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/rfc7347.txt | 1795 +++++++++++++++++++++++++++++++++++++++++++++++++++ 1 file changed, 1795 insertions(+) create mode 100644 doc/rfc/rfc7347.txt (limited to 'doc/rfc/rfc7347.txt') diff --git a/doc/rfc/rfc7347.txt b/doc/rfc/rfc7347.txt new file mode 100644 index 0000000..f92222c --- /dev/null +++ b/doc/rfc/rfc7347.txt @@ -0,0 +1,1795 @@ + + + + + + +Independent Submission H. van Helvoort, Ed. +Request for Comments: 7347 Huawei Technologies +Category: Informational J. Ryoo, Ed. +ISSN: 2070-1721 ETRI + H. Zhang + Huawei Technologies + F. Huang + Philips + H. Li + China Mobile + A. D'Alessandro + Telecom Italia + September 2014 + + + Pre-standard Linear Protection Switching in + MPLS Transport Profile (MPLS-TP) + +Abstract + + The IETF Standards Track solution for MPLS Transport Profile + (MPLS-TP) Linear Protection is provided in RFCs 6378, 7271, and 7324. + + This document describes the pre-standard implementation of MPLS-TP + Linear Protection that has been deployed by several network operators + using equipment from multiple vendors. At the time of publication, + these pre-standard implementations were still in operation carrying + live traffic. + + The specified mechanism supports 1+1 unidirectional/bidirectional + protection switching and 1:1 bidirectional protection switching. It + is purely supported by the MPLS-TP data plane and can work without + any control plane. + + + + + + + + + + + + + + + + + + +van Helvoort, et al. Informational [Page 1] + +RFC 7347 Pre-standard MPLS-TP Lin. Prot. Switching September 2014 + + +Status of This Memo + + This document is not an Internet Standards Track specification; it is + published for informational purposes. + + This is a contribution to the RFC Series, independently of any other + RFC stream. The RFC Editor has chosen to publish this document at + its discretion and makes no statement about its value for + implementation or deployment. Documents approved for publication by + the RFC Editor are not a candidate for any level of Internet + Standard; see Section 2 of RFC 5741. + + Information about the current status of this document, any errata, + and how to provide feedback on it may be obtained at + http://www.rfc-editor.org/info/rfc7347. + +Copyright Notice + + Copyright (c) 2014 IETF Trust and the persons identified as the + document authors. All rights reserved. + + This document is subject to BCP 78 and the IETF Trust's Legal + Provisions Relating to IETF Documents + (http://trustee.ietf.org/license-info) in effect on the date of + publication of this document. Please review these documents + carefully, as they describe your rights and restrictions with respect + to this document. + + + + + + + + + + + + + + + + + + + + + + + + +van Helvoort, et al. Informational [Page 2] + +RFC 7347 Pre-standard MPLS-TP Lin. Prot. Switching September 2014 + + +Table of Contents + + 1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . 4 + 2. Conventions Used in This Document . . . . . . . . . . . . . . 5 + 3. Acronyms . . . . . . . . . . . . . . . . . . . . . . . . . . 5 + 4. Linear Protection-Switching Overview . . . . . . . . . . . . 6 + 4.1. Protection Architecture Types . . . . . . . . . . . . . . 6 + 4.1.1. 1+1 Architecture . . . . . . . . . . . . . . . . . . 6 + 4.1.2. 1:1 Architecture . . . . . . . . . . . . . . . . . . 6 + 4.1.3. 1:n Architecture . . . . . . . . . . . . . . . . . . 7 + 4.2. Protection Switching Type . . . . . . . . . . . . . . . . 7 + 4.3. Protection Operation Type . . . . . . . . . . . . . . . . 7 + 5. Protection-Switching Trigger Conditions . . . . . . . . . . . 8 + 5.1. Fault Conditions . . . . . . . . . . . . . . . . . . . . 8 + 5.2. External Commands . . . . . . . . . . . . . . . . . . . . 8 + 5.2.1. End-to-End Commands . . . . . . . . . . . . . . . . . 8 + 5.2.2. Local Commands . . . . . . . . . . . . . . . . . . . 9 + 6. Protection-Switching Schemes . . . . . . . . . . . . . . . . 10 + 6.1. 1+1 Unidirectional Protection Switching . . . . . . . . . 10 + 6.2. 1+1 Bidirectional Protection Switching . . . . . . . . . 11 + 6.3. 1:1 Bidirectional Protection Switching . . . . . . . . . 12 + 7. APS Protocol . . . . . . . . . . . . . . . . . . . . . . . . 13 + 7.1. APS PDU Format . . . . . . . . . . . . . . . . . . . . . 13 + 7.2. APS Transmission . . . . . . . . . . . . . . . . . . . . 16 + 7.3. Hold-Off Timer . . . . . . . . . . . . . . . . . . . . . 17 + 7.4. WTR Timer . . . . . . . . . . . . . . . . . . . . . . . . 17 + 7.5. Command Acceptance and Retention . . . . . . . . . . . . 18 + 7.6. Exercise Operation . . . . . . . . . . . . . . . . . . . 18 + 8. Protection-Switching Logic . . . . . . . . . . . . . . . . . 19 + 8.1. Principle of Operation . . . . . . . . . . . . . . . . . 19 + 8.2. Equal Priority Requests . . . . . . . . . . . . . . . . . 21 + 8.3. Signal Degrade of the Protection Transport Entity . . . . 22 + 9. Protection-Switching State Transition Tables . . . . . . . . 22 + 10. Security Considerations . . . . . . . . . . . . . . . . . . . 24 + 11. Acknowledgements . . . . . . . . . . . . . . . . . . . . . . 24 + 12. References . . . . . . . . . . . . . . . . . . . . . . . . . 24 + 12.1. Normative References . . . . . . . . . . . . . . . . . . 24 + 12.2. Informative References . . . . . . . . . . . . . . . . . 25 + Appendix A. Operation Examples of the APS Protocol . . . . . . . 26 + + + + + + + + + + + + +van Helvoort, et al. Informational [Page 3] + +RFC 7347 Pre-standard MPLS-TP Lin. Prot. Switching September 2014 + + +1. Introduction + + The IETF Standards Track solution for MPLS Transport Profile + (MPLS-TP) Linear Protection is provided in [RFC6378], [RFC7271], and + [RFC7324]. + + This document describes the pre-standard implementation of MPLS-TP + Linear Protection that has been deployed by several network operators + using equipment from multiple vendors. At the time of publication, + these pre-standard implementations were still in operation carrying + live traffic. + + This implementation was considered in the MPLS WG; however, a + different path was chosen. + + This document may be useful in the future if a vendor or operator is + trying to interwork with a different vendor or operator who has + deployed the pre-standard implementation, and it provides a permanent + record of the pre-standard implementation. It is also worth noting + that the experience gained during deployment of the implementations + of this document was used to refine [RFC7271]. + + MPLS-TP is defined as the transport profile of MPLS technology to + allow its deployment in transport networks. A typical feature of a + transport network is that it can provide fast protection switching + for end-to-end transport paths and transport path segments. The + protection-switching time is generally required to be less than 50 ms + to meet the strict requirements of services such as voice, private + line, etc. + + The goal of a linear protection-switching mechanism is to satisfy the + requirement of fast protection switching for an MPLS-TP network. + Linear protection switching means that, for one or more working + transport entities (working paths), there is one protection transport + entity (protection path), which is disjoint from any of the working + transport entities, ready to take over the service transmission when + a working transport entity has failed. + + This document specifies a 1+1 unidirectional protection-switching + mechanism for a unidirectional transport entity (either point to + point or point to multipoint) as well as a bidirectional point-to- + point transport entity and a 1+1/1:1 bidirectional protection- + switching mechanism for a point-to-point bidirectional transport + entity. Since bidirectional protection switching needs the + coordination of the two endpoints of the transport entity, this + document also specifies the Automatic Protection Switching (APS) + protocol, which is used for this purpose. + + + + +van Helvoort, et al. Informational [Page 4] + +RFC 7347 Pre-standard MPLS-TP Lin. Prot. Switching September 2014 + + + The linear protection mechanism described in this document is + applicable to both Label Switched Paths (LSPs) and Pseudowires (PWs). + + The APS protocol specified in this document is based on the same + principles and behavior of the APS protocol designed for Synchronous + Optical Network (SONET) [T1.105.01] / Synchronous Digital Hierarchy + (SDH) [G.841], Optical Transport Network (OTN) [G.873.1], and + Ethernet [G.8031] and provides commonality with the established + operation models utilized in transport network technologies (e.g., + SDH/SONET, OTN, and Ethernet). + +2. Conventions Used in This Document + + The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", + "SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this + document are to be interpreted as described in [RFC2119]. + +3. Acronyms + + This document uses the following acronyms: + + APS Automatic Protection Switching + DNR Do not Revert + EXER Exercise + G-ACh Generic Associated Channel + FS Forced Switch + LO Lockout of Protection + LSP Label Switched Path + MPLS-TP MPLS Transport Profile + MS Manual Switch + MS-P Manual Switch to Protection transport entity + MS-W Manual Switch to Working transport entity + NR No Request + OAM Operations, Administration, and Maintenance + OTN Optical Transport Network + PDU Protocol Data Unit + PW Pseudowire + RR Reverse Request + SD Signal Degrade + SD-P Signal Degrade on Protection transport entity + SD-W Signal Degrade on Working transport entity + SDH Synchronous Digital Hierarchy + SF Signal Fail + SF-P Signal Fail on Protection transport entity + SF-W Signal Fail on Working transport entity + SONET Synchronous Optical Network + WTR Wait to Restore + + + + +van Helvoort, et al. Informational [Page 5] + +RFC 7347 Pre-standard MPLS-TP Lin. Prot. Switching September 2014 + + +4. Linear Protection-Switching Overview + + To guarantee the protection-switching time for a working transport + entity, its protection transport entity is always preconfigured + before the failure occurs. Normally, traffic will be transmitted and + received on the working transport entity. Switching to the + protection transport entity is usually triggered by link or node + failure, external commands, etc. Note that external commands are + often used in transport networks by operators, and they are very + useful in cases of service adjustment, path maintenance, etc. + +4.1. Protection Architecture Types + +4.1.1. 1+1 Architecture + + In the 1+1 architecture, the protection transport entity is + associated with a working transport entity. The normal traffic is + permanently bridged onto both the working transport entity and the + protection transport entity at the source endpoint of the protected + domain. The normal traffic on working and protection transport + entities is transmitted simultaneously to the destination sink + endpoint of the protected domain, where a selection between the + working and protection transport entity is made based on + predetermined criteria, such as signal fail and signal degrade + indications. + +4.1.2. 1:1 Architecture + + In the 1:1 architecture, the protection transport entity is + associated with a working transport entity. When the working + transport entity is determined to be impaired, the normal traffic + MUST be transferred from the working to the protection transport + entity at both the source and sink endpoints of the protected domain. + The selection between the working and protection transport entities + is made based on predetermined criteria, such as signal fail and + signal degrade indications from the working or protection transport + entity. + + The bridge at the source endpoint can be realized in two ways: it is + either a selector bridge or a broadcast bridge. With a selector + bridge, the normal traffic is connected either to the working + transport entity or the protection transport entity. With a + broadcast bridge, the normal traffic is permanently connected to the + working transport entity, and in case a protection switch is active, + it is also connected to the protection transport entity. The + broadcast bridge is recommended to be used in revertive mode only. + + + + + +van Helvoort, et al. Informational [Page 6] + +RFC 7347 Pre-standard MPLS-TP Lin. Prot. Switching September 2014 + + +4.1.3. 1:n Architecture + + Details for the 1:n protection-switching architecture are out of + scope of this document and will be provided in a different document + in the future. + + It is worth noting that the APS protocol defined here is capable of + supporting 1:n operations. + +4.2. Protection Switching Type + + The linear protection-switching types can be a unidirectional + switching type or a bidirectional switching type. + + o Unidirectional switching type: Only the affected direction of the + working transport entity is switched to the protection transport + entity; the selectors at each endpoint operate independently. + This switching type is recommended to be used for 1+1 protection + in this document. + + o Bidirectional switching type: Both directions of the working + transport entity, including the affected direction and the + unaffected direction, are switched to the protection transport + entity. For bidirectional switching, the APS protocol is required + to coordinate the two endpoints so that both have the same bridge + and selector settings, even for a unidirectional failure. This + type is applicable for 1+1 and 1:1 protection. + +4.3. Protection Operation Type + + The linear protection operation types can be a non-revertive + operation type or a revertive operation type. + + o Non-revertive operation: The normal traffic will not be switched + back to the working transport entity even after a protection + switching cause has cleared. This is generally accomplished by + replacing the previous switch request with a "Do not Revert (DNR)" + request, which has a low priority. + + o Revertive operation: The normal traffic is restored to the working + transport entity after the condition(s) causing the protection + switching has cleared. In the case of clearing a command (e.g., + Forced Switch), this happens immediately. In the case of clearing + a defect, this generally happens after the expiry of a "Wait to + Restore (WTR)" timer, which is used to avoid chattering of + selectors in the case of intermittent defects. + + + + + +van Helvoort, et al. Informational [Page 7] + +RFC 7347 Pre-standard MPLS-TP Lin. Prot. Switching September 2014 + + +5. Protection-Switching Trigger Conditions + +5.1. Fault Conditions + + Fault conditions mean the requests generated by the local Operations, + Administration, and Maintenance (OAM) function. + + o Signal Fail (SF): If an endpoint detects a failure by an OAM + function or other mechanism, it will submit a local signal failure + (local SF) to the APS module to request a protection switch. The + local SF could be on the working transport entity (Signal Fail on + Working transport entity (SF-W)) or the protection transport + entity (Signal Fail on Protection transport entity (SF-P)). + + o Signal Degrade (SD): If an endpoint detects signal degradation by + an OAM function or other mechanism, it will submit a local signal + degrade (local SD) to the APS module to request a protection + switching. The local SD could be on the working transport entity + (Signal Degrade on Working transport entity (SD-W)) or the + protection transport entity (Signal Degrade on Protection + transport entity (SD-P)). + +5.2. External Commands + + The external command issues an appropriate external request to the + protection process. + +5.2.1. End-to-End Commands + + These commands are applied to both local and remote nodes. When the + APS protocol is present, these commands, except the Clear command, + are signaled to the far end of the connection. In bidirectional + switching, these commands affect the bridge and selector at both + ends. + + o Lockout of Protection (LO): This command is used to provide the + operator a tool for temporarily disabling access to the protection + transport entity. + + o Manual Switch (MS): This command is used to provide the operator a + tool for temporarily switching normal traffic to the working + transport entity (Manual Switch to Working transport entity (MS- + W)) or to the protection transport entity (Manual Switch to + Protection transport entity (MS-P)), unless a higher priority + switch request (i.e., LO, FS, or SF) is in effect. + + + + + + +van Helvoort, et al. Informational [Page 8] + +RFC 7347 Pre-standard MPLS-TP Lin. Prot. Switching September 2014 + + + o Forced Switch (FS): This command is used to provide the operator a + tool for temporarily switching normal traffic from the working + transport entity to the protection transport entity, unless a + higher priority switch request (i.e., LO or SF-P) is in effect. + + o Exercise (EXER): Exercise is a command to test if the APS + communication is operating correctly. The EXER command SHALL NOT + affect the state of the protection selector and bridge. + + o Clear: This command between management and the local protection + process is not a request sent by APS to other endpoints. It is + used to clear the active near-end external command or WTR state. + +5.2.2. Local Commands + + These commands apply only to the near end (local node) of the + protection group. Even when an APS protocol is supported, they are + not signaled to the far end. + + o Freeze: This command freezes the state of the protection group. + Until the freeze is cleared, additional near-end commands are + rejected, and condition changes and received APS information are + ignored. When the Freeze command is cleared, the state of the + protection group is recomputed based on the condition and received + APS information. + + Because the freeze is local, if the freeze is issued at one end + only, a failure of protocol can occur as the other end is open to + accept any operator command or fault condition. + + o Clear Freeze: This command clears the local freeze. + + + + + + + + + + + + + + + + + + + + +van Helvoort, et al. Informational [Page 9] + +RFC 7347 Pre-standard MPLS-TP Lin. Prot. Switching September 2014 + + +6. Protection-Switching Schemes + +6.1. 1+1 Unidirectional Protection Switching + + +-----------+ +-----------+ + | |---------------------------------------| | + | -+---------------------------------------+- | + | / |---------------------------------------| \ | + | / | Working transport entity | \ | + --+-------> | | --------+-> + | \ | | | + | \ |---------------------------------------| | + | -+---------------------------------------| | + | source |---------------------------------------| sink | + +-----------+ Protection transport entity +-----------+ + (normal condition) + + +-----------+ +-----------+ + | |---------------------------------------| | + | -+------------------XX-------------------+ | + | / |---------------------------------------| | + | / | Working transport entity (failure) | | + --|-------> | | --------+-> + | \ | | / | + | \ |---------------------------------------| / | + | -+---------------------------------------+- | + | source |---------------------------------------| sink | + +-----------+ Protection transport entity +-----------+ + (failure condition) + + Figure 1: 1+1 Unidirectional Linear Protection Switching + + 1+1 unidirectional protection switching is the simplest protection + switching mechanism. The normal traffic is permanently bridged on + both the working and protection transport entities at the source + endpoint of the protected domain. In the normal condition, the sink + endpoint receives traffic from the working transport entity. If the + sink endpoint detects a failure on the working transport entity, it + will switch to receive traffic from the protection transport entity. + 1+1 unidirectional protection switching is recommended to be used for + unidirectional transport. + + Note that 1+1 unidirectional protection switching does not use the + APS coordination protocol since it only performs protection switching + based on the local request. + + + + + + +van Helvoort, et al. Informational [Page 10] + +RFC 7347 Pre-standard MPLS-TP Lin. Prot. Switching September 2014 + + +6.2. 1+1 Bidirectional Protection Switching + + +-----------+ +-----------+ + | |---------------------------------------| | + | -+<--------------------------------------+- | + | / +-------------------------------------->+ \ | + | sink / /|---------------------------------------|\ \ sink | + <-+-------/ / | Working transport entity | --\-------+-> + --+--------> | | <------+-- + | source \ | | / source| + | \|---------------------------------------| / | + | +-------------------------------------->| / | + | |<--------------------------------------+- | + | APS <...................................................> APS | + | |---------------------------------------+ | + +-----------+ Protection transport entity +-----------+ + (normal condition) + + +-----------+ +-----------+ + | |---------------------------------------| | + | +<----------------XX--------------------+- | + | +-------------------------------------->+ \ | + | /|---------------------------------------| \ | + | source / | Working transport entity (failure) | \ source| + --+--------> | | \<-----+-- + <-+------- \ | | --/------+-> + | sink \ \|---------------------------------------| / / sink | + | \ +-------------------------------------->+- / | + | --+<--------------------------------------+-/ | + | APS <...................................................> APS | + | |---------------------------------------+ | + +-----------+ Protection transport entity +-----------+ + (failure condition) + + Figure 2: 1+1 Bidirectional Linear Protection Switching + + In 1+1 bidirectional protection switching, for each direction, the + normal traffic is permanently bridged on both the working and + protection transport entities at the source endpoint of the protected + domain. In the normal condition, for each direction, the sink + endpoint receives traffic from the working transport entity. + + If the sink endpoint detects a failure on the working transport + entity, it will switch to receive traffic from the protection + transport entity. It will also send an APS message to inform the + sink endpoint on the other direction to switch to receive traffic + from the protection transport entity. + + + + +van Helvoort, et al. Informational [Page 11] + +RFC 7347 Pre-standard MPLS-TP Lin. Prot. Switching September 2014 + + + The APS mechanism is necessary to coordinate the two endpoints of the + transport entity and to implement 1+1 bidirectional protection + switching even for a unidirectional failure. + +6.3. 1:1 Bidirectional Protection Switching + + +-----------+ +-----------+ + | |---------------------------------------| | + | -+<--------------------------------------+- | + | / +-------------------------------------->+ \ | + | sink / /|---------------------------------------|\ \ source| + <-+-------/ / | Working transport entity | \ <-------+-- + --+--------> | | ---------+-> + | source | | sink | + | |---------------------------------------| | + | | | | + | | | | + | APS <...................................................> APS | + | |---------------------------------------| | + +-----------+ Protection transport entity +-----------+ + (normal condition) + + +-----------+ +-----------+ + | |---------------------------------------| | + | | \/ | | + | | /\ | | + | |---------------------------------------| | + | source | Working transport entity (failure) | sink | + --+-------> | | --------+-> + <-+------- \ | | / <------+-- + | sink \ \ |---------------------------------------| / / source| + | \ -+-------------------------------------->+- / | + | --+<--------------------------------------+-- | + | APS <...................................................> APS | + | |---------------------------------------+ | + +-----------+ Protection transport entity +-----------+ + (failure condition) + + Figure 3: 1:1 Bidirectional Linear Protection Switching + + In 1:1 bidirectional protection switching, for each direction, the + source endpoint sends traffic on either the working transport entity + or the protection transport entity. The sink endpoint receives the + traffic from the same transport entity on which the source endpoint + sends the traffic. + + In the normal condition, for each direction, the source and sink + endpoints send and receive traffic from the working transport entity. + + + +van Helvoort, et al. Informational [Page 12] + +RFC 7347 Pre-standard MPLS-TP Lin. Prot. Switching September 2014 + + + If the sink endpoint detects a failure on the working transport + entity, it will switch to send and receive traffic from the + protection transport entity. It will also send an APS message to + inform the sink endpoint on another direction to switch to send and + receive traffic from the protection transport entity. + + The APS mechanism is necessary to coordinate the two endpoints of the + transport entity and implement 1:1 bidirectional protection switching + even for a unidirectional failure. + +7. APS Protocol + + This APS protocol is based upon the APS protocol defined in + Section 11 of [G.8031]. See that reference for further definition of + the Protocol Data Unit (PDU) fields and protocol details beyond the + description in this document. + +7.1. APS PDU Format + + APS packets MUST be sent over a Generic Associated Channel (G-ACh) as + defined in [RFC5586]. + + The format of APS PDU is specified in Figure 4 below. + + 0 1 2 3 + 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + |0 0 0 1|0 0 0 0|0 0 0 0 0 0 0 0| Channel Type (=0x7FFA) | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | MEL | Version | OpCode | Flags | TLV Offset | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | APS Specific Information | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | End TLV | + +-+-+-+-+-+-+-+-+ + + Figure 4: APS PDU Format + + The following values MUST be used for APS PDU: + + o Channel Type: The Channel Type MUST be configurable by the + implementation. During deployment, the local system administrator + provisioned the value 0x7FFA. This is a code point value in the + range of experimental Channel Types as described in RFC 5586, + Section 10. + + + + + + +van Helvoort, et al. Informational [Page 13] + +RFC 7347 Pre-standard MPLS-TP Lin. Prot. Switching September 2014 + + + o Maintenance Entity group Level (MEL): The MEL value to set and + check MUST be configurable. The DEFAULT value MUST be "111". + With co-routed bidirectional transport paths, the configured MEL + MUST be the same in both directions. + + o Version: 0x00 + + o OpCode: 0x27 (=0d39) + + o Flags: 0x00 + + o TLV Offset: 4 + + o End TLV: 0x00 + + The format of the APS-specific information is defined in Figure 5. + + 0 1 2 3 + 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + |Request|Pr.Type| Requested | Bridged | | | + | / |-+-+-+-| | |T| Reserved(0)| + | State |A|B|D|R| Signal | Signal | | | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + + Figure 5: APS-Specific Information Format + + All bits defined as "Reserved" MUST be transmitted as 0 and ignored + on reception. + + o Request/State: + + The four bits indicate the protection-switching request type. See + Figure 6 for the code of each request/state type. + + + + + + + + + + + + + + + + + +van Helvoort, et al. Informational [Page 14] + +RFC 7347 Pre-standard MPLS-TP Lin. Prot. Switching September 2014 + + + In case that there are multiple protection-switching requests, + only the protection-switching request with the highest priority + MUST be processed. + + +------------------------------------+---------------+ + | Request/State | Code/Priority | + +------------------------------------+---------------+ + |Lockout of Protection (LO) | 1111 (highest)| + +------------------------------------+---------------+ + |Signal Fail on Protection (SF-P) | 1110 | + +------------------------------------+---------------+ + |Forced Switch (FS) | 1101 | + +------------------------------------+---------------+ + |Signal Fail on Working (SF-W) | 1011 | + +------------------------------------+---------------+ + |Signal Degrade (SD) | 1001 | + +------------------------------------+---------------+ + |Manual Switch (MS) | 0111 | + +------------------------------------+---------------+ + |Wait to Restore (WTR) | 0101 | + +------------------------------------+---------------+ + |Exercise (EXER) | 0100 | + +------------------------------------+---------------+ + |Reverse Request (RR) | 0010 | + +------------------------------------+---------------+ + |Do Not Revert (DNR) | 0001 | + +------------------------------------+---------------+ + |No Request (NR) | 0000 (lowest) | + +------------------------------------+---------------+ + + Figure 6: Protection-Switching Request Code/Priority + + o Protection Type (Pr.Type): + + The four bits are used to specify the protection type. + + A: reserved (set by default to 1) + B: 0 - 1+1 (permanent bridge) + 1 - 1:1 (no permanent bridge) + D: 0 - Unidirectional switching + 1 - Bidirectional switching + R: 0 - Non-revertive operation + 1 - Revertive operation + + + + + + + + +van Helvoort, et al. Informational [Page 15] + +RFC 7347 Pre-standard MPLS-TP Lin. Prot. Switching September 2014 + + + o Requested Signal: + + This byte is used to indicate the traffic that the near-end + requests to be carried over the protection entity. + + value = 0: Null traffic + value = 1: Normal traffic 1 + value = 2~255: Reserved + + o Bridged Signal: + + This byte is used to indicate the traffic that is bridged onto the + protection entity. + + value = 0: Null traffic + value = 1: Normal traffic 1 + value = 2~255: Reserved + + o Bridge Type (T): + + This bit is used to further specify the type of non-permanent + bridge for 1:1 protection switching. + + value = 0: Selector bridge + value = 1: Broadcast bridge + + o Reserved: + + This field MUST be set to zero. + +7.2. APS Transmission + + The APS message MUST be transported on the protection transport + entity by encapsulation with the protection transport entity label + (the label of the LSP used to transport protection traffic). If an + endpoint receives APS-specific information from the working transport + entity, it MUST ignore this information and MUST report the failure + of protocol defect (see Section 8.1) to the operator. + + A new APS packet MUST be transmitted immediately when a change in the + transmitted status occurs. The first three APS packets MUST be + transmitted as fast as possible only if the APS information to be + transmitted has been changed so that fast protection switching is + possible, even if one or two APS packets are lost or corrupted. The + interval of the first three APS packets SHOULD be 3.3 ms. APS + packets after the first three MUST be transmitted with the interval + of 5 seconds. + + + + +van Helvoort, et al. Informational [Page 16] + +RFC 7347 Pre-standard MPLS-TP Lin. Prot. Switching September 2014 + + + If no valid APS-specific information is received, the last valid + received information remains applicable. + +7.3. Hold-Off Timer + + In order to coordinate timing of protection switches at multiple + layers, a hold-off timer MAY be required. The purpose is to allow a + server-layer protection switch to have a chance to fix the problem + before switching at a client layer. + + Each selector SHOULD have a provisioned hold-off timer. The + suggested range of the hold-off timer is 0 to 10 seconds in steps of + 100 ms (accuracy of +/-5 ms). + + When a new defect or more severe defect occurs (new SF or SD) on the + active transport entity (the transport entity that currently carries + and selects traffic), this event will not be reported immediately to + protection switching if the provisioned hold-off timer value is non- + zero. Instead, the hold-off timer SHALL be started. When the hold- + off timer expires, it SHALL be checked whether a defect still exists + on the transport entity that started the timer. If it does, that + defect SHALL be reported to protection switching. The defect need + not be the same one that started the timer. + + This hold-off timer mechanism SHALL be applied for both working and + protection transport entities. + +7.4. WTR Timer + + In revertive mode of operation, to prevent frequent operation of the + protection switch due to an intermittent defect, a failed working + transport entity MUST become fault free. After the failed working + transport entity meets this criterion, a fixed period of time SHALL + elapse before a normal traffic signal uses it again. This period, + called a WTR period, MAY be configured by the operator in 1 minute + steps between 5 and 12 minutes; the default value is 5 minutes. An + SF or SD condition will override the WTR. To activate the WTR timer + appropriately, even when both ends concurrently detect clearance of + SF-W and SD-W, when the local state transits from SF-W or SD-W to No + Request (NR) with the requested signal number 1, the previous local + state, SF-W or SD-W, MUST be memorized. If both the local state and + far-end state are NR with the requested signal number 1, the local + state transits to WTR only when the previous local state is SF-W or + SD-W. Otherwise, the local state transits to NR with the requested + signal number 0. + + + + + + +van Helvoort, et al. Informational [Page 17] + +RFC 7347 Pre-standard MPLS-TP Lin. Prot. Switching September 2014 + + + In revertive mode of operation, when the protection is no longer + requested, i.e., the failed working transport entity is no longer in + SF or SD condition (and assuming no other requesting transport + entities), a local WTR state will be activated. Since this state + becomes the highest in priority, it is indicated on the APS signal + and maintains the normal traffic signal from the previously failed + working transport entity on the protection transport entity. This + state SHALL normally time out and become an NR state. The WTR timer + deactivates earlier when any request of higher priority request + preempts this state. + +7.5. Command Acceptance and Retention + + The commands Clear, LO, FS, MS, and EXER are accepted or rejected in + the context of previous commands, the condition of the working and + protection entities in the protection group, and (in bidirectional + switching only) the APS information received. + + The Clear command MUST be only valid if a near-end LO, FS, MS, or + EXER command is in effect or if a WTR state is present at the near + end and rejected otherwise. This command will remove the near-end + command or WTR state, allowing the next lower-priority condition or + (in bidirectional switching) APS request to be asserted. + + Other commands MUST be rejected unless they are higher priority than + the previously existing command, condition, or (in bidirectional + switching) APS request. If a new command is accepted, any previous, + lower-priority command that is overridden MUST be forgotten. If a + higher priority command overrides a lower-priority condition or (in + bidirectional switching) APS request, that other request will be + reasserted if it still exists at the time the command is cleared. If + a command is overridden by a condition or (in bidirectional + switching) APS request, that command MUST be forgotten. + +7.6. Exercise Operation + + Exercise is a command to test if the APS communication is operating + correctly. It is lower priority than any "real" switch request. It + is only valid in bidirectional switching, since this is the only + place where you can get a meaningful test by looking for a response. + + The Exercise command SHALL issue the command with the same requested + and bridged signal numbers of the NR, Reverse Request (RR), or DNR + request that it replaces. The valid response will be an RR with the + corresponding requested and bridged signal numbers. When Exercise + commands are input at both ends, an EXER, instead of RR, MUST be + transmitted from both ends. The standard response to DNR MUST be DNR + rather than NR. When the exercise command is cleared, it MUST be + + + +van Helvoort, et al. Informational [Page 18] + +RFC 7347 Pre-standard MPLS-TP Lin. Prot. Switching September 2014 + + + replaced with NR or RR if the requested signal number is 0 and DNR or + RR if the requested signal number is 1. + +8. Protection-Switching Logic + +8.1. Principle of Operation + + +-------------+ Persistent +----------+ + SF,SD | Hold-off | fault | Local | + ----------->| timer logic |----------->| request | + +-------------+ | logic | + Other local requests ----------------->| | + (LO, FS, MS, EXER, Clear) +----------+ + | + | Highest + | local request + | + Remote APS V + message +-------+ Remote APS +----------------+ + ------------->| APS | request/state | APS process | + (received | check |-------------->| logic | + from far end) +-------+ +----------------+ + | ^ | | + | | | Signaled | + | | | APS | + | | Txed | | + | | "Requested V | + | | Signal" +-----------+ | + | +-----------------| APS mess. | | + | | generator | | + | +-----------+ | + | | | + V | | + Failure of V | + protocol APS message | + detection V + Set local + bridge/selector + + Figure 7: Protection-Switching Logic + + Figure 7 describes the protection-switching logic. + + One or more local protection-switching requests may be active. The + "local request logic" determines which of these requests is highest + using the order of priority given in Figure 6. This highest local + request information SHALL be passed on to the "APS process logic". + Note that an accepted Clear command, clearance of SF or SD, or + + + +van Helvoort, et al. Informational [Page 19] + +RFC 7347 Pre-standard MPLS-TP Lin. Prot. Switching September 2014 + + + expiration of the WTR timer SHALL NOT be processed by the local + request logic but SHALL be considered as the highest local request + and submitted to the APS process logic for processing. + + The remote APS message is received from the far end and is subjected + to the validity check and mismatch detection in "APS check". Failure + of protocol situations are as follows: + + o The "B" field mismatch due to incompatible provisioning; + + o The reception of the APS message from the working entity due to + working/protection configuration mismatch; + + o No match in sent "Requested Signal" and received "Requested + Signal" for more than 50 ms; + + o No APS message is received on the protection transport entity + during at least 3.5 times the long APS interval (e.g., at least + 17.5 seconds), and there is no defect on the protection transport + entity. + + Provided the "B" field matches: + + o If the "D" bit mismatches, the bidirectional side will fall back + to unidirectional switching. + + o If the "R" bit mismatches, one side will clear switches to WTR and + the other will clear to DNR. The two sides will interwork and the + traffic is protected. + + o If the "T" bit mismatches, the side using a broadcast bridge will + fall back to using a selector bridge. + + The APS message with invalid information MUST be ignored, and the + last valid received information remains applicable. + + The linear protection-switching algorithm SHALL commence immediately + every time one of the input signals changes, i.e., when the status of + any local request changes, or when different APS-specific information + is received from the far end. The consequent actions of the + algorithm are also initiated immediately, i.e., change the local + bridge/selector position (if necessary), transmit new APS-specific + information (if necessary), or detect the failure of protocol defect + if the protection switching is not completed within 50 ms. + + + + + + + +van Helvoort, et al. Informational [Page 20] + +RFC 7347 Pre-standard MPLS-TP Lin. Prot. Switching September 2014 + + + The state transition is calculated in the "APS process logic" based + on the highest local request, the request of the last received + "Request/State" information, and state transition tables defined in + Section 9, as follows: + + o If the highest local request is Clear, clearance of SF or SD, or + expiration of WTR, a state transition is calculated first based on + the highest local request and state machine table for local + requests to obtain an intermediate state. This intermediate state + is the final state in case of clearance of SF-P; otherwise, + starting at this intermediate state, the last received far-end + request and the state machine table for far-end requests are used + to calculate the final state. + + o If the highest local request is neither Clear nor clearance of SF + or of SD nor expiration of WTR, the APS process logic compares the + highest local request with the request of the last received + "Request/State" information based on Figure 6. + + 1. If the highest local request has higher or equal priority, it + is used with the state transition table for local requests + defined in Section 9 to determine the final state; otherwise, + + 2. The request of the last received "Request/State" information + is used with the state transition table for far-end requests + defined in Section 9 to determine the final state. + + The "APS message generator" generates APS-specific information with + the signaled APS information for the final state from the state + transition calculation (with coding as described in Figure 5). + +8.2. Equal Priority Requests + + In general, once a switch has been completed due to a request, it + will not be overridden by another request of the same priority + (first-come, first-served policy). Equal priority requests from both + sides of a bidirectional protection group are both considered valid, + as follows: + + o If the local state is NR, with the requested signal number 1, and + the far-end state is NR, with the requested signal number 0, the + local state transits to NR with the requested signal number 0. + This applies to the case when the remote request for switching to + the protection transport entity has been cleared. + + + + + + + +van Helvoort, et al. Informational [Page 21] + +RFC 7347 Pre-standard MPLS-TP Lin. Prot. Switching September 2014 + + + o If both the local and far-end states are NR, with the requested + signal number 1, the local state transits to the appropriate new + state (DNR state for non-revertive mode and WTR state for + revertive mode). This applies to the case when the old request + has been cleared at both ends. + + o If both the local and far-end states are RR, with the same + requested signal number, both ends transit to the appropriate new + state according to the requested signal number. This applies to + the case of concurrent deactivation of EXER from both ends. + + o In other cases, no state transition occurs, even if equal priority + requests are activated from both ends. Note that if MSs are + issued simultaneously to both working and protection transport + entities, either as local or far-end requests, the MS to the + working transport entity is considered as having higher priority + than the MS to the protection transport entity. + +8.3. Signal Degrade of the Protection Transport Entity + + Signal degrade on the protection transport entity has the same + priority as signal degrade on the working transport entity. As a + result, if an SD condition affects both transport entities, the first + SD detected MUST NOT be overridden by the second SD detected. If the + SD is detected simultaneously, either as local or far-end requests on + both working and protection transport entities, then the SD on the + standby transport entity MUST be considered as having higher priority + than the SD on the active transport entity, and the normal traffic + signal continues to be selected from the active transport entity + (i.e., no unnecessary protection switching is performed). + + In the preceding sentence, "simultaneously" relates to the occurrence + of SD on both the active and standby transport entities at input to + the protection-switching process at the same time, or as long as an + SD request has not been acknowledged by the remote end in + bidirectional protection switching. + +9. Protection-Switching State Transition Tables + + In this section, state transition tables for the following protection + switching configurations are described. + + o 1:1 bidirectional (revertive mode, non-revertive mode); + + o 1+1 bidirectional (revertive mode, non-revertive mode); + + o 1+1 unidirectional (revertive mode, non-revertive mode). + + + + +van Helvoort, et al. Informational [Page 22] + +RFC 7347 Pre-standard MPLS-TP Lin. Prot. Switching September 2014 + + + Note that any other global or local request that is not described in + state transition tables does not trigger any state transition. + + The states specified in the state transition tables can be described + as follows: + + o NR: NR is the state entered by the local priority under all + conditions where no local protection-switching requests (including + WTR and DNR) are active. NR can also indicate that the highest + local request is overridden by the far-end request, whose priority + is higher than the highest local request. Normal traffic signal + is selected from the corresponding transport entity. + + o LO, SF-P, SD-P: The access by the normal traffic to the protection + transport entity is NOT allowed in this state. The normal traffic + is carried by the working transport entity, regardless of the + fault/degrade condition possibly present (due to the highest + priority of the switching triggers leading to this state). + + o FS, SF-W, SD-W, MS-W, MS-P: A switching trigger NOT resulting in + the protection transport entity unavailability is present. The + normal traffic is selected either from the corresponding working + transport entity or from the protection transport entity, + according to the behavior of the specific switching trigger. + + o WTR: In revertive operation, after the clearing of an SF-W or SD- + W, this maintains normal traffic as selected from the protection + transport entity until the WTR timer expires or another request + with higher priority, including the Clear command, is received. + This is used to prevent frequent operation of the selector in the + case of intermittent failures. + + o DNR: In non-revertive operation, this is used to maintain a normal + traffic to be selected from the protection transport entity. + + o EXER: Exercise of the APS protocol. + + o RR: The near end will enter and signal Reverse Request only in + response to an EXER from the far end. + + [State transition tables are shown at the end of the PDF form of this + document.] + + + + + + + + + +van Helvoort, et al. Informational [Page 23] + +RFC 7347 Pre-standard MPLS-TP Lin. Prot. Switching September 2014 + + +10. Security Considerations + + MPLS-TP is a subset of MPLS and so builds upon many of the aspects of + the security model of MPLS. MPLS networks make the assumption that + it is very hard to inject traffic into a network and equally hard to + cause traffic to be directed outside the network. The control-plane + protocols utilize hop-by-hop security and assume a "chain-of-trust" + model such that end-to-end control-plane security is not used. For + more information on the generic aspects of MPLS security, see + [RFC5920]. + + This document describes a protocol carried in the G-ACh [RFC5586] and + so is dependent on the security of the G-ACh, itself. The G-ACh is a + generalization of the associated channel defined in [RFC4385]. Thus, + this document relies heavily on the security mechanisms provided for + the associated channel and described in those two documents. + +11. Acknowledgements + + The authors would like to thank Hao Long, Vincenzo Sestito, Italo + Busi, Igor Umansky, and Andy Malis for their input to and review of + the current 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. + + [RFC4385] Bryant, S., Swallow, G., Martini, L., and D. McPherson, + "Pseudowire Emulation Edge-to-Edge (PWE3) Control Word for + Use over an MPLS PSN", RFC 4385, February 2006. + + [RFC5586] Bocci, M., Vigoureux, M., and S. Bryant, "MPLS Generic + Associated Channel", RFC 5586, June 2009. + + [RFC5920] Fang, L., "Security Framework for MPLS and GMPLS + Networks", RFC 5920, July 2010. + + [G.841] International Telecommunications Union, "Types and + characteristics of SDH network protection architectures", + ITU-T Recommendation G.841, October 1998. + + [G.873.1] International Telecommunications Union, "Optical Transport + Network (OTN): Linear protection", ITU-T Recommendation + G.873.1, May 2014. + + + + +van Helvoort, et al. Informational [Page 24] + +RFC 7347 Pre-standard MPLS-TP Lin. Prot. Switching September 2014 + + + [G.8031] International Telecommunications Union, "Ethernet linear + protection switching", ITU-T Recommendation G.8031/Y.1342, + June 2011. + + [T1.105.01] + American National Standards Institute, "Synchronous + Optical Network (SONET) - Automatic Protection Switching", + ANSI 0900105.01:2000 (R2010), March 2000. + +12.2. Informative References + + [RFC6378] Weingarten, Y., Bryant, S., Osborne, E., Sprecher, N., and + A. Fulignoli, "MPLS Transport Profile (MPLS-TP) Linear + Protection", RFC 6378, October 2011. + + [RFC7271] Ryoo, J., Gray, E., van Helvoort, H., D'Alessandro, A., + Cheung, T., and E. Osborne, "MPLS Transport Profile (MPLS- + TP) Linear Protection to Match the Operational + Expectations of Synchronous Digital Hierarchy, Optical + Transport Network, and Ethernet Transport Network + Operators", RFC 7271, June 2014. + + [RFC7324] Osborne, E., "Updates to MPLS Transport Profile Linear + Protection", RFC 7324, July 2014. + + + + + + + + + + + + + + + + + + + + + + + + + + + +van Helvoort, et al. Informational [Page 25] + +RFC 7347 Pre-standard MPLS-TP Lin. Prot. Switching September 2014 + + +Appendix A. Operation Examples of the APS Protocol + + The sequence diagrams shown in this section are only a few examples + of the APS operations. The first APS message, which differs from the + previous APS message, is shown. The operation of hold-off timer is + omitted. The fields whose values are changed during APS packet + exchange are shown in the APS packet exchange. They are Request/ + State, requested traffic, and bridged traffic. For an example, + SF(0,1) represents an APS packet with the following field values: + Request/State = SF, Requested Signal = 0, and Bridged Signal = 1. + The values of the other fields remain unchanged from the initial + configuration. The signal numbers 0 and 1 refer to null signal and + normal traffic signal, respectively. W(A->Z) and P(A->Z) indicate + the working and protection paths in the direction of A to Z, + respectively. + + Example 1. 1:1 bidirectional protection switching (revertive mode) - + Unidirectional SF case + + A Z + | | + (1) |---- NR(0,0)----->| + |<----- NR(0,0)----| + | | + | | + (2) | (SF on W(Z->A)) | + |---- SF(1,1)----->| (3) + |<----- NR(1,1)----| + (4) | | + | | + (5) | (Recovery) | + |---- WTR(1,1)---->| + /| | + WTR timer | | + \| | + (6) |---- NR(0,0)----->| (7) + (8) |<----- NR(0,0)----| + | | + + (1) The protected domain is operating without any defect, and the + working entity is used for delivering the normal traffic. + + (2) Signal Fail occurs on the working entity in the Z to A + direction. Selector and bridge of node A select protection + entity. Node A generates an SF(1,1) message. + + + + + + +van Helvoort, et al. Informational [Page 26] + +RFC 7347 Pre-standard MPLS-TP Lin. Prot. Switching September 2014 + + + (3) Upon receiving SF(1,1), node Z sets selector and bridge to + protection entity. As there is no local request in node Z, node + Z generates an NR(1,1) message. + + (4) Node A confirms that the far end is also selecting protection + entity. + + (5) Node A detects clearing of the SF condition, starts the WTR + timer, and sends a WTR(1,1) message. + + (6) At expiration of the WTR timer, node A sets selector and bridge + to working entity and sends an NR(0,0) message. + + (7) Node Z is notified that the far-end request has been cleared and + sets selector and bridge to working entity. + + (8) It is confirmed that the far end is also selecting working + entity. + + Example 2. 1:1 bidirectional protection switching (revertive mode) - + Bidirectional SF case + + A Z + | | + (1) |---- NR(0,0)----->| (1) + |<----- NR(0,0)----| + | | + | | + (2) | (SF on W(Z<->A)) | (2) + |<---- SF(1,1)---->| + (3) | | (3) + | | + (4) | (Recovery) | (4) + |<---- NR(1,1)---->| + (5) |<--- WTR(1,1)---->| (5) + /| |\ + WTR timer | | WTR timer + \| |/ + (6) |<---- NR(1,1)---->| (6) + (7) |<----- NR(0,0)--->| (7) + (8) | | (8) + + (1) The protected domain is operating without any defect, and the + working entity is used for delivering the normal traffic. + + (2) Nodes A and Z detect local SF conditions on the working entity, + set selector and bridge to protection entity, and generate + SF(1,1) messages. + + + +van Helvoort, et al. Informational [Page 27] + +RFC 7347 Pre-standard MPLS-TP Lin. Prot. Switching September 2014 + + + (3) Upon receiving SF(1,1), each node confirms that the far end is + also selecting protection entity. + + (4) Each node detects clearing of the SF condition and sends an + NR(1,1) message as the last received APS message was SF. + + (5) Upon receiving NR(1,1), each node starts the WTR timer and sends + WTR(1,1). + + (6) At expiration of the WTR timer, each node sends NR(1,1) as the + last received APS message was WTR. + + (7) Upon receiving NR(1,1), each node sets selector and bridge to + working entity and sends an NR(0,0) message. + + (8) It is confirmed that the far end is also selecting working + entity. + + Example 3. 1:1 bidirectional protection switching (revertive mode) - + Bidirectional SF case - Inconsistent WTR timers + + A Z + | | + (1) |---- NR(0,0)----->| (1) + |<----- NR(0,0)----| + | | + | | + (2) | (SF on W(Z<->A)) | (2) + |<---- SF(1,1)---->| + (3) | | (3) + | | + (4) | (Recovery) | (4) + |<---- NR(1,1)---->| + (5) |<--- WTR(1,1)---->| (5) + /| |\ + WTR timer | | | + \| | WTR timer + (6) |----- NR(1,1)---->| | (7) + | |/ + (9) |<----- NR(0,0)----| (8) + |---- NR(0,0)----->| (10) + + (1) The protected domain is operating without any defect, and the + working entity is used for delivering the normal traffic. + + (2) Nodes A and Z detect local SF conditions on the working entity, + set selector and bridge to protection entity, and generate + SF(1,1) messages. + + + +van Helvoort, et al. Informational [Page 28] + +RFC 7347 Pre-standard MPLS-TP Lin. Prot. Switching September 2014 + + + (3) Upon receiving SF(1,1), each node confirms that the far end is + also selecting protection entity. + + (4) Each node detects clearing of the SF condition and sends an + NR(1,1) message as the last received APS message was SF. + + (5) Upon receiving NR(1,1), each node starts the WTR timer and + sends WTR(1,1). + + (6) At expiration of the WTR timer in node A, node A sends an + NR(1,1) message as the last received APS message was WTR. + + (7) At node Z, the received NR(1,1) is ignored as the local WTR has + a higher priority. + + (8) At expiration of the WTR timer in node Z, node Z sets selector + and bridge to working entity and sends an NR(0,0) message. + + (9) Upon receiving NR(0,0), node A sets selector and bridge to + working entity and sends an NR(0,0) message. + + (10) It is confirmed that the far end is also selecting working + entity. + + Example 4. 1:1 bidirectional protection switching (non-revertive + mode) - Unidirectional SF on working followed by unidirectional SF on + protection + + + + + + + + + + + + + + + + + + + + + + + + +van Helvoort, et al. Informational [Page 29] + +RFC 7347 Pre-standard MPLS-TP Lin. Prot. Switching September 2014 + + + A Z + | | + (1) |---- NR(0,0)----->| (1) + |<----- NR(0,0)----| + | | + | | + (2) | (SF on W(Z->A)) | + |----- SF(1,1)---->| (3) + (4) |<----- NR(1,1)----| + | | + | | + (5) | (Recovery) | + |----- DNR(1,1)--->| (6) + |<--- DNR(1,1)---->| + | | + | | + | (SF on P(A->Z)) | (7) + (8) |<--- SF-P(0,0)----| + |---- NR(0,0)----->| + | | + | | + | (Recovery) | (9) + |<----- NR(0,0)----| + | | + + (1) The protected domain is operating without any defect, and the + working entity is used for delivering the normal traffic. + + (2) Signal Fail occurs on the working entity in the Z to A + direction. Selector and bridge of node A select the protection + entity. Node A generates an SF(1,1) message. + + (3) Upon receiving SF(1,1), node Z sets selector and bridge to + protection entity. As there is no local request in node Z, node + Z generates an NR(1,1) message. + + (4) Node A confirms that the far end is also selecting protection + entity. + + (5) Node A detects clearing of the SF condition and sends a DNR(1,1) + message. + + (6) Upon receiving DNR(1,1), node Z also generates a DNR(1,1) + message. + + (7) Signal Fail occurs on the protection entity in the A to Z + direction. Selector and bridge of node Z select the working + entity. Node Z generates an SF-P(0,0) message. + + + +van Helvoort, et al. Informational [Page 30] + +RFC 7347 Pre-standard MPLS-TP Lin. Prot. Switching September 2014 + + + (8) Upon receiving SF-P(0,0), node A sets selector and bridge to + working entity and generates an NR(0,0) message. + + (9) Node Z detects clearing of the SF condition and sends an NR(0,0) + message. + + Exmaple 5. 1:1 bidirectional protection switching (non-revertive + mode) - Bidirectional SF on working followed by bidirectional SF on + protection + + A Z + | | + (1) |---- NR(0,0)----->| (1) + |<----- NR(0,0)----| + | | + | | + (2) | (SF on W(A<->Z)) | (2) + (3) |<---- SF(1,1)---->| (3) + | | + | | + (4) | (Recovery) | (4) + (5) |<---- NR(1,1)---->| (5) + |<--- DNR(1,1)---->| + | | + | | + (6) | (SF on P(A<->Z)) | (6) + (7) |<--- SF-P(0,0)--->| (7) + | | + | | + (8) | (Recovery) | (8) + |<---- NR(0,0)---->| + | | + + (1) The protected domain is operating without any defect, and the + working entity is used for delivering the normal traffic. + + (2) Nodes A and Z detect local SF conditions on the working entity, + set selector and bridge to protection entity, and generate + SF(1,1) messages. + + (3) Upon receiving SF(1,1), each node confirms that the far end is + also selecting protection entity. + + (4) Each node detects clearing of the SF condition and sends an + NR(1,1) message as the last received APS message was SF. + + (5) Upon receiving NR(1,1), each node sends DNR(1,1). + + + + +van Helvoort, et al. Informational [Page 31] + +RFC 7347 Pre-standard MPLS-TP Lin. Prot. Switching September 2014 + + + (6) Signal Fail occurs on the protection entity in both directions. + Selector and bridge of each node selects the working entity. + Each node generates an SF-P(0,0) message. + + (7) Upon receiving SF-P(0,0), each node confirms that the far end is + also selecting working entity. + + (8) Each node detects clearing of the SF condition and sends an + NR(0,0) message. + +Authors' Addresses + + Huub van Helvoort (editor) + Huawei Technologies + + EMail: huub@van-helvoort.eu + + + Jeong-dong Ryoo (editor) + ETRI + + EMail: ryoo@etri.re.kr + + + Haiyan Zhang + Huawei Technologies + + EMail: zhanghaiyan@huawei.com + + + Feng Huang + Philips + + EMail: feng.huang@philips.com + + + Han Li + China Mobile + + EMail: lihan@chinamobile.com + + + Alessandro D'Alessandro + Telecom Italia + + EMail: alessandro.dalessandro@telecomitalia.it + + + + + +van Helvoort, et al. Informational [Page 32] + -- cgit v1.2.3