E should + either assign a dedicated resource for this recovery LSP or reject + this request if the C-D span has already reached its maximum recovery + bandwidth sharing ratio. In the latter case, C-D span failure would + imply that one of the working LSP would not be recoverable. + + Consequently, node E must have the required information to perform + admission control for the recovery LSP requests it processes + (implying for instance, that the path followed by the working LSP is + carried with the corresponding recovery LSP request). If node E can + guarantee that the working LSPs (A-C-D and B-C-D) are SRLG disjoint + over the C-D span, it may securely accept the incoming recovery LSP + request and assign to the recovery LSPs (A-E-F-D and B-E-F-D) the + + + +Papadimitriou & Mannie Informational [Page 40] + +RFC 4428 GMPLS Recovery Mechanisms March 2006 + + + same resources on the link E-F. This may occur if the link E-F has + not yet reached its maximum recovery bandwidth sharing ratio. In + this example, one assumes that the node failure probability is + negligible compared to the link failure probability. + + To achieve this, the path followed by the working LSP is transported + with the recovery LSP request and examined at each upstream node of + potentially shareable links. Admission control is performed using + the interface identifiers (included in the path) to retrieve in the + TE DataBase the list of SRLG IDs associated to each of the working + LSP links. If the working LSPs (A-C-D and B-C-D) have one or more + link or SRLG ID in common (in this example, one or more SRLG id in + common over the span C-D), node E should not assign the same resource + over link E-F to the recovery LSPs (A-E-F-D and B-E-F-D). Otherwise, + one of these working LSPs would not be recoverable if C-D span + failure occurred. + + There are some issues related to this method; the major one is the + number of SRLG IDs that a single link can cover (more than 100, in + complex environments). Moreover, when using link bundles, this + approach may generate the rejection of some recovery LSP requests. + This occurs when the SRLG sub-TLV corresponding to a link bundle + includes the union of the SRLG id list of all the component links + belonging to this bundle (see [RFC4202] and [RFC4201]). + + In order to overcome this specific issue, an additional mechanism may + consist of querying the nodes where the information would be + available (in this case, node E would query C). The main drawback of + this method is that (in addition to the dedicated mechanism(s) it + requires) it may become complex when several common nodes are + traversed by the working LSPs. Therefore, when using link bundles, + solving this issue is closely related to the sequence of the recovery + operations. Per-component flooding of SRLG identifiers would deeply + impact the scalability of the link state routing protocol. + Therefore, one may rely on the usage of an on-line accessible network + management system. + + + + + + + + + + + + + + + +Papadimitriou & Mannie Informational [Page 41] + +RFC 4428 GMPLS Recovery Mechanisms March 2006 + + +9. Summary and Conclusions + + The following table summarizes the different recovery types and + schemes analyzed throughout this document. + + -------------------------------------------------------------------- + | Path Search (computation and selection) + -------------------------------------------------------------------- + | Pre-planned (a) | Dynamic (b) + -------------------------------------------------------------------- + | | faster recovery | Does not apply + | | less flexible | + | 1 | less robust | + | | most resource-consuming | + Path | | | + Setup ------------------------------------------------------------ + | | relatively fast recovery | Does not apply + | | relatively flexible | + | 2 | relatively robust | + | | resource consumption | + | | depends on sharing degree | + ------------------------------------------------------------ + | | relatively fast recovery | less faster (computation) + | | more flexible | most flexible + | 3 | relatively robust | most robust + | | less resource-consuming | least resource-consuming + | | depends on sharing degree | + -------------------------------------------------------------------- + + 1a. Recovery LSP setup (before failure occurrence) with resource + reservation (i.e., signaling) and selection is referred to as LSP + protection. + + 2a. Recovery LSP setup (before failure occurrence) with resource + reservation (i.e., signaling) and with resource pre-selection is + referred to as pre-planned LSP re-routing with resource pre- + selection. This implies only recovery LSP activation after + failure occurrence. + + 3a. Recovery LSP setup (before failure occurrence) with resource + reservation (i.e., signaling) and without resource selection is + referred to as pre-planned LSP re-routing without resource pre- + selection. This implies recovery LSP activation and resource + (i.e., label) selection after failure occurrence. + + 3b. Recovery LSP setup after failure occurrence is referred to as to + as LSP re-routing, which is full when recovery LSP path + computation occurs after failure occurrence. + + + +Papadimitriou & Mannie Informational [Page 42] + +RFC 4428 GMPLS Recovery Mechanisms March 2006 + + + Thus, the term pre-planned refers to recovery LSP path pre- + computation, signaling (reservation), and a priori resource selection + (optional), but not cross-connection. Also, the shared-mesh recovery + scheme can be viewed as a particular case of 2a) and 3a), using the + additional constraint described in Section 8.4.3. + + The implementation of these recovery mechanisms requires only + considering extensions to GMPLS signaling protocols (i.e., [RFC3471] + and [RFC3473]). These GMPLS signaling extensions should mainly focus + in delivering (1) recovery LSP pre-provisioning for the cases 1a, 2a, + and 3a, (2) LSP failure notification, (3) recovery LSP switching + action(s), and (4) reversion mechanisms. + + Moreover, the present analysis (see Section 8) shows that no GMPLS + routing extensions are expected to efficiently implement any of these + recovery types and schemes. + +10. Security Considerations + + This document does not introduce any additional security issue or + imply any specific security consideration from [RFC3945] to the + current RSVP-TE GMPLS signaling, routing protocols (OSPF-TE, IS-IS- + TE) or network management protocols. + + However, the authorization of requests for resources by GMPLS-capable + nodes should determine whether a given party, presumably already + authenticated, has a right to access the requested resources. This + determination is typically a matter of local policy control, for + example, by setting limits on the total bandwidth made available to + some party in the presence of resource contention. Such policies may + become quite complex as the number of users, types of resources, and + sophistication of authorization rules increases. This is + particularly the case for recovery schemes that assume pre-planned + sharing of recovery resources, or contention for resources in case of + dynamic re-routing. + + Therefore, control elements should match the requests against the + local authorization policy. These control elements must be capable + of making decisions based on the identity of the requester, as + verified cryptographically and/or topologically. + +11. Acknowledgements + + The authors would like to thank Fabrice Poppe (Alcatel) and Bart + Rousseau (Alcatel) for their revision effort, and Richard Rabbat + (Fujitsu Labs), David Griffith (NIST), and Lyndon Ong (Ciena) for + their useful comments. + + + + +Papadimitriou & Mannie Informational [Page 43] + +RFC 4428 GMPLS Recovery Mechanisms March 2006 + + + Thanks also to Adrian Farrel for the thorough review of the document. + +12. References + +12.1. Normative References + + [RFC2119] Bradner, S., "Key words for use in RFCs to Indicate + Requirement Levels", BCP 14, RFC 2119, March 1997. + + [RFC3471] Berger, L., "Generalized Multi-Protocol Label Switching + (GMPLS) Signaling Functional Description", RFC 3471, + January 2003. + + [RFC3473] Berger, L., "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. + + [RFC4201] Kompella, K., Rekhter, Y., and L. Berger, "Link Bundling + in MPLS Traffic Engineering (TE)", RFC 4201, October + 2005. + + [RFC4202] Kompella, K., Ed. and Y. Rekhter, Ed., "Routing + Extensions in Support of Generalized Multi-Protocol + Label Switching (GMPLS)", RFC 4202, October 2005. + + [RFC4204] Lang, J., Ed., "Link Management Protocol (LMP)", RFC + 4204, October 2005. + + [RFC4209] Fredette, A., Ed. and J. Lang, Ed., "Link Management + Protocol (LMP) for Dense Wavelength Division + Multiplexing (DWDM) Optical Line Systems", RFC 4209, + October 2005. + + [RFC4427] Mannie E., Ed. and D. Papadimitriou, Ed., "Recovery + (Protection and Restoration) Terminology for Generalized + Multi-Protocol Label Switching (GMPLS)", RFC 4427, March + 2006. + +12.2. Informative References + + [BOUILLET] E. Bouillet, et al., "Stochastic Approaches to Compute + Shared Meshed Restored Lightpaths in Optical Network + Architectures," IEEE Infocom 2002, New York City, June + 2002. + + + +Papadimitriou & Mannie Informational [Page 44] + +RFC 4428 GMPLS Recovery Mechanisms March 2006 + + + [DEMEESTER] P. Demeester, et al., "Resilience in Multilayer + Networks," IEEE Communications Magazine, Vol. 37, No. 8, + pp. 70-76, August 1998. + + [GLI] G. Li, et al., "Efficient Distributed Path Selection for + Shared Restoration Connections," IEEE Infocom 2002, New + York City, June 2002. + + [IPO-IMP] Strand, J. and A. Chiu, "Impairments and Other + Constraints on Optical Layer Routing", RFC 4054, May + 2005. + + [KODIALAM1] M. Kodialam and T.V. Lakshman, "Restorable Dynamic + Quality of Service Routing," IEEE Communications + Magazine, pp. 72-81, June 2002. + + [KODIALAM2] M. Kodialam and T.V. Lakshman, "Dynamic Routing of + Restorable Bandwidth-Guaranteed Tunnels using Aggregated + Network Resource Usage Information," IEEE/ ACM + Transactions on Networking, pp. 399-410, June 2003. + + [MANCHESTER] J. Manchester, P. Bonenfant and C. Newton, "The + Evolution of Transport Network Survivability," IEEE + Communications Magazine, August 1999. + + [RFC3386] Lai, W. and D. McDysan, "Network Hierarchy and + Multilayer Survivability", RFC 3386, November 2002. + + [T1.105] ANSI, "Synchronous Optical Network (SONET): Basic + Description Including Multiplex Structure, Rates, and + Formats," ANSI T1.105, January 2001. + + [WANG] J. Wang, L. Sahasrabuddhe, and B. Mukherjee, "Path vs. + Subpath vs. Link Restoration for Fault Management in + IP-over-WDM Networks: Performance Comparisons Using + GMPLS Control Signaling," IEEE Communications Magazine, + pp. 80-87, November 2002. + + For information on the availability of the following documents, + please see http://www.itu.int + + [G.707] ITU-T, "Network Node Interface for the Synchronous + Digital Hierarchy (SDH)," Recommendation G.707, October + 2000. + + [G.709] ITU-T, "Network Node Interface for the Optical Transport + Network (OTN)," Recommendation G.709, February 2001 (and + Amendment no.1, October 2001). + + + +Papadimitriou & Mannie Informational [Page 45] + +RFC 4428 GMPLS Recovery Mechanisms March 2006 + + + [G.783] ITU-T, "Characteristics of Synchronous Digital Hierarchy + (SDH) Equipment Functional Blocks," Recommendation + G.783, October 2000. + + [G.798] ITU-T, "Characteristics of optical transport network + hierarchy equipment functional block," Recommendation + G.798, June 2004. + + [G.806] ITU-T, "Characteristics of Transport Equipment - + Description Methodology and Generic Functionality", + Recommendation G.806, October 2000. + + [G.841] ITU-T, "Types and Characteristics of SDH Network + Protection Architectures," Recommendation G.841, October + 1998. + + [G.842] ITU-T, "Interworking of SDH network protection + architectures," Recommendation G.842, October 1998. + + [G.874] ITU-T, "Management aspects of the optical transport + network element," Recommendation G.874, November 2001. + +Editors' Addresses + + Dimitri Papadimitriou + Alcatel + Francis Wellesplein, 1 + B-2018 Antwerpen, Belgium + + Phone: +32 3 240-8491 + EMail: dimitri.papadimitriou@alcatel.be + + + Eric Mannie + Perceval + Rue Tenbosch, 9 + 1000 Brussels + Belgium + + Phone: +32-2-6409194 + EMail: eric.mannie@perceval.net + + + + + + + + + + +Papadimitriou & Mannie Informational [Page 46] + +RFC 4428 GMPLS Recovery Mechanisms March 2006 + + +Full Copyright Statement + + Copyright (C) The Internet Society (2006). + + This document is subject to the rights, licenses and restrictions + contained in BCP 78, and except as set forth therein, the authors + retain all their rights. + + This document and the information contained herein are provided on an + "AS IS" basis and THE CONTRIBUTOR, THE ORGANIZATION HE/SHE REPRESENTS + OR IS SPONSORED BY (IF ANY), THE INTERNET SOCIETY AND THE INTERNET + ENGINEERING TASK FORCE DISCLAIM ALL WARRANTIES, EXPRESS OR IMPLIED, + INCLUDING BUT NOT LIMITED TO ANY WARRANTY THAT THE USE OF THE + INFORMATION HEREIN WILL NOT INFRINGE ANY RIGHTS OR ANY IMPLIED + WARRANTIES OF MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE. + +Intellectual Property + + The IETF takes no position regarding the validity or scope of any + Intellectual Property Rights or other rights that might be claimed to + pertain to the implementation or use of the technology described in + this document or the extent to which any license under such rights + might or might not be available; nor does it represent that it has + made any independent effort to identify any such rights. Information + on the procedures with respect to rights in RFC documents can be + found in BCP 78 and BCP 79. + + Copies of IPR disclosures made to the IETF Secretariat and any + assurances of licenses to be made available, or the result of an + attempt made to obtain a general license or permission for the use of + such proprietary rights by implementers or users of this + specification can be obtained from the IETF on-line IPR repository at + http://www.ietf.org/ipr. + + The IETF invites any interested party to bring to its attention any + copyrights, patents or patent applications, or other proprietary + rights that may cover technology that may be required to implement + this standard. Please address the information to the IETF at + ietf-ipr@ietf.org. + +Acknowledgement + + Funding for the RFC Editor function is provided by the IETF + Administrative Support Activity (IASA). + + + + + + + +Papadimitriou & Mannie Informational [Page 47] + -- cgit v1.2.3