MPLS Working Group J. Ryoo, Ed.
Internet-Draft ETRI
Updates: 6378 (if approved) E. Gray, Ed.
Intended status: Standards Track Ericsson
Expires: August 12, 2014 H. van Helvoort
Huawei Technologies
A. D'Alessandro
Telecom Italia
T. Cheung
ETRI
E. Osborne
Cisco Systems, Inc.
February 8, 2014
MPLS Transport Profile (MPLS-TP) Linear Protection to Match the
Operational Expectations of SDH, OTN and Ethernet Transport Network
Operators
draft-ietf-mpls-tp-psc-itu-02.txt
Abstract
This document describes alternate mechanisms to perform some of the
sub-functions of MPLS Transport Profile (MPLS-TP) linear protection
defined in RFC 6378, and also defines additional mechanisms. The
purpose of these alternate and additional mechanisms is to provide
operator control and experience that more closely models the behavior
of linear protection seen in other transport networks.
This document also introduces capabilities and modes for linear
protection. A capability is an individual behavior, and a mode is a
particular combination of capabilities. Two modes are defined in
this document: Protection State Coordination (PSC) mode and Automatic
Protection Switching (APS) mode.
This document describes the behavior of the PSC protocol including
priority logic and state machine when all the capabilities associated
with the APS mode are enabled.
This document updates RFC 6378 in that the capability advertisement
method defined here is an addition to that document.
Status of This Memo
This Internet-Draft is submitted in full conformance with the
provisions of BCP 78 and BCP 79.
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Internet-Drafts are working documents of the Internet Engineering
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This Internet-Draft will expire on August 12, 2014.
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
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Table of Contents
1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . 3
2. Conventions Used in This Document . . . . . . . . . . . . . . 5
3. Acronyms . . . . . . . . . . . . . . . . . . . . . . . . . . 5
4. Capability 1: Priority Modification . . . . . . . . . . . . . 6
4.1. Motivations for swapping priorities of FS and SF-P . . . 6
4.2. Motivation for raising the priority of SFc . . . . . . . 7
4.3. Motivation for introducing Freeze command . . . . . . . . 7
4.4. Procedures in support of Capability 1 . . . . . . . . . . 7
5. Capability 2: Non-revertive Behavior Modification . . . . . . 8
6. Capability 3: Support of MS-W Command . . . . . . . . . . . . 8
6.1. Motivation for adding MS-W . . . . . . . . . . . . . . . 8
6.2. Terminology to support MS-W . . . . . . . . . . . . . . . 9
6.3. Behavior of MS-P and MS-W . . . . . . . . . . . . . . . . 9
6.4. Equal priority resolution for MS . . . . . . . . . . . . 9
7. Capability 4: Support of Protection against SD . . . . . . . 10
7.1. Motivation for supporting protection against SD . . . . . 10
7.2. Terminology to support SD . . . . . . . . . . . . . . . . 10
7.3. Behavior of protection against SD . . . . . . . . . . . . 11
7.4. Equal priority resolution . . . . . . . . . . . . . . . . 12
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8. Capability 5: Support of EXER Command . . . . . . . . . . . . 13
9. Capabilities and Modes . . . . . . . . . . . . . . . . . . . 14
9.1. Capabilities . . . . . . . . . . . . . . . . . . . . . . 14
9.1.1. Sending and receiving the Capabilities TLV . . . . . 15
9.2. Modes . . . . . . . . . . . . . . . . . . . . . . . . . . 15
9.2.1. PSC mode . . . . . . . . . . . . . . . . . . . . . . 16
9.2.2. APS mode . . . . . . . . . . . . . . . . . . . . . . 16
10. PSC Protocol in APS Mode . . . . . . . . . . . . . . . . . . 16
10.1. Request field in PSC protocol message . . . . . . . . . 16
10.2. Priorities of local inputs and remote requests . . . . . 16
10.3. Acceptance and retention of local inputs . . . . . . . . 19
11. State Transition Tables in APS Mode . . . . . . . . . . . . . 19
11.1. State transition by local inputs . . . . . . . . . . . . 22
11.2. State transition by remote messages . . . . . . . . . . 24
11.3. State transition for 1+1 unidirectional
protection . . . . . . . . . . . . . . . . . . . . . . . 26
12. Provisioning Mismatch and Protocol Failure in the APS Mode . 27
13. Security Considerations . . . . . . . . . . . . . . . . . . . 28
14. IANA Considerations . . . . . . . . . . . . . . . . . . . . . 28
14.1. MPLS PSC Request Registry . . . . . . . . . . . . . . . 28
14.2. MPLS PSC TLV Registry . . . . . . . . . . . . . . . . . 28
14.3. MPLS PSC Capability Flag Registry . . . . . . . . . . . 28
15. Acknowledgements . . . . . . . . . . . . . . . . . . . . . . 29
16. References . . . . . . . . . . . . . . . . . . . . . . . . . 29
16.1. Normative References . . . . . . . . . . . . . . . . . . 29
16.2. Informative References . . . . . . . . . . . . . . . . . 29
Appendix A. An Example of Out-of-service Ccenarios . . . . . . . 30
Appendix B. An Example of Sequence Diagram Showing
the Problem with the Priority Level of SFc . . . . . 31
Appendix C. Freeze Command . . . . . . . . . . . . . . . . . . . 33
Appendix D. Operation Examples of the APS Mode . . . . . . . . . 33
Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . . 37
1. Introduction
Linear protection mechanisms for the MPLS Transport Profile (MPLS-TP)
are described in RFC 6378 [RFC6378] to meet the requirements
described in RFC 5654 [RFC5654].
This document describes alternate mechanisms to perform some of the
sub-functions of linear protection, and also defines additional
mechanisms. The purpose of these alternate and additional mechanisms
is to provide operator control and experience that more closely
models the behavior of linear protection seen in other transport
networks, such as Synchronous Digital Hierarchy (SDH), Optical
Transport Network (OTN) and Ethernet transport networks. Linear
protection for SDH, OTN, and Ethernet transport networks are defined
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in ITU-T Recommendations G.841 [G841], G.873.1 [G873.1] and G.8031
[G8031], respectively.
The reader of this document is assumed to be familiar with RFC 6378.
The alternative mechanisms described in this document are for the
following capabilities:
1. Priority modification,
2. non-revertive behavior modification,
and the following capabilities have been added to define additional
mechanisms:
3. support of Manual Switch to Working path (MS-W) command,
4. support of protection against Signal Degrade (SD), and
5. support of Exercise (EXER) command.
Priority modification includes priority swapping between Signal Fail
on Protection path (SF-P) and Forced Switch (FS), and raising the
priority level of Clear Signal Fail (SFc).
Non-revertive behavior is modified to align with the behavior defined
in RFC 4427 [RFC4427] as well as to follow the behavior of linear
protection seen in other transport networks.
Support of MS-W command to revert traffic to the working path in non-
revertive operation is covered in this document.
Support of protection switching protocol against SD is covered in
this document. The specifics for the method of identifying SD is out
of the scope of this document similarly to Signal Fail (SF) for RFC
6378.
Support of EXER command to test if the Protection State Coordination
(PSC) communication is operating correctly is also covered in this
document. More specifically, EXER command tests and validates the
linear protection mechanism and PSC protocol including the aliveness
of the priority logic, the PSC state machine and the PSC message
generation and reception, and the integrity of the protection path,
without triggering the actual traffic switching.
This document introduces capabilities and modes. A capability is an
individual behavior. The capabilities of a node are advertised using
the method given in this document. A mode is a particular
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combination of capabilities. Two modes are defined in this document:
PSC mode and Automatic Protection Switching (APS) mode.
This document describes the behavior of the PSC protocol including
the priority logic and the state machine when all the capabilities
associated with the APS mode are enabled. The PSC protocol behavior
for the PSC mode is as defined in RFC 6378.
This document updates RFC 6378 by adding a capability advertisement
mechanism. It is recommended that existing implementations of RFC
6378 should be updated to support this capability. The backward
compatibility with existing implementations is described in
Section 9.2.1.
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 RFC 2119 [RFC2119].
3. Acronyms
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This document uses the following acronyms:
APS Automatic Protection Switching
DNR Do-not-Revert
EXER Exercise
FS Forced Switch
LER Label Edge Router
LO Lockout of protection
MS Manual Switch
MS-P Manual Switch to Protection path
MS-W Manual Switch to Working path
MPLS-TP MPLS Transport Profile
NR No Request
OC Operator Clear
OTN Optical Transport Network
PSC Protection State Coordination
RR Reverse Request
SD Signal Degrade
SDH Synchronous Digital Hierarchy
SD-P Signal Degrade on Protection path
SD-W Signal Degrade on Working path
SF Signal Fail
SFc Clear Signal Fail
SFDc Clear Signal Fail or Degrade
SF-P Signal Fail on Protection path
SF-W Signal Fail on Working path
WTR Wait-to-Restore
4. Capability 1: Priority Modification
RFC 6378 [RFC6378] defines the priority of FS to be higher than that
of SF-P. That document also defines the priority of Clear SF (SFc)
to be low. This document defines the priority modification
capability whereby the priorities of FS and SF-P are swapped and the
priority of Clear SF (SFc) is raised. In addition, this capability
introduces the use of Freeze command as described in Appendix C. The
reasons for these changes are explained in the following sub-sections
from technical and network operational aspects.
4.1. Motivations for swapping priorities of FS and SF-P
Defining the priority of FS higher than that of SF-P can result in a
situation where the protected traffic is taken out-of-service. When
the protection path fails PSC communication may stop as a result. In
this case, if any input that is supposed to be signaled to the other
end has a higher priority than SF-P then this can result in
unpredictable protection switching state. An example of the out-of-
service scenarios is shown in Appendix A.
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According to Section 2.4 of RFC 5654 [RFC5654] it MUST be possible to
operate an MPLS-TP network without using a control plane. This means
that the PSC communication channel is very important for the transfer
of external switch commands (e.g., FS), and these commands should not
rely on the presence of a control plane. In consequence, the failure
of the PSC communication channel has higher priority than FS.
In other transport networks (such as SDH, OTN, and Ethernet transport
networks) the priority of SF-P has been higher than that of FS. It
is therefore important to offer network operators the option of
having the same behavior in their MPLS-TP network so that they can
have the same operational protection switching behavior to which they
have become accustomed. Typically, FS command is issued before
network maintenance jobs, (e.g., replacing optical cables or other
network components). When an operator pulls out a cable on the
protection path by mistake, the traffic should be protected and the
operator expects this behavior based on his/her experience on the
traditional transport network operations.
4.2. Motivation for raising the priority of SFc
The priority level of SFc defined in RFC 6378 can cause traffic
disruption when a node that has experienced local signal fails on
both the working and the protection paths is recovering from these
failures.
An example of sequence diagram showing the problem with the priority
level of SFc as defined in RFC 6378 is shown in Appendix B.
4.3. Motivation for introducing Freeze command
With the priority swapping between FS and SF-P, the traffic is always
moved back to the working path when SF-P occurs in Protecting
administrative state. In the case that network operators need an
option to control their networks so that the traffic can remain on
the protection path even when the PSC communication channel is
broken, the Freeze command, which is a local command (i.e., not
signaled to the other end) can be used. The use of the Freeze
command is described in Appendix C.
4.4. Procedures in support of Capability 1
When this capability is in use the list of local requests in order of
priority SHALL be as follows:
(from higher to lower)
o Clear Signal Fail
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o Signal Fail on Protection path
o Forced Switch
o Signal Fail on Working path
This requires different PSC Control logic (including the state
machine) compared to that described in RFC 6378. Section 10 and
Section 11 show the PSC Control logic when all of the capabilities in
APS mode are enabled.
5. Capability 2: Non-revertive Behavior Modification
Non-revertive mode of protection switching is defined in RFC 4427
[RFC4427]. In this mode, the traffic does not return to the working
path when switch-over requests are terminated.
However, the PSC protocol defined in RFC 6378 [RFC6378] supports this
operation only when recovering from a defect condition: it does not
support the non-revertive function when an operator's switch-over
command, such as FS or Manual Switch (MS), is cleared. To be aligned
with the behavior in other transport networks and to be consistent
with RFC 4427, a node should go into the Do-not-Revert (DNR) state
not only when a failure condition on the working path is cleared, but
also when an operator command that requested switch-over is cleared.
This requires different PSC Control logic (including the state
machine) compared to that described in RFC 6378. Section 10 and
Section 11 show the PSC Control logic when all of the capabilities in
APS mode are enabled.
6. Capability 3: Support of MS-W Command
6.1. Motivation for adding MS-W
Changing the non-revertive operation as described in Section 5
introduces necessity of a new operator command to revert traffic to
the working path when in the DNR state. When the traffic is on the
protection path in the DNR state, a Manual Switch to Working (MS-W)
command is issued to switch the normal traffic back to working path.
According to Section 4.3.3.6 (Do-not-Revert State) in RFC 6378
[RFC6378], "to revert back to Normal state, the administrator SHALL
issue a Lockout of protection (LO) command followed by a Clear
command." However, using LO command introduces the potential risk of
an unprotected situation while the LO is in effect.
Manual Switch-over for recovery LSP/span command is defined in RFC
4427 [RFC4427]. Requirement 83 in RFC 5654 [RFC5654] states that the
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external commands defined in RFC 4427 must be supported. No such
command is supported in PSC as defined in RFC 6378 so there is a need
to provide support for that feature. Note that the "Manual Switch-
over for recovery LSP/span" command is the same as the MS-W command.
6.2. Terminology to support MS-W
RFC 6378 uses the term "Manual Switch" and its acronym "MS". This
document uses the term "Manual Switch to Protection path" and "MS-P"
to have the same meaning, but avoid confusion with "Manual Switch to
Working path" and its acronym "MS-W".
Similarly, RFC 6378 uses the term "Protecting administrative state",
and this document uses "Switching administrative state" to cover the
same concept but also include the case where traffic is switched back
to the working path by administrative MS-W command.
6.3. Behavior of MS-P and MS-W
If one of the MS-P and MS-W commands is received and processed after
the other, the two commands SHALL have the same priority such that if
one of the commands is already issued and accepted, the command that
is issued afterwards SHALL be ignored. However, if two Label Edge
Routers (LERs) request opposite operations simultaneously (i.e., one
LER sends MS-P and the other sends MS-W), the MS-W SHALL be
considered to have a higher priority than MS-P, and MS-P SHALL NOT be
accepted and SHALL be cancelled.
Two commands, MS-P and MS-W are represented by the same Request field
value, but differentiated by the FPath value. When traffic is
switched to the protection path, the FPath field SHALL indicate that
the working path is being blocked (i.e., FPath set to 1), and the
Path field SHALL indicate that user data traffic is being transported
on the protection path (i.e., Path set to 1). When traffic is
switched to the working path, the FPath field SHALL indicate that the
protection path is being blocked (i.e., FPath set to 0), and the Path
field SHALL indicate that user data traffic is being transported on
the working path (i.e., Path set to 0).
When an MS command is in effect at an LER, any subsequent MS or EXER
command and any other lower priority requests SHALL be ignored.
6.4. Equal priority resolution for MS
RFC 6378 defines only one rule for equal priority condition in
Section 4.3.2 as "The remote message from the remote LER is assigned
a priority just below the similar local input." In order to support
the manual switch behavior described in Section 6.3, additional rules
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for equal priority resolution are required. Since the support of
protection against signal degrade also requires a similar equal
priority resolution, the rules are described in Section 7.4.
Support of this function requires changes to the PSC Control logic
(including the state machine) compared to that shown in RFC 6378.
Section 10 and Section 11 show the PSC Control logic when all of the
capabilities in APS mode are enabled.
7. Capability 4: Support of Protection against SD
7.1. Motivation for supporting protection against SD
In MPLS-TP survivability framework [RFC6372], fault conditions
include both SF and SD that can be used to trigger protection
switching.
RFC 6378 [RFC6378], which defines the protection switching protocol
for MPLS-TP does not specify how the SF and SD are detected, and
specifies the protection switching protocol associated with SF only.
The PSC protocol associated with SD is covered in this document, but
the specifics for the method of identifying SD is out of the scope of
the protection protocol similar to the facts that how SF is detect
and how MS and FS commands are initiated in a management system and
signaled to protection switching are out of its scope.
7.2. Terminology to support SD
In this document the term Clear Signal Fail or Degrade (SFDc) is used
to indicate the clearance of either a degraded condition or a failure
condition.
The second paragraph of Section 4.3.3.2 Unavailable state in RFC 6378
shows the intention of including Signal Degrade on Protection path
(SD-P) in the Unavailable state. Even though the protection path can
be partially available under the condition of SD-P, this document
follows the same state grouping as RFC 6378 for SD-P.
The bullet item "Protecting failure state" in Section 3.6 in RFC 6378
includes the degraded condition in Protecting failure state. This
document follows the same state grouping as RFC 6378 for Signal
Degrade on Working path (SD-W).
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7.3. Behavior of protection against SD
In order to make the behavior of MPLS-TP networks consistent with
that of other transport networks (such as SDH, OTN and Ethernet
transport networks), the priorities of SD-P and SD-W are defined to
be equal. Once a switch has been completed due to SD on one path, it
will not be overridden by SD on the other path (first come, first
served behavior), to avoid protection switching that cannot improve
signal quality.
SD indicates that the transmitting end point has identified a
degradation of the signal, or integrity of the packet transmission on
either the working path or the protection path. The FPath field
SHALL identify the path that is reporting the degrade condition
(i.e., if the protection path, then FPath is set to 0; if the working
path, then FPath is set to 1), and the Path field SHALL indicate
where the data traffic is being transported (i.e., if the working
path is selected, then Path is set to 0; if the protection path is
selected, then Path is set to 1).
The Wait-to-Restore (WTR) timer is used when the protected domain is
configured for revertive behavior and started at the node that
recovers from a local degraded condition on the working path.
Protection switching against SD is always provided by a selector
bridge duplicating user data traffic and feeding it to both the
working path and the protection path under SD condition. When a
local or remote SD occurs on either the working path or the
protection path, the LER SHALL duplicate user data traffic and SHALL
feed to both the working path and the protection path. The packet
duplication SHALL continue as long as any SD condition exists in the
protected domain, and SHALL stop when there is no SD condition.
Additionally, the packet duplication SHALL continue in the WTR state
in revertive mode. In non-revertive mode, the packet duplication
SHALL stop when there is no SD condition.
The selector bridge with the packet duplication under SD condition,
which is a non-permanent bridge, is considered to be a 1:1 protection
architecture.
Protection switching against SD does not introduce any modification
to the operation of the selector at the sink LER described in RFC
6378. The selector chooses either the working or protection path
from which to receive the normal traffic in both 1:1 and 1+1
architectures. The position of the selector, i.e., which path to
receive the traffic, is determined by the PSC protocol in
bidirectional switching or by the local input in unidirectional
switching.
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7.4. Equal priority resolution
In order to support the manual switch behavior described in
Section 6.3 and the protection against Signal Degrade described in
Section 7.3, the rules to resolve the equal priority requests are
required.
For the equal priority local inputs, such as MS and SD, first-come,
first-served rule is applied. Once a local input is determined as
the highest priority local input, then a subsequent equal priority
local input requesting a different action, i.e., the action results
in the same PSC Request field but different FPath value, will not be
presented to the PSC Control logic as the highest local request.
Furthermore, in the case of MS command, the subsequent local MS
command requesting a different action will be cancelled.
If the LER is in a remote state due to a remote SD (or MS) message, a
subsequent local input having the same priority but requesting
different action to the PSC Control logic, will be considered as
having lower priority than the remote message, and will be ignored.
If the LER is in remote Switching administrative state due to a
remote MS-P, then subsequent local MS-W SHALL be ignored and
automatically cancelled. If the LER is in remote Unavailable state
due to a remote SD-P, then subsequent local SD-W input will be
ignored. However, the local SD-W SHALL appear in the Local Request
logic as long as the SD condition exists, but SHALL NOT be the top
priority global request, which determines the state transition at the
PSC Control logic.
There is a case where one LER receives a local input and the other
LER receives, simultaneously, a local input with the same priority
but requesting different action. In this case, each of the two LERs
receives a subsequent remote message having the same priority but
requesting different action, while the LER is in a local state due to
the local input. When this case happens, a priority must be set for
the inputs with the same priority regardless of its origin (local
input or remote message).
o When MS-W and MS-P occur simultaneously at both LERs, MS-W SHALL
be considered as having higher priority than MS-P at both LERs.
o When SD-W and SD-P occur simultaneously at both LERs, the SD on
the standby path (the path from which the selector does not select
the user data traffic) is considered as having higher priority
than the SD on the active path (the path from which the selector
selects the user data traffic) regardless of its origin (local or
remote message). Therefore, no unnecessary protection switching
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is performed and the user data traffic continues to be selected
from the active path.
In the preceding paragraphs, the "simultaneously" refers to the case
a sent SD (or MS) request has not been confirmed by the remote end in
bidirectional protection switching. When a local node that has
transmitted a SD message receives a SD (or MS) message that indicates
a different value of data path (Path) field than the value of the
Path field in the transmitted SD (or MS) message, both the local and
the remote SD requests are considered to occur simultaneously.
The addition of support for protection against SD requires different
PSC Control logic (including the state machine) compared to that
shown in RFC 6378. Section 10 and Section 11 show the PSC Control
logic when all of the capabilities in APS mode are enabled.
8. Capability 5: Support of EXER Command
EXER is a command to test if the PSC communication is operating
correctly. More specifically, EXER is to test and validate the
linear protection mechanism and PSC protocol including the aliveness
of the Local Request logic, the PSC state machine and the PSC message
generation and reception, and the integrity of the protection path,
without triggering the actual traffic switching. It is used while
the working path is either carrying the traffic or not. It has lower
priority than any "real" switch request. It is only valid in
bidirectional switching, since this is the only place where one can
get a meaningful test by looking for a response.
This command is documented in R84 of RFC 5654 [RFC5654].
A received EXER message indicates that the remote end point is
operating under an operator command to validate the protection
mechanism and PSC protocol including the aliveness of the Local
Request logic, the PSC state machine and the PSC message generation
and reception, and the integrity of the protection path, without
triggering the actual traffic switching. The valid response to EXER
message is an Reverse Request (RR) with the corresponding FPath and
Path numbers. The local LER SHALL signal a RR only in response to an
EXER command from the remote LER.
If EXER commands are input at both ends, then a race condition may
arise. This is resolved as follows:
o If an LER has issued EXER and receives EXER before receiving RR,
it
o MUST treat the received EXER as it would an RR, and
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o SHOULD NOT respond with RR.
The following PSC Requests are added to the PSC Request field to
support the Exercise command (see also Section 14.1):
(3) Exercise - indicates that the transmitting end point is
exercising the protection channel and mechanism. FPath and Path
are set to the same value of the No Request (NR), RR or DNR
request that EXER replaces.
(2) Reverse Request - indicates that the transmitting end point is
responding to an EXER command from the remote LER. FPath and Path
are set to the same value of the NR or DNR request that RR
replaces.
The relative priorities of EXER and RR are shown in Section 10.2.
9. Capabilities and Modes
9.1. Capabilities
A Capability is an individual behavior whose use is signaled in a
Capabilities TLV, which is placed in Optional TLVs field inside the
PSC message shown in Figure 2 of RFC 6378 [RFC6378]. The format of
the Capabilities TLV is:
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
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Type = Capabilities | Length |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Value = Flags |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 1: Format of Capabilities TLV
The value of the Type field is TBD pending IANA allocation.
The value of the Length field is the length of the Flags field in
octets. The length of the Flags field MUST be a multiple of 4 octets
and MUST be the minimum required to signal all the required
capabilities.
Section 4 to Section 8 discuss five capabilities that are signaled
using the five most significant bits; if a node wishes to signal
these five capabilities, it MUST send a Flags field of 4 octets. A
node would send a Flags field greater than 4 octets only if it had
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more than 32 Capabilities to indicate. All unused bits MUST be set
to zero.
If the bit assigned for an individual capability is set to 1, it
indicates the sending node's intent to use that capability in the
protected domain. If a bit is set to 0, the sending node does not
intend to use the indicated capability in the protected domain. Note
that it is not possible to distinguish between the intent not to use
a capability and a node's complete non-support (i.e., lack of
implementation) of a given capability.
This document defines five specific capabilities that are described
from Section 4 to Section 8. Each capability is assigned bit as
follows:
0x80000000: priority modification
0x40000000: non-revertive behavior modification
0x20000000: support of MS-W command
0x10000000: support of protection against SD
0x08000000: support of EXER command
If all the five capabilities should be used, an LER SHALL set
0xF8000000 in the Flags field.
9.1.1. Sending and receiving the Capabilities TLV
A node MUST include its Capabilities TLV in every PSC message that it
sends. The transmission and acceptance of the PSC message is
described in Section 4.1 of RFC 6378.
When a node receives a Capabilities TLV it MUST compare it to its
most recent transmitted Capabilities TLV. If the two are equal, the
protected domain is said to be running in the mode indicated by that
set of capabilities (see Section 9.2). If the sent and received
Capabilities TLVs are not equal, this indicates a capabilities
mismatch. When this happens, the node MUST alert the operator and
MUST NOT perform any protection switching until the operator resolves
the mismatch in the Capabilities TLV.
9.2. Modes
A mode is a given set of Capabilities. Modes are shorthand;
referring to a set of capabilities by their individual values or by
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the name of their mode does not change the protocol behavior. This
document defines two modes - PSC and APS.
9.2.1. PSC mode
PSC mode is defined as the lack of any Capabilities - that is, a
Capabilities set of 0x0. It is the behavior specified in RFC 6378.
There are two ways to declare PSC mode. A node can send no
Capabilities TLV at all since there are no TLV units defined in RFC
6378, or it can send a Capabilities TLV with Flags value set to 0x0.
In order to allow backward compatibility between two nodes - one
which can send the Capabilities TLV, and one which cannot, a node
which has the ability to send and receive the PSC mode Capabilities
TLV MUST be able to both send the PSC mode Capabilities TLV and send
no Capabilities TLV at all. An implementation MUST be configurable
between these two choices.
9.2.2. APS mode
APS mode is defined as the use of all the five specific capabilities,
which are described from Section 4 to Section 8 in this document.
APS mode is indicated with the Flags value of 0xF8000000.
10. PSC Protocol in APS Mode
This section and Section 11 define the behavior of PSC protocol when
all of the aforementioned capabilities are enabled, i.e., APS mode.
10.1. Request field in PSC protocol message
This document defines two new values for the "Request" field in the
PSC protocol message that is shown in Figure 2 of RFC 6378 [RFC6378]
as follows:
(3) Exercise
(2) Reverse Request
See also Section 14.1 of this document.
10.2. Priorities of local inputs and remote requests
Based on the description in Section 3 and Section 4.3.2 in RFC 6378,
the priorities of multiple outstanding local inputs are evaluated in
the Local Request logic, where the highest priority local input
(highest local request) is determined. This highest local request is
passed to the PSC Control logic, that will determine the higher
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priority input (top priority global request) between the highest
local request and the last received remote message. When a remote
message comes to the PSC Control logic, the top priority global
request is determined between this remote message and the highest
local request which is present. The top priority global request is
used to determine the state transition, which is described in
Section 11. In this document, in order to simplify the description
on the PSC Control logic, we strictly decouple the priority
evaluation from the state transition table lookup.
The priorities for both local and remote requests are defined as
follows from highest to lowest:
o Operator Clear (Local only)
o Lockout of protection (Local and Remote)
o Clear Signal Fail or Degrade (Local only)
o Signal Fail on Protection path (Local and Remote)
o Forced Switch (Local and Remote)
o Signal Fail on Working path (Local and Remote)
o Signal Degrade on either Protection path or Working path (Local
and Remote)
o Manual Switch to either Protection path or Working path (Local and
Remote)
o WTR Timer Expires (Local only)
o WTR (Remote only)
o Exercise (Local and Remote)
o Reverse Request (Remote only)
o Do-Not-Revert (Remote only)
o No Request (Remote and Local)
Note that the "Local only" requests are not signaled to the remote
LER. Likewise, the "Remote only" requests do not exist in the Local
Request logic as local inputs. For example, the priority of WTR only
applies to the received WTR message, which is generated from the
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remote LER. The remote LER that is running the WTR timer in the WTR
state has no local request.
The remote request from the remote LER is assigned a priority just
below the same local request. However, for the equal priority
requests, such as SD and MS, the following equal priority resolution
rules are defined:
o If two local inputs having the same priority but requesting
different action come to the Local Request logic, then the input
coming first SHALL be considered to have a higher priority than
the other coming later (first-come, first-served).
o If the PSC Control logic has both the highest local request and a
remote message with the same priority and requesting the same
action, i.e., the same PSC Request field and the same FPath value,
then the local input SHALL be considered to have a higher priority
than the remote message.
o If the PSC Control logic has both the highest local request and a
remote message with the same priority but requesting different
action and the remote message exists when the highest local
request comes to the PSC Control logic, the highest local request
is ignored and the remote Request SHALL be the top priority global
request.
o If the PSC Control logic has both the highest local request and a
remote message with the same priority but requesting different
action and the highest local request exists when the remote
message comes to the PSC Control logic, the top priority global
request SHALL be determined by the following rules for each
simultaneous condition:
o For simultaneous MS requests, the MS-W request SHALL be considered
to have a higher priority than the MS-P request. The LER that has
local MS-W request SHALL maintain the local MS-W request as the
top priority global request, but the other LER that has local MS-P
request SHALL clear the MS-P command and internally generate
"Operator Clear" request.
o For simultaneous SD requests, the SD on the standby path (the path
from which the selector does not select the user data traffic)
SHALL be considered as having higher priority than the SD on the
active path (the path from which the selector selects the user
data traffic) regardless of its origin (local or remote message).
The LER that has the SD on the standby path SHALL maintain the
local SD on the standby path request as the top priority global
request. The other LER that has local SD on the active path SHALL
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use the remote SD on the standby path as the top priority global
request to lookup the state transition table. The differentiation
of the active and standby paths is based upon which path had been
used for the user data traffic at the time just before an LER
selected its local SD as the top priority global request.
No Request is another exception to the rule of assigning a remote
request a priority just below the same local request. Since a
received NR message needs to be used in the state transition table
lookup when there is no outstanding local request, the received
remote NR request SHALL be the top priority global request when there
is no request in the local LER.
10.3. Acceptance and retention of local inputs
A local input indicating a defect, such as SF-P, SF-W, SD-P and SD-W,
SHALL be accepted and retained persistently in the Local Request
logic as long as the defect condition exists. If there is any higher
priority local input than the local defect input, the higher priority
local input is passed to the PSC Control logic as the highest local
request, but the local defect input cannot be removed but remains in
the Local Request logic. When the higher priority local input
disappears, the local defect will become the highest local request if
the defect condition still exists.
Operator Clear command, SFDc and WTR Timer Expires are not
persistent. Once they appear to the Local Request logic and complete
the operation, they SHALL be disappeared.
Operator LO, FS, MS, and EXER commands SHALL be rejected if there is
any higher priority local input in the Local Request logic. If a new
higher-priority local request (including an operator command) is
accepted, any previous lower-priority local operator command SHALL be
cancelled. When any higher-priority remote request is received, a
lower-priority local operator command SHALL be cancelled. The
cancelled operator command is forgotten and will never return, unless
the operator reissues the command.
11. State Transition Tables in APS Mode
When there is a change in the highest local request or in remote PSC
messages, the top priority global request SHALL be evaluated and the
state transition tables SHALL be looked up in the PSC Control logic.
The following rules are applied to the operation related to the state
transition table lookup.
o If the top priority global request, which determines the state
transition, is the highest local request, the local state
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transition table in Section 11.1 SHALL be used to decide the next
state of the LER. Otherwise, remote messages state transition
table in Section 11.2 SHALL be used.
o If in remote state, the highest local defect condition (SF-P,
SF-W, SD-P or SD-W) SHALL always be reflected in the Request field
and Fpath.
o For the LER currently in the local state, if the top priority
global request is changed to Operator Clear (OC) or SFDc causing
the next state to be Normal, WTR or DNR, then all the local and
remote requests SHALL be re-evaluated as if the LER is in the
state specified in the footnotes to the state transition tables,
before deciding the final state. If there are no active requests,
the LER enters the state specified in the footnotes to the state
transition tables. This re-evaluation is an internal operation
confined within the local LER, and the PSC messages are generated
according to the final state.
o The WTR timer is started only when the LER which has recovered
from a local failure/degradation enters the WTR state. An LER
which is entering into the WTR state due to a remote WTR message
does not start the WTR timer. The WTR timer SHALL be stopped when
any local or remote request triggers the state change out of the
WTR state.
The extended states, as they appear in the table, are as follows:
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N Normal state
UA:LO:L Unavailable state due to local LO command
UA:P:L Unavailable state due to local SF-P
UA:DP:L Unavailable state due to local SD-P
UA:LO:R Unavailable state due to remote LO message
UA:P:R Unavailable state due to remote SF-P message
UA:DP:R Unavailable state due to remote SD-P message
PF:W:L Protecting failure state due to local SF-W
PF:DW:L Protecting failure state due to local SD-W
PF:W:R Protecting failure state due to remote SF-W message
PF:DW:R Protecting failure state due to remote SD-W message
SA:F:L Switching administrative state due to local FS command
SA:MW:L Switching administrative state due to local MS-W command
SA:MP:L Switching administrative state due to local MS-P command
SA:F:R Switching administrative state due to remote FS message
SA:MW:R Switching administrative state due to remote MS-W message
SA:MP:R Switching administrative state due to remote MS-P message
E::L Exercise state due to local EXER command
E::R Exercise state due to remote EXER message
WTR Wait-to-Restore state
DNR Do-not-Revert state
Each state corresponds to the transmission of a particular set of
Request, FPath and Path bits. The table below lists the message that
is generally sent in each particular state. If the message to be
sent in a particular state deviates from the table below, it is noted
in the footnotes to the state transition tables.
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State REQ(FP,P)
------- ---------
N NR(0,0)
UA:LO:L LO(0,0)
UA:P:L SF(0,0)
UA:DP:L SD(0,0)
UA:LO:R highest local request(local FPath,0)
UA:P:R highest local request(local FPath,0)
UA:DP:R highest local request(local FPath,0)
PF:W:L SF(1,1)
PF:DW:L SD(1,1)
PF:W:R highest local request(local FPath,1)
PF:DW:R highest local request(local FPath,1)
SA:F:L FS(1,1)
SA:MW:L MS(0,0)
SA:MP:L MS(1,1)
SA:F:R highest local request(local FPath,1)
SA:MW:R NR(0,0)
SA:MP:R NR(0,1)
WTR WTR(0,1)
DNR DNR(0,1)
E::L EXER(0,x), where x is the existing Path value
when Exercise command is issued.
E::R RR(0,x), where x is the existing Path value
when RR message is generated.
Some operation examples of APS mode are shown in Appendix D.
In the state transition tables below, the letter 'i' stands for
"ignore", and is an indication to remain in the current state and
continue transmitting the current PSC message
11.1. State transition by local inputs
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| OC | LO | SFDc | SF-P | FS | SF-W |
--------+-----+---------+------+--------+--------+--------+
N | i | UA:LO:L | i | UA:P:L | SA:F:L | PF:W:L |
UA:LO:L | (1) | i | i | i | i | i |
UA:P:L | i | UA:LO:L | (1) | i | i | i |
UA:DP:L | i | UA:LO:L | (1) | UA:P:L | SA:F:L | PF:W:L |
UA:LO:R | i | UA:LO:L | i | UA:P:L | i | PF:W:L |
UA:P:R | i | UA:LO:L | i | UA:P:L | i | PF:W:L |
UA:DP:R | i | UA:LO:L | i | UA:P:L | SA:F:L | PF:W:L |
PF:W:L | i | UA:LO:L | (2) | UA:P:L | SA:F:L | i |
PF:DW:L | i | UA:LO:L | (2) | UA:P:L | SA:F:L | PF:W:L |
PF:W:R | i | UA:LO:L | i | UA:P:L | SA:F:L | PF:W:L |
PF:DW:R | i | UA:LO:L | i | UA:P:L | SA:F:L | PF:W:L |
SA:F:L | (3) | UA:LO:L | i | UA:P:L | i | i |
SA:MW:L | (1) | UA:LO:L | i | UA:P:L | SA:F:L | PF:W:L |
SA:MP:L | (3) | UA:LO:L | i | UA:P:L | SA:F:L | PF:W:L |
SA:F:R | i | UA:LO:L | i | UA:P:L | SA:F:L | PF:W:L |
SA:MW:R | i | UA:LO:L | i | UA:P:L | SA:F:L | PF:W:L |
SA:MP:R | i | UA:LO:L | i | UA:P:L | SA:F:L | PF:W:L |
WTR | (4) | UA:LO:L | i | UA:P:L | SA:F:L | PF:W:L |
DNR | i | UA:LO:L | i | UA:P:L | SA:F:L | PF:W:L |
E::L | (5) | UA:LO:L | i | UA:P:L | SA:F:L | PF:W:L |
E::R | i | UA:LO:L | i | UA:P:L | SA:F:L | PF:W:L |
| SD-P | SD-W | MS-W | MS-P | WTRExp | EXER
--------+---------+---------+---------+---------+--------+------
N | UA:DP:L | PF:DW:L | SA:MW:L | SA:MP:L | i | E::L
UA:LO:L | i | i | i | i | i | i
UA:P:L | i | i | i | i | i | i
UA:DP:L | i | i | i | i | i | i
UA:LO:R | UA:DP:L | PF:DW:L | i | i | i | i
UA:P:R | UA:DP:L | PF:DW:L | i | i | i | i
UA:DP:R | UA:DP:L | PF:DW:L | i | i | i | i
PF:W:L | i | i | i | i | i | i
PF:DW:L | i | i | i | i | i | i
PF:W:R | UA:DP:L | PF:DW:L | i | i | i | i
PF:DW:R | UA:DP:L | PF:DW:L | i | i | i | i
SA:F:L | i | i | i | i | i | i
SA:MW:L | UA:DP:L | PF:DW:L | i | i | i | i
SA:MP:L | UA:DP:L | PF:DW:L | i | i | i | i
SA:F:R | UA:DP:L | PF:DW:L | i | i | i | i
SA:MW:R | UA:DP:L | PF:DW:L | SA:MW:L | i | i | i
SA:MP:R | UA:DP:L | PF:DW:L | i | SA:MP:L | i | i
WTR | UA:DP:L | PF:DW:L | SA:MW:L | SA:MP:L | (6) | i
DNR | UA:DP:L | PF:DW:L | SA:MW:L | SA:MP:L | i | E::L
E::L | UA:DP:L | PF:DW:L | SA:MW:L | SA:MP:L | i | i
E::R | UA:DP:L | PF:DW:L | SA:MW:L | SA:MP:L | i | E::L
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(1) Re-evaluate to determine final state as if the LER is in the
Normal state. If there are no active requests, the LER enters
the Normal State.
(2) In the case that both local input after SFDc and the last
received remote message are no requests, the LER enters into the
WTR state when the domain is configured for revertive behavior,
or the LER enters into the DNR state when the domain is
configured for non-revertive behavior. In all the other cases,
where one or more active requests exist, re-evaluate to
determine the final state as if the LER is in the Normal state.
(3) Re-evaluate to determine final state as if the LER is in the
Normal state when the domain is configured for revertive
behavior, or as if the LER is in the DNR state when the domain
is configured for non-revertive behavior. If there are no
active requests, the LER enters either the Normal state when the
domain is configured for revertive behavior or the DNR state
when the domain is configured for non-revertive behavior.
(4) Remain in the WTR state and send NR(0,1). Stop the WTR timer if
it is running. In APS mode, OC can cancel the WTR timer and
hasten the state transition to the Normal state as in other
transport networks.
(5) If Path value is 0, re-evaluate to determine final state as if
the LER is in the Normal state. If Path value is 1, re-evaluate
to determine final state as if the LER is in the DNR state. If
there are no active requests, the LER enters the Normal state
when Path value is 0, or the DNR state when Path value is 1.
(6) Remain in the WTR state and send NR(0,1).
11.2. State transition by remote messages
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| LO | SF-P | FS | SF-W | SD-P | SD-W |
--------+---------+--------+--------+--------+---------+---------+
N | UA:LO:R | UA:P:R | SA:F:R | PF:W:R | UA:DP:R | PF:DW:R |
UA:LO:L | i | i | i | i | i | i |
UA:P:L | UA:LO:R | i | i | i | i | i |
UA:DP:L | UA:LO:R | UA:P:R | SA:F:R | PF:W:R | i | (7) |
UA:LO:R | i | UA:P:R | SA:F:R | PF:W:R | UA:DP:R | PF:DW:R |
UA:P:R | UA:LO:R | i | SA:F:R | PF:W:R | UA:DP:R | PF:DW:R |
UA:DP:R | UA:LO:R | UA:P:R | SA:F:R | PF:W:R | i | PF:DW:R |
PF:W:L | UA:LO:R | UA:P:R | SA:F:R | i | i | i |
PF:DW:L | UA:LO:R | UA:P:R | SA:F:R | PF:W:R | (8) | i |
PF:W:R | UA:LO:R | UA:P:R | SA:F:R | i | UA:DP:R | PF:DW:R |
PF:DW:R | UA:LO:R | UA:P:R | SA:F:R | PF:W:R | UA:DP:R | i |
SA:F:L | UA:LO:R | UA:P:R | i | i | i | i |
SA:MW:L | UA:LO:R | UA:P:R | SA:F:R | PF:W:R | UA:DP:R | PF:DW:R |
SA:MP:L | UA:LO:R | UA:P:R | SA:F:R | PF:W:R | UA:DP:R | PF:DW:R |
SA:F:R | UA:LO:R | UA:P:R | i | PF:W:R | UA:DP:R | PF:DW:R |
SA:MW:R | UA:LO:R | UA:P:R | SA:F:R | PF:W:R | UA:DP:R | PF:DW:R |
SA:MP:R | UA:LO:R | UA:P:R | SA:F:R | PF:W:R | UA:DP:R | PF:DW:R |
WTR | UA:LO:R | UA:P:R | SA:F:R | PF:W:R | UA:DP:R | PF:DW:R |
DNR | UA:LO:R | UA:P:R | SA:F:R | PF:W:R | UA:DP:R | PF:DW:R |
E::L | UA:LO:R | UA:P:R | SA:F:R | PF:W:R | UA:DP:R | PF:DW:R |
E::R | UA:LO:R | UA:P:R | SA:F:R | PF:W:R | UA:DP:R | PF:DW:R |
| MS-W | MS-P | WTR | EXER | RR | DNR | NR
--------+---------+---------+-----+------+----+------+----
N | SA:MW:R | SA:MP:R | i | E::R | i | i | i
UA:LO:L | i | i | i | i | i | i | i
UA:P:L | i | i | i | i | i | i | i
UA:DP:L | i | i | i | i | i | i | i
UA:LO:R | SA:MW:R | SA:MP:R | i | E::R | i | i | N
UA:P:R | SA:MW:R | SA:MP:R | i | E::R | i | i | N
UA:DP:R | SA:MW:R | SA:MP:R | i | E::R | i | i | N
PF:W:L | i | i | i | i | i | i | i
PF:DW:L | i | i | i | i | i | i | i
PF:W:R | SA:MW:R | SA:MP:R | (9) | E::R | i | (10) | (11)
PF:DW:R | SA:MW:R | SA:MP:R | (9) | E::R | i | (10) | (11)
SA:F:L | i | i | i | i | i | i | i
SA:MW:L | i | i | i | i | i | i | i
SA:MP:L | i | i | i | i | i | i | i
SA:F:R | SA:MW:R | SA:MP:R | i | E::R | i | DNR | N
SA:MW:R | i | SA:MP:R | i | E::R | i | i | N
SA:MP:R | SA:MW:R | i | i | E::R | i | DNR | N
WTR | SA:MW:R | SA:MP:R | i | i | i | i | (12)
DNR | SA:MW:R | SA:MP:R | i | E::R | i | i | i
E::L | SA:MW:R | SA:MP:R | (13)| i | i | i | i
E::R | SA:MW:R | SA:MP:R | i | i | i | DNR | N
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NOTES:
(7) If the received SD-W message has Path=0, ignore the message. If
the received SD-W message has Path=1, go to PF:DW:R state and
transmit SD(0,1)
(8) If the received SD-P message has Path=1, ignore the message. If
the received SD-P message has Path=0, go to UA:DP:R state and
transmit SD(1,0).
(9) Transition to the WTR state and continue to send the current
message.
(10) Transition to the DNR state and continue to send the current
message.
(11) If the received NR message has Path=1, transition to the WTR
state if domain configured for revertive behavior, else
transition to the DNR state. If the received NR message has
Path=0, transition to the Normal state.
(12) If the receiving LER's WTR timer is running, maintain current
state and message. If the WTR timer is not running, transition
to the Normal state.
(13) Transit to the WTR state and send NR(0,1) message. The WTR
timer is not initiated.
11.3. State transition for 1+1 unidirectional protection
The state transition tables given in Section 11.1 and Section 11.2
are for bidirectional protection switching, where remote PSC protocol
messages are used to determine the protection switching actions. The
1+1 unidirectional protection switching does not require the remote
information in PSC protocol message and acts upon local inputs only.
The state transition by local inputs in Section 11.1 SHALL be reused
for the 1+1 unidirectional protection under the following conditions:
o The value of Request field in the received remote message is
ignored and always assumed to be no request.
o Replace footnote (4) with "Stop the WTR timer and transit to the
Normal state."
o Replace footnote (6) with "Transit to the Normal state."
o Exercise is not applicable.
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12. Provisioning Mismatch and Protocol Failure in the APS Mode
The remote PSC message that is received from the remote LER is
subject to the detection of provisioning mismatch and protocol
failure conditions. In the APS mode, provisioning mismatches are
handled as follows:
o If the PSC message is received from the working path due to
working/protection path configuration mismatch, the node MUST
alert the operator and MUST NOT perform any protection switching
until the operator resolves this path configuration mismatch.
o In the case that the mismatch happens in two-bit "Protection Type
(PT)" field, which indicates permanent/selector bridge type and
uni/bidirectional switching type,
* If the value of the PT field of one side is 2 (i.e., selector
bridge) and the value of PT field of the other side is 1 or 3
(i.e., permanent bridge), then this event MUST be notified to
the operator and each node MUST NOT perform any protection
switching until the operator resolves this bridge type
mismatch.
* If the bridge type matches but the switching type mismatches,
i.e., one side has PT=1 (unidirectional switching) while the
other side has PT=2 or 3 (bidirectional switching), then the
node provisioned for bidirectional switching SHOULD fall back
to unidirectional switching to allow interworking. The node
SHOULD notify the operator of this event.
o If the "Revertive (R)" bit mismatches, two sides will interwork
and traffic is protected according to the state transition
definition given in Section 11. The node SHOULD notify the
operator of this event.
o If the Capabilities TLV mismatches, the node MUST alert the
operator and MUST NOT perform any protection switching until the
operator resolves the mismatch in the Capabilities TLV.
The followings are the protocol failure situations and the actions to
be taken:
o No match in sent "Data Path (Path)" and received "Data Path
(Path)" for more than 50 ms: The node MAY continue to perform
protection switching and SHOULD notify the operator of this event.
o No PSC message is received on the protection path during at least
3.5 times the long PSC message interval, (e.g. at least 17.5
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seconds with a default message interval of 5 seconds) and there is
no defect on the protection path: The node MUST alert the operator
and MUST NOT perform any protection switching until the operator
resolves this defect.
13. Security Considerations
No specific security issue is raised in addition to those ones
already documented in RFC 6378 [RFC6378]
14. IANA Considerations
14.1. MPLS PSC Request Registry
In the "Multiprotocol Label Switching (MPLS) Operations,
Administration, and Management (OAM) Parameters" registry, IANA
maintains the "MPLS PSC Request Registry".
IANA is requested to assign two new code points from this registry.
The values shall be allocated as follows:
Value Description Reference
----- --------------------- ---------------
2 Reverse Request (this document)
3 Exercise (this document)
14.2. MPLS PSC TLV Registry
In the "Multiprotocol Label Switching (MPLS) Operations,
Administration, and Management (OAM) Parameters" registry, IANA
maintains the "MPLS PSC TLV Registry".
This document defines a new value for the Capabilities TLV type in
the "MPLS PSC TLV Registry".
Value Description Reference
------ --------------------- ---------------
TBD Capabilities (this document)
14.3. MPLS PSC Capability Flag Registry
IANA is requested to create and maintain a new registry within the
"Multiprotocol Label Switching (MPLS) Operations, Administration, and
Management (OAM) Parameters" registry called "MPLS PSC Capability
Flag Registry". All flags within this registry SHALL be allocated
according to the "Standards Action" procedures as specified in RFC
5226 [RFC5226].
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The length of the flags MUST be a multiple of 4 octets. This
document defines 4 octet flags. Flags greater than 4 octets SHALL be
used only if more than 32 Capabilities need to be defined. Flags
defined in this document are:
Bit Hex Value Capability Reference
---- ---------- ----------------------------------- ---------------
0 0x80000000 priority modification (this document)
1 0x40000000 non-revertive behavior modification (this document)
2 0x20000000 support of MS-W command (this document)
3 0x10000000 support of protection against SD (this document)
4 0x08000000 support of EXER command (this document)
5-31 Unassigned (this document)
15. Acknowledgements
The authors would like to thank Yaacov Weingarten, Yuji Tochio,
Malcolm Betts, Ross Callon and Qin Wu for their valuable comments and
suggestions on this document.
We would also like to acknowledge explicit text provided by Loa
Andersson and Adrian Farrel.
16. References
16.1. Normative References
[RFC2119] Bradner, S., "Key words for use in RFCs to Indicate
Requirement Levels", BCP 14, RFC 2119, March 1997.
[RFC5226] Narten, T. and H. Alvestrand, "Guidelines for Writing an
IANA Considerations Section in RFCs", BCP 26, RFC 5226,
May 2008.
[RFC5654] Niven-Jenkins, B., Brungard, D., Betts, M., Sprecher, N.,
and S. Ueno, "Requirements of an MPLS Transport Profile",
RFC 5654, September 2009.
[RFC6378] Weingarten, Y., Bryant, S., Osborne, E., Sprecher, N., and
A. Fulignoli, "MPLS Transport Profile (MPLS-TP) Linear
Protection", RFC 6378, October 2011.
16.2. Informative References
[RFC4427] Mannie, E. and D. Papadimitriou, "Recovery (Protection and
Restoration) Terminology for Generalized Multi-Protocol
Label Switching (GMPLS)", RFC 4427, March 2006.
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[RFC6372] Sprecher, N. and A. Farrel, "MPLS Transport Profile (MPLS-
TP) Survivability Framework", RFC 6372, September 2011.
[G841] International Telecommunications Union, "Types and
characteristics of SDH network protection architectures",
ITU-T Recommendation G.841, October 1998.
[G873.1] International Telecommunications Union, "Optical Transport
Network (OTN): Linear protection", ITU-T Recommendation
G.873.1, July 2011.
[G8031] International Telecommunications Union, "Ethernet Linear
Protection Switching", ITU-T Recommendation G.8031/Y.1342,
June 2011.
Appendix A. An Example of Out-of-service Ccenarios
The sequence diagram shown is an example of the out-of-service
scenarios based on the priority level defined in RFC 6378. The first
PSC message which differs from the previous PSC message is shown.
A Z
| |
(1) |-- NR(0,0) ------>| (1)
|<----- NR(0,0) ---|
| |
| |
| (FS issued at Z) | (2)
(3) |<------ FS(1,1) --|
|-- NR(0,1) ------>|
| |
| |
(4) | (SF on P(A<-Z)) |
| |
| |
| (Clear FS at Z) | (5)
(6) | X <- NR(0,0) --|
| |
| |
(1) Each end is in the Normal state, and transmits NR(0,0) messages.
(2) When a FS command is issued at node Z, node Z goes into local
Protecting administrative state (PA:F:L) and begins transmission of
an FS(1,1) messages.
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(3) A remote FS message causes node A to go into remote Protecting
administrative state (PA:F:R), and node A begins transmitting NR(0,1)
messages.
(4) When node A detects a unidirectional SF-P, node A keeps sending
NR(0,1) message because SF-P is ignored under the PA:F:R state.
(5) When a Clear command is issued at node Z, node Z goes into the
Normal state and begins transmission of NR(0,0) messages.
(6) But, node A cannot receive PSC message because of local
unidirectional SF-P. Because no valid PSC message is received, over
a period of several successive message intervals, the last valid
received message remains applicable and the node A continue to
transmit an NR(0,1) message in the PA:F:R state.
Now, there exists a mismatch between the bridge/selector positions of
node A (transmitting an NR(0,1)) and node Z (transmitting an
NR(0,0)). It results in out-of-service even when there is neither
SF-W nor FS.
Appendix B. An Example of Sequence Diagram Showing the Problem with the
Priority Level of SFc
An example of sequence diagram showing the problem with the priority
level of SFc defined in RFC 6378 is given below. The following
sequence diagram is depicted for the case of bidirectional signal
fails. However, other cases with unidirectional signal fails can
result in the same problem. The first PSC message which differs from
the previous PSC message is shown.
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A Z
| |
(1) |-- NR(0,0) ------>| (1)
|<----- NR(0,0) ---|
| |
| |
(2) | (SF on P(A<->Z)) | (2)
|-- SF(0,0) ------>|
|<------ SF(0,0) --|
| |
| |
(3) | (SF on W(A<->Z)) | (3)
| |
| |
(4) | (Clear SF-P) | (4)
| |
| |
(5) | (Clear SF-W) | (5)
| |
| |
(1) Each end is in the Normal state, and transmits NR(0,0) messages.
(2) When SF-P occurs, each node enters into the UA:P:L state and
transmits SF(0,0) messages. Traffic remains on the working path.
(3) When SF-W occurs, each node remains in the UA:P:L state as SF-W
has a lower priority than SF-P. Traffic is still on the working
path. Traffic cannot be delivered as both the working path and the
protection path are experiencing signal fails.
(4) When SF-P is cleared, local "Clear SF-P" request cannot be
presented to the PSC Control logic, which takes the highest local
request and runs PSC state machine, since the priority of "Clear
SF-P" is lower than that of SF-W. Consequently, there is no change
in state, and the selector and/or bridge keep pointing at the working
path, which has signal fail condition.
Now, traffic cannot be delivered while the protection path is
recovered and available. It should be noted that the same problem
will occur in the case that the sequence of SF-P and SF-W events is
changed.
If we further continue with this sequence to see what will happen
after SF-W is cleared,
(5) When SF-W is cleared, local "Clear SF-W" request can be passed to
the PSC Control logic as there is no higher priority local input, but
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this will be ignored in the PSC Control logic according to the state
transition definition in RFC 6378. There will be no change in state
or protocol message transmitted.
As SF-W is now cleared and the selector and/or bridge are still
pointing at the working path, traffic delivery is resumed. However,
each node is the in UA:P:L state and transmitting SF(0,0) message,
while there exists no outstanding request for protection switching.
Moreover, any future legitimate protection switching requests, such
as SF-W, will be rejected as each node thinks the protection path is
unavailable.
Appendix C. Freeze Command
The "Freeze" command applies only to the local LER of the protection
group and is not signaled to the remote LER. This command freezes
the state of the protection group. Until the Freeze is cleared,
additional local commands are rejected and condition changes and
received PSC information are ignored.
"Clear Freeze" command clears the local freeze. When the Freeze
command is cleared, the state of the protection group is recomputed
based on the persistent condition of the local triggers.
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 a fault condition.
Appendix D. Operation Examples of the APS Mode
The sequence diagrams shown in this section are only a few examples
of the APS mode operations. The first PSC protocol message which
differs from the previous message is shown. The operation of hold-
off timer is omitted. The Request, FPath and Path fields, whose
values are changed during PSC message exchange are shown. For an
example, SF(1, 0) represents an PSC message with the following field
values: Request = SF, FPath = 1, and Path = 1. The values of the
other fields remain unchanged from the initial configuration.
W(A->Z) and P(A->Z) indicate the working path and the protection path
in the direction of A to Z, respectively.
Example 1. 1:1 bidirectional protection switching (revertive mode) -
Unidirectional SF case
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A Z
| |
(1) |<---- NR(0,0)---->| (1)
| |
| |
(2) | (SF on W(Z->A)) |
|---- SF(1,1)----->| (3)
(4) |<----- NR(0,1)----|
| |
| |
(5) | (Clear SF-W) |
|---- WTR(0,1)---->|
/| |
| | |
WTR timer | |
| | |
\| |
(6) |---- NR(0,1)----->| (7)
(8) |<----- NR(0,0)----|
|---- NR(0,0)----->| (9)
| |
(1) The protection domain is operating without any defect, and the
working path is used for delivering the traffic in the Normal state.
(2) SF-W occurs in the Z to A direction. Node A enters into the
PF:W:L state and generates SF(1, 1) message. Selector and bridge of
node A are pointing at the protection path.
(3) Upon receiving SF(1, 1), node Z sets selector and bridge to the
protection path. As there is no local request in node Z, node Z
generates NR(0, 1) message in the PF:W:R state.
(4) Node A confirms that the remote LER is also selecting protection
path.
(5) Node A detects clearing of SF condition, starts the WTR timer,
and sends WTR(0, 1) message in the WTR state.
(6) At expiration of the WTR timer, node A sets selector and bridge
to the working path and sends NR(0, 1) message.
(7) Node Z is notified that the remote request has been cleared.
Node Z transits to the Normal state and sends NR(0,0) message.
(8) Upon receiving NR(0,0) message, node A transits to the Normal
state and sends NR(0,0) message.
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(9) It is confirmed that the remote LER is also selecting the working
path.
Example 2. 1:1 bidirectional protection switching (revertive mode) -
Bidirectional SF case - Inconsistent WTR timers
A Z
| |
(1) |<---- NR(0,0)---->| (1)
| |
| |
(2) | (SF on W(A<->Z)) | (2)
|<---- SF(1,1)---->|
| |
| |
(3) | (Clear SF-W) | (3)
|<---- NR(0,1)---->|
(4) |<--- WTR(0,1) --->| (4)
/| |\
| | | |
WTR timer | | WTR timer
| | | |
| | |/
| |<------ NR(0,1)---| (5)
| | |
\| |
(6) |--- NR(0,1)------>|
|<------ NR(0,0)---| (7)
(8) |--- NR(0,0)------>|
| |
(1) Each end is in the Normal state, and transmits NR(0,0) messages.
(2) When SF-W occurs, each node enters into the PF:W:L state and
transmits SF(1,1) messages. Traffic is switched to the protection
path. Upon receiving SF(1,1), each node confirms that the remote LER
is also sending and receiving the traffic from the protection path.
(3) When SF-W is cleared, each node transits to the PF:W:R state and
transmits NR(0,1) messages as the last received message is SF-W.
(4) Upon receiving NR(0,1) messages, each node goes into the WTR
state, starts the WTR timer, and sends the WTR(0,1) messages.
(5) At expiration of the WTR timer in node Z, node Z sends NR(0,1) as
the last received APS message was WTR. When NR(0,1) arrives at node
A, node A maintains the WTR state and keeps sending current WTR
messages as described in the state transition table.
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(6) At expiration of the WTR timer in node A, node A sends NR(0,1).
(7) When the NR(0,1) message arrives at node Z, node Z moves to the
Normal state, sets selector and bridge to the working path, and sends
NR(0, 0) message.
(8) The received NR(0,0) message causes node A to go to the Normal
state. Now, the traffic is switched back to the working path.
Example 3. 1:1 bidirectional protection switching - R bit mismatch
This example shows that both sides will interwork and the traffic is
protected when one side (node A) is configured as revertive mode and
the other (node Z) is configured as non-revertive mode. The
interworking is covered in the state transition tables.
(revertive) A Z (non-revertive)
| |
(1) |<---- NR(0,0)---->| (1)
| |
| |
(2) | (SF on W(A<->Z)) | (2)
|<---- SF(1,1)---->|
| |
| |
(3) | (Clear SF-W) | (3)
|<---- NR(0,1)---->|
(4) |<----- DNR(0,1)---| (4)
/|-- WTR(0,1)------>|
| |<----- NR(0,1)----| (5)
| | |
WTR timer | |
| | |
| | |
\| |
(6) |--- NR(0,1)------>|
|<------ NR(0,0)---| (7)
(8) |--- NR(0,0)------>|
| |
(1) Each end is in the Normal state, and transmits NR(0,0) messages.
(2) When SF-W occurs, each node enters into the PF:W:L state and
transmits SF(l,l) messages. Traffic is switched to the protection
path. Upon receiving SF(1,1), each node confirms that the remote LER
is also sending and receiving the traffic on the protection path.
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(3) When SF-W is cleared, each node transits to the PF:W:R state and
transmits NR(0,1) messages as the last received message is SF-W.
(4) Upon receiving NR(0,1) messages, node A goes into the WTR state,
starts the WTR timer, and sends WTR(0,1) messages. At the same time,
node B transits to the DNR state and sends DNR(0,1) message.
(5) When the WTR message arrives at node Z, node Z transits to the
WTR state and send NR(0,1) message according to the state transition
table. At the same time, the DNR message arrived at node Z is
ignored according to the state transition table. Therefore, node Z,
which is configured as non-revertive mode, is operating as if in
revertive mode.
(6) At expiration of the WTR timer in node A, node A sends NR(0,1).
(7) When the NR(0,1) message arrives at node Z, node Z moves to the
Normal state, sets selector and bridge to the working path, and sends
NR(0, 0) message.
(8) The received NR(0,0) message causes node A to transits to the
Normal state. Now, the traffic is switched back to the working path.
Authors' Addresses
Jeong-dong Ryoo (editor)
ETRI
218 Gajeongno
Yuseong-gu, Daejeon 305-700
South Korea
Phone: +82-42-860-5384
Email: ryoo@etri.re.kr
Eric Gray (editor)
Ericsson
Email: eric.gray@ericsson.com
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Huub van Helvoort
Huawei Technologies
Karspeldreef 4,
Amsterdam 1101 CJ
the Netherlands
Phone: +31 20 4300936
Email: huub.van.helvoort@huawei.com
Alessandro D'Alessandro
Telecom Italia
via Reiss Romoli, 274
Torino 10148
Italy
Phone: +39 011 2285887
Email: alessandro.dalessandro@telecomitalia.it
Taesik Cheung
ETRI
218 Gajeongno
Yuseong-gu, Daejeon 305-700
South Korea
Phone: +82-42-860-5646
Email: cts@etri.re.kr
Eric Osborne
Cisco Systems, Inc.
Email: eosborne@cisco.com
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