--- 1/draft-ietf-mpls-rsvp-te-p2mp-02.txt	2006-02-04 17:18:34.000000000 +0100
+++ 2/draft-ietf-mpls-rsvp-te-p2mp-03.txt	2006-02-04 17:18:34.000000000 +0100
@@ -1,25 +1,25 @@
 
 Network Working Group                               R. Aggarwal (Editor)
 Internet Draft                                          Juniper Networks
-Expiration Date: January 2006
+Expiration Date: April 2006
                                                D. Papadimitriou (Editor)
                                                                  Alcatel
 
                                                     S. Yasukawa (Editor)
                                                                      NTT
 
-                                                               July 2005
+                                                            October 2005
 
          Extensions to RSVP-TE for Point to Multipoint TE LSPs
 
-                  draft-ietf-mpls-rsvp-te-p2mp-02.txt
+                  draft-ietf-mpls-rsvp-te-p2mp-03.txt
 
 Status of this Memo
 
    By submitting this Internet-Draft, each author represents that any
    applicable patent or other IPR claims of which he or she is aware
    have been or will be disclosed, and any of which he or she becomes
    aware will be disclosed, in accordance with Section 6 of BCP 79.
 
    Internet-Drafts are working documents of the Internet Engineering
    Task Force (IETF), its areas, and its working groups.  Note that
@@ -77,127 +77,131 @@
  6.2.1      Resv Message Throttling  ...............................  18
  6.3        Record Routing  ........................................  18
  6.3.1      RRO Processing  ........................................  18
  6.4        Reservation Style  .....................................  19
  7          PathTear Message  ......................................  19
  7.1        PathTear Message Format  ...............................  19
  7.2        Pruning  ...............................................  20
  7.2.1      Implicit S2L Sub-LSP Teardown  .........................  20
  7.2.2      Explicit S2L Sub-LSP Teardown   ........................  20
  8          Notify and ResvConf Messages  ..........................  21
- 9          Refresh Reduction  .....................................  21
-10          State Management  ......................................  22
-10.1        Incremental State Update  ..............................  22
-10.2        Combining Multiple Path Messages  ......................  23
-11          Error Processing  ......................................  24
-11.1        PathErr Messages  ......................................  24
-11.2        ResvErr Messages  ......................................  24
-11.3        Branch Failure Handling  ...............................  25
-12          Admin Status Change  ...................................  26
-13          Label Allocation on LANs with Multiple Downstream Nodes  ...26
-14          P2MP LSP and Sub-LSP Re-optimization  ..................  26
+ 8.1        Notify Messages  .......................................  21
+ 8.2        ResvConf Messages  .....................................  22
+ 9          Refresh Reduction  .....................................  23
+10          State Management  ......................................  23
+10.1        Incremental State Update  ..............................  23
+10.2        Combining Multiple Path Messages  ......................  24
+11          Error Processing  ......................................  25
+11.1        PathErr Messages  ......................................  25
+11.2        ResvErr Messages  ......................................  26
+11.3        Branch Failure Handling  ...............................  26
+12          Admin Status Change  ...................................  27
 
-14.1        Make-before-break  .....................................  27
-14.2        Sub-Group Based Re-optimization  .......................  27
-15          Fast Reroute  ..........................................  27
-15.1        Facility Backup  .......................................  28
-15.2        One to One Backup  .....................................  29
-16          Support for LSRs that are not P2MP Capable  ............  29
-17          Reduction in Control Plane Processing with LSP Hierarchy  ..31
-18          P2MP LSP Remerging and Cross-Over  .....................  31
-19          New and Updated Message Objects  .......................  34
-19.1        SESSION Object  ........................................  34
-19.1.1      P2MP LSP Tunnel IPv4 SESSION Object  ...................  34
-19.1.2      P2MP LSP Tunnel IPv6 SESSION Object  ...................  35
-19.2        SENDER_TEMPLATE object  ................................  35
-19.2.1      P2MP LSP Tunnel IPv4 SENDER_TEMPLATE Object  ...........  35
-19.2.2      P2MP LSP Tunnel IPv6 SENDER_TEMPLATE Object  ...........  36
-19.3        S2L SUB-LSP Object  ....................................  37
-19.3.1      S2L SUB-LSP IPv4 Object  ...............................  37
-19.3.2      S2L SUB-LSP IPv6 Object  ...............................  38
-19.4        FILTER_SPEC Object  ....................................  38
-19.4.1      P2MP LSP_IPv4 FILTER_SPEC Object  ......................  38
-19.4.2      P2MP LSP_IPv4 FILTER_SPEC Object  ......................  38
-19.5        P2MP SECONDARY_EXPLICIT_ROUTE Object (SERO)  ...........  38
-19.6        P2MP_SECONDARY_RECORD_ROUTE Object (SRRO)  .............  39
-20          IANA Considerations  ...................................  39
-20.1        New Class Numbers  .....................................  39
-20.2        New Class Types  .......................................  39
-20.3        New Error Codes  .......................................  40
-20.4        LSP Attributes Flags  ..................................  40
-21          Security Considerations  ...............................  41
-22          Acknowledgements  ......................................  41
-23          Appendix  ..............................................  41
-23.1        Example  ...............................................  41
-24          References  ............................................  42
-24.1        Normative References  ..................................  42
-24.2        Informative References  ................................  43
-25          Author Information  ....................................  44
-25.1        Editor Information  ....................................  44
-25.2        Contributor Information  ...............................  45
-26          Intellectual Property  .................................  47
-27          Full Copyright Statement  ..............................  48
-28          Acknowledgement  .......................................  48
+13          Label Allocation on LANs with Multiple Downstream Nodes.  28
+14          P2MP LSP and Sub-LSP Re-optimization  ..................  28
+14.1        Make-before-break  .....................................  28
+14.2        Sub-Group Based Re-optimization  .......................  28
+15          Fast Reroute  ..........................................  29
+15.1        Facility Backup  .......................................  29
+15.2        One to One Backup  .....................................  30
+16          Support for LSRs that are not P2MP Capable  ............  30
+17          Reduction in Control Plane Processing with LSP Hierarchy. 32
+18          P2MP LSP Remerging and Cross-Over  .....................  32
+18.1        Procedures  ............................................  33
+18.1.1      Re-Merge Procedures  ...................................  34
+19          New and Updated Message Objects  .......................  36
+19.1        SESSION Object  ........................................  36
+19.1.1      P2MP LSP Tunnel IPv4 SESSION Object  ...................  36
+19.1.2      P2MP LSP Tunnel IPv6 SESSION Object  ...................  37
+19.2        SENDER_TEMPLATE object  ................................  37
+19.2.1      P2MP LSP Tunnel IPv4 SENDER_TEMPLATE Object  ...........  38
+19.2.2      P2MP LSP Tunnel IPv6 SENDER_TEMPLATE Object  ...........  39
+19.3        <S2L_SUB_LSP> Object  ..................................  40
+19.3.1      <S2L_SUB_LSP> IPv4 Object  .............................  40
+19.3.2      <S2L_SUB_LSP> IPv6 Object  .............................  40
+19.4        FILTER_SPEC Object  ....................................  40
+19.4.1      P2MP LSP_IPv4 FILTER_SPEC Object  ......................  41
+19.4.2      P2MP LSP_IPv4 FILTER_SPEC Object  ......................  41
+19.5        P2MP SECONDARY_EXPLICIT_ROUTE Object (SERO)  ...........  41
+19.6        P2MP SECONDARY_RECORD_ROUTE Object (SRRO)  .............  41
+20          IANA Considerations  ...................................  41
+20.1        New Class Numbers  .....................................  41
+20.2        New Class Types  .......................................  42
+20.3        New Error Codes  .......................................  42
+20.4        LSP Attributes Flags  ..................................  43
+21          Security Considerations  ...............................  43
+22          Acknowledgements  ......................................  43
+23          Appendix  ..............................................  43
+23.1        Example  ...............................................  43
+24          References  ............................................  45
+24.1        Normative References  ..................................  45
+24.2        Informative References  ................................  46
+25          Author Information  ....................................  47
+25.1        Editor Information  ....................................  47
+25.2        Contributor Information  ...............................  47
+26          Intellectual Property  .................................  50
+27          Full Copyright Statement  ..............................  50
+28          Acknowledgement  .......................................  51
 
 1. 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 [KEYWORDS].
 
 2. Terminology
 
    This document uses terminologies defined in [RFC3031], [RFC2205],
    [RFC3209], [RFC3473] and [P2MP-REQ].
 
 3. Introduction
 
-   [RFC3209] defines a mechanism for setting up P2P TE LSPs in MPLS net-
-   works. [RFC3473] defines extensions to [RFC3209] for setting up P2P
-   TE LSPs in GMPLS networks. However these specifications do not pro-
-   vide a mechanism for building P2MP TE LSPs.
+   [RFC3209] defines a mechanism for setting up P2P TE LSPs in MPLS
+   networks. [RFC3473] defines extensions to [RFC3209] for setting up P2P
+   TE LSPs in GMPLS networks. However these specifications do not
+   provide a mechanism for building P2MP TE LSPs.
 
    This document defines extensions to RSVP-TE protocol [RFC3209,
    RFC3473] to support P2MP TE LSPs satisfying the set of requirements
    described in [P2MP-REQ].
 
    This document relies on the semantics of RSVP that RSVP-TE inherits
-   for building P2MP LSPs. A P2MP LSP  is comprised of multiple S2L sub-
-   LSPs. These S2L sub-LSPs are set up between the ingress and egress
+   for building P2MP LSPs. A P2MP LSP  is comprised of multiple S2L
+   sub-LSPs. These S2L sub-LSPs are set up between the ingress and egress
    LSRs and are appropriately combined by the branch LSRs using RSVP
    semantics to result in a P2MP TE LSP. One Path message may signal one
    or multiple S2L sub-LSPs. Hence the S2L sub-LSPs belonging to a P2MP
    LSP can be signaled using one Path message or split across multiple
    Path messages.
 
    Path computation and P2MP application specific aspects are outside of
    the scope of this document.
 
 4. Mechanism
 
    This document describes a solution that optimizes data replication by
    allowing non-ingress nodes in the network to be replication/branch
    nodes. A branch node is a LSR that is capable of replicating the
-   incoming data on two or more outgoing interfaces. The solution uses
-   RSVP-TE in the core of the network for setting up a P2MP TE LSP.
+   incoming data on two or more outgoing interfaces. The solution relies
+   on RSVP-TE in the network for setting up a P2MP TE LSP.
 
    The P2MP TE LSP is set up by associating multiple S2L TE sub-LSPs and
-   relying on data replication at branch nodes. This is described fur-
-   ther in the following sub-sections by describing P2MP Tunnels and how
-   they relate to S2L sub-LSPs.
+   relying on data replication at branch nodes. This is described
+   further in the following sub-sections by describing P2MP Tunnels and
+   how they relate to S2L sub-LSPs.
 
 4.1. P2MP Tunnels
 
    The specific aspect related to P2MP TE LSP is the action required at
-   a branch node, where data replication occurs. For instance, in the
-   MPLS case, incoming labeled data is appropriately replicated to sev-
-   eral outgoing interfaces which may have different labels.
+   a branch node, where data replication occurs. Incoming MPLS labeled
+   data is appropriately replicated to several outgoing interfaces which
+   may have different labels.
 
    A P2MP TE Tunnel comprises of one or more P2MP LSPs. A P2MP TE Tunnel
    is identified by a P2MP SESSION object. This object contains the
    identifier of the P2MP Session which includes the P2MP ID, a tunnel
    ID and an extended tunnel ID.
 
    The fields of a P2MP SESSION object are identical to those of the
    SESSION object defined in [RFC3209] except that the Tunnel Endpoint
    Address field is replaced by the P2MP Identifier (P2MP ID) field.
 
@@ -210,115 +214,112 @@
    ID, and Extended Tunnel ID that are part of the P2MP SESSION object,
    and the tunnel sender address and LSP ID fields of the P2MP
    SENDER_TEMPLATE object. The new P2MP SENDER_TEMPLATE object is
    defined in section 20.2.
 
 4.3. Sub-Groups
 
    As with all other RSVP controlled LSPs, P2MP LSP  state is managed
    using RSVP messages. While use of RSVP messages is the same, P2MP LSP
    state differs from P2P LSP state in a number of ways. The two most
-   notable differences are that a P2MP LSP  comprises multiple S2L Sub-
-   LSPs and that, as a result of this, it may not be possible to repre-
-   sent full state in a single IP datagram and even more likely that it
-   can't fit into a single IP packet. It must also be possible to effi-
-   ciently add and remove endpoints to and from P2MP TE LSPs. An addi-
-   tional issue is that P2MP LSP must also handle the state "remerge"
+   notable differences are that a P2MP LSP  comprises multiple S2L
+   Sub-LSPs and that, as a result of this, it may not be possible to
+   represent full state in a single IP packet and even more likely that it
+   can't fit into a single IP packet. It must also be possible to
+   efficiently add and remove endpoints to and from P2MP TE LSPs. An
+   additional issue is that P2MP LSP must also handle the state "remerge"
    problem, see [P2MP-REQ].
 
    These differences in P2MP state are addressed through the addition of
-   a sub-group identifier (Sub-Group ID) and sub-group originator (Sub-
-   Group Originator ID) to the SENDER_TEMPLATE and FILTER_SPEC objects.
-
-   Taken together the Sub-Group ID and Sub-Group Originator ID are
-   referred to as the Sub-Group fields.
+   a sub-group identifier (Sub-Group ID) and sub-group originator
+   (Sub-Group Originator ID) to the SENDER_TEMPLATE and FILTER_SPEC
+   objects. Taken together the Sub-Group ID and Sub-Group Originator ID
+   are referred to as the Sub-Group fields.
 
    The Sub-Group fields, together with rest of the SENDER_TEMPLATE and
    SESSION objects, are used to represent a portion of a P2MP LSP's
    state.  This portion of a P2MP LSP's state refers only to signaling
    state and not data plane replication or branching. For example, it is
    possible for a node to "branch" signaling state for a P2MP LSP, but
-   to not branch the data associated with the P2MP LSP. Typical applica-
-   tions for generation and use of multiple subgroups are adding an
-   egress and semantic fragmentation to ensure that a Path message
+   to not branch the data associated with the P2MP LSP. Typical
+   applications for generation and use of multiple subgroups are adding
+   an egress and semantic fragmentation to ensure that a Path message
    remains within a single IP packet.
 
 4.4. S2L Sub-LSPs
 
    A P2MP LSP is constituted of one or more S2L sub-LSPs.
 
 4.4.1. Representation of a S2L Sub-LSP
 
    A S2L sub-LSP exists within the context of a P2MP LSP. Thus it is
    identified by the P2MP ID, Tunnel ID, and Extended Tunnel ID that are
    part of the P2MP SESSION, the tunnel sender address and LSP ID fields
    of the P2MP SENDER_TEMPLATE object, and the S2L sub-LSP destination
-   address that is part of the S2L_SUB_LSP object. The S2L_SUB_LSP
+   address that is part of the <S2L_SUB_LSP> object. The <S2L_SUB_LSP>
    object is defined in section 20.3.
 
    An EXPLICIT_ROUTE Object (ERO) or P2MP SECONDARY_EXPLICIT_ROUTE
    Object (SERO) is used to optionally specify the explicit route of a
    S2L sub-LSP. Each ERO or a SERO that is signaled corresponds to a
-   particular S2L_SUB_LSP object. Details of explicit route encoding are
-   specified in section 4.5. The SECONDARY_EXPLICIT_ROUTE Object is
+   particular <S2L_SUB_LSP> object.  Details of explicit route encoding
+   are specified in section 4.5. The SECONDARY_EXPLICIT_ROUTE Object is
    defined in [RECOVERY], a new P2MP SECONDARY_EXPLICIT_ROUTE Object C-
-   type is defined in Section 20.5 and a matching P2MP SEC-
-   ONDARY_RECORD_ROUTE Object C-type is defined in Section 20.6.
+   C-type is defined in Section 20.5 and a matching P2MP
+   SECONDARY_RECORD_ROUTE Object C-type is defined in Section 20.6.
 
 4.4.2. S2L Sub-LSPs and Path Messages
 
    The mechanism in this document allows a P2MP LSP to be signaled using
    one or more Path messages. Each Path message may signal one or more
    S2L sub-LSPs. Support for multiple Path messages is desirable as one
    Path message may not be large enough to fit all the S2L sub-LSPs; and
    they also allow separate manipulation of sub-trees of the P2MP LSP.
    The reason for allowing a single Path message, to signal multiple S2L
    sub-LSPs, is to optimize the number of control messages needed to
    setup a P2MP LSP.
 
 4.5. Explicit Routing
 
    When a Path message signals a single S2L sub-LSP (that is, the Path
    message is only targeting a single leaf in the P2MP tree), the
    EXPLICIT_ROUTE object encodes the path from the ingress LSR to the
-   egress LSR. The Path message also includes the S2L_SUB_LSP object for
-   the S2L sub-LSP being signaled. The < [<EXPLICIT_ROUTE>],
+   egress LSR. The Path message also includes the <S2L_SUB_LSP> object
+   for the S2L sub-LSP being signaled. The < [<EXPLICIT_ROUTE>],
    <S2L_SUB_LSP> > tuple represents the S2L sub-LSP and is referred to
-   as the sub-LSP descriptor.  The absence of the ERO should be inter-
-   preted as requiring hop-by-hop routing for the sub-LSP based on the
-   S2L sub-LSP destination address field of the S2L_SUB_LSP object.
+   as the sub-LSP descriptor.  The absence of the ERO should be
+   interpreted as requiring hop-by-hop routing for the sub-LSP based on
+   the S2L sub-LSP destination address field of the <S2L_SUB_LSP> object.
 
    When a Path message signals multiple S2L sub-LSPs the path of the
    first S2L sub-LSP, from the ingress LSR to the egress LSR, is encoded
    in the ERO. The first S2L sub-LSP is the one that corresponds to the
-   first S2L_SUB_LSP object in the Path message. The S2L sub-LSPs corre-
-   sponding to the S2L_SUB_LSP objects that follow are termed as subse-
-   quent S2L sub-LSPs.  One approach to encode the explicit route of a
-   subsequent S2L sub-LSP is to include all the hops from the ingress to
-   the egress of the S2L sub-LSP. However this implies potential repeti-
-   tion of hops that can be learned from the ERO or explicit routes of
-   other S2L sub-LSPs. Explicit route compression using SEROs attempts
-   to minimize such repetition.
+   first <S2L_SUB_LSP> object in the Path message. The S2L sub-LSPs
+   coresponding to the <S2L_SUB_LSP> objects that follow are termed as
+   subsequent S2L sub-LSPs.  In order to avoid the potential repetition
+   of path information for the parts of S2L sub-LSPs that share hops,
+   this information is deduced from the explicit routes of other S2L
+   sub-LSPs using explicit route compression in SEROs.
 
-   The path of each subsequent S2L sub-LSP is encoded in a P2MP SEC-
-   ONDARY_EXPLICIT_ROUTE object (SERO). The format of the SERO is the
+   The path of each subsequent S2L sub-LSP is encoded in a P2MP
+   SECONDARY_EXPLICIT_ROUTE object (SERO). The format of the SERO is the
    same as an ERO (as defined in [RFC3209]). Each subsequent S2L sub-LSP
    is represented by tuples of the form < [<P2MP SEC-
-   ONDARY_EXPLICIT_ROUTE>] <S2L_SUB_LSP> >. There is a one to one corre-
-   spondence between a S2L_SUB_LSP object and a SERO. A SERO for a par-
-   ticular S2L sub-LSP includes only the path from a certain branch LSR
-   to the egress LSR if the path to that branch LSR can be derived from
-   the ERO or other SEROs. The absence of a SERO should be interpreted
-   as requiring hop-by-hop routing for that S2L sub-LSP. Note that the
-   destination address is carried in the S2L sub-LSP object. The encod-
-   ing of the SERO and S2L sub-LSP object are described in detail in
-   section 20.
+   ONDARY_EXPLICIT_ROUTE>] <S2L_SUB_LSP> >. There is a one to one
+   correspondence between a <S2L_SUB_LSP> object and a SERO. A SERO for a
+   particular S2L sub-LSP includes only the path from a certain branch
+   LSR to the egress LSR if the path to that branch LSR can be derived
+   from the ERO or other SEROs. The absence of a SERO should be
+   interpreted as requiring hop-by-hop routing for that S2L sub-LSP. Note
+   that the destination address is carried in the S2L sub-LSP object.
+   The encoding of the SERO and <S2L_SUB_LSP> object are described in
+   detail in section 20.
 
    Explicit route compression is illustrated using the following figure.
 
                                     A
                                     |
                                     |
                                     B
                                     |
                                     |
                           C----D----E
@@ -330,61 +331,62 @@
                                J    K   L   M
                                |    |   |   |
                                |    |   |   |
                                N    O   P   Q--R
 
                         Figure 1. Explicit Route Compression
 
    Figure 1. shows a P2MP LSP with LSR A as the ingress LSR and six
    egress LSRs: (F, N, O, P, Q and R). When all the six S2L sub-LSPs are
    signaled in one Path message let us assume that the S2L sub-LSP to
-   LSR F is the first S2L sub-LSP and the rest are subsequent S2L sub-
-   LSPs. Following is one way for the ingress LSR A to encode the S2L
+   LSR F is the first S2L sub-LSP and the rest are subsequent S2L
+   sub-LSPs. Following is one way for the ingress LSR A to encode the S2L
    sub-LSP explicit routes using compression:
 
-      S2L sub-LSP-F:   ERO = {B, E, D, C, F},  S2L_SUB_LSP Object-F
-      S2L sub-LSP-N:   SERO = {D, G, J, N}, S2L_SUB_LSP Object-N
-      S2L sub-LSP-O:   SERO = {E, H, K, O}, S2L_SUB_LSP Object-O
-      S2L sub-LSP-P:   SERO = {H, L, P}, S2L_SUB_LSP Object-P,
-      S2L sub-LSP-Q:   SERO = {H, I, M, Q}, S2L_SUB_LSP Object-Q,
-      S2L sub-LSP-R:   SERO = {Q, R}, S2L_SUB_LSP Object-R,
+      S2L sub-LSP-F:   ERO = {B, E, D, C, F},  <S2L_SUB_LSP> object-F
+      S2L sub-LSP-N:   SERO = {D, G, J, N}, <S2L_SUB_LSP> object-N
+      S2L sub-LSP-O:   SERO = {E, H, K, O}, <S2L_SUB_LSP> object-O
+      S2L sub-LSP-P:   SERO = {H, L, P}, <S2L_SUB_LSP> object-P,
+      S2L sub-LSP-Q:   SERO = {H, I, M, Q}, <S2L_SUB_LSP> object-Q,
+      S2L sub-LSP-R:   SERO = {Q, R}, <S2L_SUB_LSP> object-R,
 
    After LSR E processes the incoming Path message from LSR B it sends a
    Path message to LSR D with the S2L sub-LSP explicit routes encoded as
    follows:
 
-      S2L sub-LSP-F:   ERO = {D, C, F},  S2L_SUB_LSP Object-F
-      S2L sub-LSP-N:   SERO = {D, G, J, N}, S2L_SUB_LSP Object-N
+      S2L sub-LSP-F:   ERO = {D, C, F},  <S2L_SUB_LSP> object-F
+      S2L sub-LSP-N:   SERO = {D, G, J, N}, <S2L_SUB_LSP> object-N
 
    LSR E also sends a Path message to LSR H and following is one way to
    encode the S2L sub-LSP explicit routes using compression:
 
-      S2L sub-LSP-O:   ERO = {H, K, O}, S2L_SUB_LSP Object-O
-      S2L sub-LSP-P:   SERO = {H, L, P}, S2L_SUB_LSP Object-P,
-      S2L sub-LSP-Q:   SERO = {H, I, M, Q}, S2L_SUB_LSP Object-Q,
-      S2L sub-LSP-R:   SERO = {Q, R}, S2L_SUB_LSP Object-R,
+      S2L sub-LSP-O:   ERO = {H, K, O}, <S2L_SUB_LSP> object-O
+      S2L sub-LSP-P:   SERO = {H, L, P}, S2L_SUB_LSP object-P,
+      S2L sub-LSP-Q:   SERO = {H, I, M, Q}, <S2L_SUB_LSP> object-Q,
+      S2L sub-LSP-R:   SERO = {Q, R}, <S2L_SUB_LSP> object-R,
 
    After LSR H processes the incoming Path message from E it sends a
    Path message to LSR K, LSR L and LSR I. The encoding for the Path
    message to LSR K is as follows:
 
-      S2L sub-LSP-O:   ERO  = {K, O}, S2L_SUB_LSP Object-O
-   The encoding of the Path message sent by LSR H to LSR L is as fol-
-   lows:
+      S2L sub-LSP-O:   ERO  = {K, O}, <S2L_SUB_LSP> object-O
 
-      S2L sub-LSP-P:   ERO = {L, P}, S2L_SUB_LSP Object-P,
+   The encoding of the Path message sent by LSR H to LSR L is as
+   follows:
+
+      S2L sub-LSP-P:   ERO = {L, P}, <S2L_SUB_LSP> object-P,
 
    Following is one way for LSR H to encode the S2L sub-LSP explicit
    routes in the Path message sent to LSR I:
 
-      S2L sub-LSP-Q:   ERO = {I, M, Q}, S2L_SUB_LSP Object-Q,
-      S2L sub-LSP-R:   SERO = {Q, R}, S2L_SUB_LSP Object-R,
+      S2L sub-LSP-Q:   ERO = {I, M, Q}, <S2L_SUB_LSP> object-Q,
+      S2L sub-LSP-R:   SERO = {Q, R}, <S2L_SUB_LSP> object-R,
 
    The explicit route encodings in the Path messages sent by LSRs D and
    Q are left as an exercise to the reader.
 
    This compression mechanism reduces the Path message size. It also
    reduces extra processing that can result if explicit routes are
    encoded from ingress to egress for each S2L sub-LSP. No assumptions
    are placed on the ordering of the subsequent S2L sub-LSPs and hence
    on the ordering of the SEROs in the Path message. All LSRs need to
    process the ERO corresponding to the first S2L sub-LSP. A LSR needs
@@ -421,128 +422,130 @@
    Following is the format of the S2L sub-LSP descriptor list.
 
    <S2L sub-LSP descriptor list> ::= <S2L sub-LSP descriptor>
                                      [ <S2L sub-LSP descriptor list> ]
 
    <S2L sub-LSP descriptor> ::= <S2L_SUB_LSP> [ <P2MP SEC-
    ONDARY_EXPLICIT_ROUTE> ]
 
    Each LSR MUST use the common objects in the Path message and the S2L
    sub-LSP descriptors to process each S2L sub-LSP represented by the
-   S2L sub-LSP object and the SUB-/EXPLICIT_ROUTE object combination.
+   <S2L_SUB_LSP> object and the SECONDARY-/EXPLICIT_ROUTE object
+   combination.
 
-   The first S2L_SUB_LSP object's explicit route is specified by the
+   The first <S2L_SUB_LSP> object's explicit route is specified by the
    ERO. Explicit routes of subsequent S2L sub-LSPs are specified by the
-   corresponding SERO. A SERO corresponds to the following S2L_SUB_LSP
+   corresponding SERO. A SERO corresponds to the following <S2L_SUB_LSP>
    object.
 
    The RRO in the sender descriptor contains the hops traversed by the
    Path message and applies to all the S2L sub-LSPs signaled in the Path
    message.
 
    Path message processing is described in the next section.
 
 5.2. Path Message Processing
 
-   The ingress-LSR initiates the set up of a S2L sub-LSP to each egress-
+   The ingress-LSR initiates the set up of a S2L sub-LSP to each egress
    LSR that is the destination of the P2MP LSP. Each S2L sub-LSP is
    associated with the same P2MP LSP using common P2MP SESSION object
-   and <Source Address, LSP-ID> fields in the P2MP SENDER_TEMPLATE
+   and <Sender Address, LSP-ID> fields in the P2MP SENDER_TEMPLATE
    object.  Hence it can be combined with other S2L sub-LSPs to form a
    P2MP LSP.  Another S2L sub-LSP belonging to the same instance of this
    S2L sub-LSP (i.e.  the same P2MP LSP) shares resources with this S2L
-   sub-LSP. The session corresponding to the P2MP TE tunnel is deter-
-   mined based on the P2MP SESSION object. Each S2L sub-LSP is identi-
-   fied using the S2L_SUB_LSP object. Explicit routing for the S2L sub-
-   LSPs is achieved using the ERO and SEROs.
+   sub-LSP. The session corresponding to the P2MP TE tunnel is
+   determined based on the P2MP SESSION object. Each S2L sub-LSP is
+   identified using the <S2L_SUB_LSP> object. Explicit routing for the S2L
+   sub-LSPs is achieved using the ERO and SEROs.
 
    As mentioned earlier, it is possible to signal S2L sub-LSPs for a
    given P2MP LSP in one or more Path messages. And a given Path message
    can contain one or more S2L sub-LSPs. A LSR that supports RSVP-TE
    signaled P2MP LSPs MUST be able to receive and process multiple Path
    messages for the same P2MP LSP and multiple S2L sub-LSPs in one Path
    message. This implies that a LSR MUST be able to receive and process
    all objects listed in section 20.
 
 5.2.1. Multiple Path Messages
 
-   As described in section 3, either the <EXPLICIT_ROUTE> <S2L SUB-LSP>
+   As described in section 3, either the <EXPLICIT_ROUTE> <S2L_SUB_LSP>
    or the <P2MP SECONDARY_EXPLICIT_ROUTE> <S2L_SUB_LSP> tuple is used to
    specify a S2L sub-LSP. Multiple Path messages can be used to signal a
    P2MP LSP. Each Path message can signal one or more S2L sub-LSPs. If a
    Path message contains only one S2L sub-LSP, each LSR along the S2L
    sub-LSP follows [RFC3209] procedures for processing the Path message
-   besides the S2L SUB-LSP object processing described in this document.
+   besides the <S2L_SUB_LSP> object processing described in this docu-
+   ment.
 
    Processing of Path messages containing more than one S2L sub-LSP is
    described in Section 5.2.2.
 
    An ingress LSR may use multiple Path messages for signaling a P2MP
    LSP.  This may be because a single Path message may not be large
    enough to signal the P2MP LSP. Or it may be while adding leaves to
    the P2MP LSP the new leaves are signaled in a new Path message. Or an
-   ingress LSR MAY choose to break the P2MP tree into separate manage-
-   able P2MP trees.  These trees share the same root and may share the
-   trunk and certain branches.  The scope of this management decomposi-
-   tion of P2MP trees is bounded by a single tree (the P2MP Tree) and
-   multiple trees with a single leaf each (S2L sub-LSPs).  Per [P2MP-
-   REQ], a P2MP LSP MUST have consistent attributes across all portions
-   of a tree. This implies that each Path message that is used to signal
-   a P2MP LSP is signaled using the same signaling attributes with the
-   exception of the S2L sub-LSP information.
+   ingress LSR MAY choose to break the P2MP tree into separate
+   manageable P2MP trees.  These trees share the same root and may share the
+   trunk and certain branches.  The scope of this management
+   decomposition of P2MP trees is bounded by a single tree (the P2MP Tree)
+   and multiple trees with a single leaf each (S2L sub-LSPs).  Per
+   [P2MP-REQ], a P2MP LSP MUST have consistent attributes across all
+   portions of a tree. This implies that each Path message that is used
+   to signal a P2MP LSP is signaled using the same signaling attributes
+   with the exception of the S2L sub-LSP information.
 
    The resulting sub-LSPs from the different Path messages belonging to
    the same P2MP LSP SHOULD share labels and resources where they share
    hops to prevent multiple copies of the data being sent.
 
    In certain cases a transit LSR may need to generate multiple Path
-   messages to signal state corresponding to a single received Path mes-
-   sage. For instance ERO expansion may result in an overflow of the
+   messages to signal state corresponding to a single received Path
+   message. For instance ERO expansion may result in an overflow of the
    resultant Path message. In this case the message can be decomposed
    into multiple Path messages such that each of the messages carry a
    subset of the X2L sub-tree carried by the incoming message.
 
    Multiple Path messages generated by a LSR that signal state for the
    same P2MP LSP are signaled with the same SESSION object and have the
    same <Source address, LSP-ID> in the SENDER_TEMPLATE object. In order
-   to disambiguate these Path messages a <Sub-Group Originator ID, sub-
-   Group ID> tuple is introduced (also referred to as the Sub-Group
-   field) and encoded in the SENDER_TEMPLATE object. Multiple Path mes-
-   sages generated by a LSR to signal state for the same P2MP LSP have
-   the same Sub-Group Originator ID and have a different sub-Group ID.
-   The Sub-Group Originator ID SHOULD be set to the TE Router ID of the
-   LSR that originates the Path message. This is either the ingress LSR
-   or a LSR which re-originates the Path message with its own Sub-Group
+   to disambiguate these Path messages a <Sub-Group Originator ID,
+   sub-Group ID> tuple is introduced (also referred to as the Sub-Group
+   field) and encoded in the SENDER_TEMPLATE object. Multiple Path
+   messages generated by a LSR to signal state for the same P2MP LSP
+   have the same Sub-Group Originator ID and have a different sub-Group
+   ID. The Sub-Group Originator ID SHOULD be set to the TE Router ID of
+   the LSR that originates the Path message. This is either the ingress
+   LSR or a LSR which re-originates the Path message with its own Sub-Group
    Originator ID. Cases when a transit LSR may change the Sub-Group
    Originator ID of an incoming Path message are described below. The
    <Sub-Group Originator ID, sub-Group ID> tuple is globally unique. The
-   sub-Group ID space is specific to the Sub-Group Originator ID. There-
-   fore the combination <Sub-Group Originator ID, sub-Group ID> is net-
-   work-wide unique. Also, a router that changes the Sub-Group origina-
-   tor ID of an incoming Path message MUST use the same value of the
-   Sub-Group Originator ID for all outgoing Path messages, for a partic-
-   ular P2MP LSP, and SHOULD not vary it during the life of the P2MP
-   LSP.
+   sub-Group ID space is specific to the Sub-Group Originator ID.
+   Therefore the combination <Sub-Group Originator ID, sub-Group ID> is
+   network-wide unique. Also, a router that changes the Sub-Group
+   originator ID of an incoming Path message MUST use the same value of
+   the Sub-Group Originator ID for all outgoing Path messages, for a
+   particular P2MP LSP, and SHOULD not vary it during the life of the
+   P2MP LSP.
 
 5.2.2. Multiple S2L Sub-LSPs in one Path message
 
    The S2L sub-LSP descriptor list allows the signaling of one or more
    S2L sub-LSPs in one Path message. It is possible to signal multiple
-   S2L sub-LSP object and ERO/SERO combinations in a single Path mes-
+   <S2L_SUB_LSP> object and ERO/SERO combinations in a single Path mes-
    sage. Note that these two objects are the ones that differentiate a
    S2L sub-LSP.
 
    All LSRs MUST process the ERO corresponding to the first S2L sub-LSP
    when the ERO is present. If one or more SEROs are present an ERO MUST
-   be present.  The first S2L sub-LSP MUST be propagated in a Path mes-
-   sage by each LSR along the explicit route specified by the ERO. A LSR
-   MUST process a S2L sub-LSP descriptor for a subsequent S2L sub-LSP
+   be present.  The first S2L sub-LSP MUST be propagated in a Path
+   message by each LSR along the explicit route specified by the ERO. A
+   LSR MUST process a S2L sub-LSP descriptor for a subsequent S2L sub-LSP
    only if the first hop in the corresponding SERO is a local address of
    that LSR. If this is not the case the S2L sub-LSP descriptor MUST be
    included in the Path message sent to LSR that is the next hop to
    reach the first hop in the SERO. This next hop is determined by using
    the ERO or other SEROs that encode the path to the SERO's first hop.
    If this is the case and the LSR is also the egress, the S2L sub-LSP
    descriptor MUST NOT be propagated downstream. If this is the case and
    the LSR is not the egress the S2L sub-LSP descriptor MUST be included
    in a Path message sent to the next-hop determined from the SERO.
    Hence a branch LSR MUST only propagate the relevant S2L sub-LSP
@@ -550,108 +553,109 @@
    that is propagated on a downstream link MUST only contain those S2L
    sub-LSPs that are routed using that link. This processing MAY result
    in a subsequent S2L sub-LSP in an incoming Path message to become the
    first S2L sub-LSP in an outgoing Path message.
 
    Note that if one or more SEROs contain loose hops, expansion of such
    loose hops MAY result in overflowing the Path message size. Section
    5.2.3 describes how signaling of the set of S2L sub-LSPs can be split
    in more than one Path message.
 
-   The Record Route Object (RRO) contains the hops traversed by the Path
-   message and applies to all the S2L sub-LSPs signaled in the path mes-
-   sage. A transit LSR MUST append its address in an incoming RRO and
+   The RECORD_ROUTE Object (RRO) contains the hops traversed by the Path
+   message and applies to all the S2L sub-LSPs signaled in the path
+   message. A transit LSR MUST append its address in an incoming RRO and
    propagate it downstream. A branch LSR MUST form a new RRO for each of
    the outgoing Path messages. Each such updated RRO MUST be formed
    using the rules in [RFC3209].
 
    If a LSR is unable to support a S2L sub-LSP in a Path message, a
    PathErr message MUST be sent for the impacted S2L sub-LSP, and normal
    processing of the rest of the P2MP LSP SHOULD continue. The default
    behavior is that the remainder of the LSP is not impacted (that is,
    all other branches are allowed to set up) and the failed branches are
    reported in PathErr messages in which the Path_State_Removed flag
    MUST NOT be set. However, the ingress LSR may set a LSP Integrity
    flag to request that if there is a setup failure on any branch the
-   entire LSP should fail to set up. This is described further in sec-
-   tion 12.
+   entire LSP should fail to set up. This is described further in
+   section 12.
 
 5.2.3. Transit Fragmentation
 
    In certain cases a transit LSR may need to generate multiple Path
-   messages to signal state corresponding to a single received Path mes-
-   sage. For instance ERO expansion may result in an overflow of the
-   resultant Path message. It is desirable not to rely on IP fragmenta-
-   tion in this case. In order to achieve this, the multiple Path mes-
-   sages generated by the transit LSR, are signaled with the Sub-Group
+   messages to signal state corresponding to a single received Path
+   message. For instance ERO expansion may result in an overflow of the
+   resultant Path message. It is desirable not to rely on IP
+   fragmentation in this case. In order to achieve this, the multiple Path
+   messages generated by the transit LSR, are signaled with the Sub-Group
    Originator ID set to the TE Router ID of the transit LSR and a dis-
    tinct sub-Group ID. Thus each distinct Path message that is generated
    by the transit LSR for the P2MP LSP carries a distinct <Sub-Group
    Originator ID, Sub-Group ID> tuple.
 
    When multiple Path messages are used by an ingress or transit node,
    each Path message SHOULD be identical with the exception of the S2L
    sub-LSP related information (e.g., SERO), message and hop information
    (e.g., INTEGRITY, MESSAGE_ID and RSVP_HOP), and the sub-group fields
    of the SENDER_TEMPLATE objects. Except when performing a  make-
-   before-break operation, the tunnel sender address and LSP ID fields
-   MUST be the same in each message, and for transit nodes, the same as
-   the values in the received Path message.
+   before-break operation as specified in section 14.1, the tunnel
+   sender address and LSP ID fields MUST be the same in each message,
+   and for transit nodes, the same as the values in the received Path
+   message.
 
    As described above one case in which the Sub-Group Originator ID of a
    received Path message is changed is that of transit fragmentation.
-   The Sub-Group Originator ID of a received Path message may also be
-   changed in the outgoing Path message and set to that of the LSR orig-
-   inating the Path message based on a local policy. For instance a LSR
-   may decide to always change the Sub-Group Originator ID while per-
-   forming ERO expansion. The Sub-Group ID MUST not be changed if the
-   Sub-Group Originator ID is not being changed.
+   Another case is when the Sub-Group Originator ID of a received Path
+   message may be changed in the outgoing Path message and set to that
+   of the LSR originating the Path message based on a local policy. For
+   instance a LSR may decide to always change the Sub-Group Originator
+   ID while performing ERO expansion. The Sub-Group ID MUST not be
+   changed if the Sub-Group Originator ID is not being changed.
 
 5.2.4. Control of Branch Fate Sharing
 
-   An ingress LSR can control the behavior of an LSP if there is a fail-
-   ure during LSP setup or after an LSP has been established. The
+   An ingress LSR can control the behavior of an LSP if there is a
+   failure during LSP setup or after an LSP has been established. The
    default behavior is that only the branches downstream of the failure
    are not established, but the ingress may request 'LSP integrity' such
    that any failure anywhere within the LSP tree causes the entire P2MP
    LSP to fail.
 
    The ingress LSP may request 'LSP integrity' by setting bit [TBA] of
    the Attributes Flags TLV. The bit is set if LSP integrity is
    required.
 
    It is RECOMMENDED to use the LSP_ATTRIBUTES Object for this flag and
    not the LSP_REQUIRED_ATTRIBUTES Object.
 
    A branch LSR that supports the Attributes Flags TLV and recognizes
    this bit MUST support LSP integrity or reject the LSP setup with a
-   PathErr carrying the error "Routing Error"/"Unsupported LSP
+   PathErr message carrying the error "Routing Error"/"Unsupported LSP
    Integrity"
 
 5.3. Grafting
 
    The operation of adding egress LSR(s) to an existing P2MP LSP is
    termed as grafting. This operation allows egress nodes to join a P2MP
    LSP at different points in time.
 
    There are two methods to add S2L sub-LSPs to a P2MP LSP.  The first
    is to add new S2L sub-LSPs to the P2MP LSP by adding them to an
    existing Path message and refreshing the entire Path message. Path
    message processing described in section 4 results in adding these S2L
    sub-LSPs to the P2MP LSP. Note that as a result of adding one or more
    S2L sub-LSPs to a Path message the ERO compression encoding may have
    to be recomputed.
 
    The second is to use incremental updates described in section 10.1.
-   The egress LSRs can be added by signaling only the impacted S2L sub-
-   LSPs in a new Path message. Hence other S2L sub-LSPs do not have to
-   be re-signaled.
+   The egress LSRs can be added by signaling only the impacted S2L
+   sub-LSPs in a new Path message. Hence other S2L sub-LSPs do not have
+   to be re-signaled.
 
 6. Resv Message
 
 6.1. Resv Message Format
 
    The Resv message follows the [RFC3209] and [RFC3473] format:
 
    <Resv Message> ::=    <Common Header> [ <INTEGRITY> ]
                          [ [<MESSAGE_ID_ACK> | <MESSAGE_ID_NACK>] ... ]
                          [ <MESSAGE_ID> ]
@@ -681,35 +685,35 @@
    <FF flow descriptor> ::= [ <FLOWSPEC> ] <FILTER_SPEC> <LABEL>
                             [ <RECORD_ROUTE> ] [ <S2L sub-LSP descriptor
    list> ]
 
    <SE filter spec> ::=     <FILTER_SPEC> <LABEL> [ <RECORD_ROUTE> ]
                             [ <S2L sub-LSP descriptor list> ]
 
    <S2L sub-LSP descriptor list> ::= <S2L sub-LSP descriptor>
                                      [ <S2L sub-LSP descriptor list> ]
 
-   <S2L sub-LSP descriptor> ::= <S2L_SUB_LSP> [ <P2MP SEC-
-   ONDARY_EXPLICIT_ROUTE> ]
+   <S2L sub-LSP descriptor> ::= <S2L_SUB_LSP> [ <P2MP
+   SECONDARY_EXPLICIT_ROUTE> ]
    FILTER_SPEC is defined in section 20.4.
 
    The S2L sub-LSP descriptor has the same format as in section 4.1 with
    the difference that a P2MP_SECONDARY_RECORD_ROUTE object is used in
    place of a P2MP SECONDARY_EXPLICIT_ROUTE object. The P2MP_SEC-
    ONDARY_RECORD_ROUTE objects follow the same compression mechanism as
-   the P2MP SECONDARY_EXPLICIT_ROUTE objects. Note that that a Resv mes-
-   sage can signal multiple S2L sub-LSPs that may belong to the same
+   the P2MP SECONDARY_EXPLICIT_ROUTE objects. Note that that a Resv
+   message can signal multiple S2L sub-LSPs that may belong to the same
    FILTER_SPEC object or different FILTER_SPEC objects. The same label
-   SHOULD be allocated if the <Source Address, LSP-ID> fields of the
+   SHOULD be allocated if the <Sender Address, LSP-ID> fields of the
    FILTER_SPEC object are the same.
 
-   However different upstream labels are allocated if the <Source
+   However different upstream labels are allocated if the <Sender
    Address, LSP-ID> of the FILTER_SPEC object is different as that
    implies different P2MP LSP.
 
 6.2. Resv Message Processing
 
    The egress LSR MUST follow normal RSVP procedures while originating a
    Resv message. The Resv message carries the label allocated by the
    egress LSR.
 
    A subsequent node MUST allocates its own label and pass it in the
@@ -730,118 +734,122 @@
    from downstream Resv messages for that P2MP LSP. Note that a transit
    node may become a replication point in the future when a branch is
    attached to it.  Hence this results in the setup of a P2MP LSP from
    the ingress-LSR to the egress LSRs.
 
    The ingress LSR may need to understand when all desired egresses have
    been reached. This is achieved using <S2L_SUB_LSP> objects.
 
    Each branch node can potentially send one Resv message upstream for
    each of the downstream receivers. This MAY result in overflowing the
-   Resv message, particularly when considering that the number of mes-
-   sages increases the closer the branch node is to the ingress.
+   Resv message, particularly when considering that the number of
+   messages increases the closer the branch node is to the ingress of
+   the P2MP LSP.
 
    Transit nodes MUST replace the Sub-Group ID fields received in the
    FILTER_SPEC objects with the value that was received in the Sub-Group
    ID field of the Path message from the upstream neighbor, when the
    node set the Sub-Group Originator field in the associated Path mes-
    sage.  ResvErr messages generation is unmodified.  Nodes propagating
-   a received ResvErr message MUST use the Sub-Group field values car-
-   ried in the corresponding Resv message.
+   a received ResvErr message MUST use the Sub-Group field values
+   carried in the corresponding Resv message.
 
 6.2.1. Resv Message Throttling
 
    A branch node may have to send the Resv message being sent upstream
    whenever there is a change in a Resv message for a S2L sub-LSP
-   received from downstream. This can result in excessive Resv messages
-   sent upstream, particularly when the S2L sub-LSPs are established for
-   the first time.  In order to mitigate this situation, branch nodes
-   can limit their transmission of Resv messages. Specifically, in the
-   case where the only change being sent in a Resv message is in one or
-   more SRRO objects, the branch node SHOULD transmit the Resv message
-   only after a delay time has passed since the transmission of the pre-
-   vious Resv message for the same session. This delayed Resv message
-   SHOULD include SRROs for all branches. Specific mechanisms for Resv
-   message throttling are implementation dependent and are outside the
-   scope of this document.
+   received from one of the downstream neighbors. This can result in
+   excessive Resv messages sent upstream,particularly when the S2L
+   sub-LSPs are established for the first time. In order to mitigate
+   this situation, branch nodes can limit their transmission of Resv mes-
+   sages. Specifically, in the case where the only change being sent in
+   a Resv message is in one or more SRRO objects, the branch node SHOULD
+   transmit the Resv message only after a delay time has passed since
+   the transmission of the previous Resv message for the same session.
+   This delayed Resv message SHOULD include SRROs for all branches.
+   Specific mechanisms for Resv message throttling are implementation
+   dependent and are outside the scope of this document.
 
 6.3. Record Routing
 
 6.3.1. RRO Processing
 
    A Resv message contains a record route per S2L sub-LSP that is being
    signaled by the Resv message if the sender node requests route
    recording by including a RRO in the Path message. The same rule is
    used during signaling of P2MP LSP i.e. insertion of the RRO in the
    Path message used to signal one or more S2L sub-LSP triggers the
    inclusion of an RRO for each sub-LSP.
 
    The record route of the first S2L sub-LSP is encoded in the RRO.
    Additional RROs for the subsequent S2L sub-LSPs are referred to as
    P2MP_SECONDARY_RECORD_ROUTE objects (SRROs). Their format is speci-
    fied in section 20.5. The ingress node then receives the RRO and
    possibly the SRRO  corresponding to each subsequent S2L sub-LSP. Each
-   S2L_SUB_LSP object is followed by the RRO/SRRO. The ingress node can
-   then determine the record route corresponding to a particular S2L
+   <S2L_SUB_LSP> object is followed by the RRO/SRRO. The ingress node
+   can then determine the record route corresponding to a particular S2L
    sub-LSP. The RRO and SRROs can be used to construct the end to end
    Path for each S2L sub-LSP.
 
 6.4. Reservation Style
 
    Considerations about the reservation style in a Resv message apply as
    described in [RFC3209]. The reservation style in the Resv messages
    can either be FF or SE. All P2MP LSP that belong to the same P2MP
    Tunnel MUST be signaled with the same reservation style. Irrespective
    of whether the reservation style is FF or SE, the S2L sub-LSPs that
    belong to the same P2MP LSP SHOULD share labels where they share
    hops. If the S2L sub-LSPs that belong to the same P2MP LSP share
    labels then they MUST share resources. The S2L sub-LSPs that belong
    to different P2MP LSP MUST NOT share labels. If the reservation style
-   is FF than S2L Sub-LSPs that belong to different P2MP LSP MUST NOT
+   is FF than S2L sub-LSPs that belong to different P2MP LSP MUST NOT
    share resources. If the reservation style is SE than S2L sub-LSPs
    that belong to different P2MP LSP and the same P2MP Tunnel SHOULD
    share resources where they share hops, but MUST not share labels.
 
 7. PathTear Message
 
 7.1. PathTear Message Format
 
    The format of the PathTear message is as follows:
 
    <PathTear Message> ::= <Common Header> [ <INTEGRITY> ]
                            [ [ <MESSAGE_ID_ACK> |
                                <MESSAGE_ID_NACK> ... ]
                            [ <MESSAGE_ID> ]
                            <SESSION> <RSVP_HOP>
                            [ <sender descriptor> ]
-                           [ <S2L sub-LSP descriptor list> ]
+                           [ <S2L sub-LSP list> ]
 
-                 <sender descriptor> ::= (see earlier definition)
+   <S2L sub-LSP list> ::= <S2L_SUB_LSP> [ <S2L sub-LSP list> ]
+
+   The definition of <sender descriptor> is not changed by this docu-
+   ment.
 
    Note: it is assumed that the S2L sub-LSP descriptor will not include
-   the P2MP SECONDARY_EXPLICIT_ROUTE object associated with each
-   S2L_SUB_LSP being deleted
+   the P2MP SECONDARY_EXPLICIT_ROUTE object associated with each S2L
+   sub-LSP being deleted.
 
 7.2. Pruning
 
    The operation of removing egress LSR(s) from an existing P2MP LSP is
    termed as pruning. This operation allows egress nodes to be removed
    from a P2MP LSP at different points in time. This section describes
    the mechanisms to perform pruning.
 
 7.2.1. Implicit S2L Sub-LSP Teardown
 
    Implicit teardown uses standard RSVP message processing. Per standard
    RSVP processing, a S2L sub-LSP may be removed from a P2MP TE LSP by
    sending a modified message for the Path or Resv message that previ-
-   ously advertised the S2L sub-LSP. This message MUST list all S2L sub-
-   LSPs that are not being removed. When using this approach, a node
+   ously advertised the S2L sub-LSP. This message MUST list all S2L
+   sub-LSPs that are not being removed. When using this approach, a node
    processing a message that removes a S2L sub-LSP from a P2MP TE LSP
    MUST ensure that the S2L sub-LSP is not included in any other Path
    state associated with session before interrupting the data path to
    that egress.  All other message processing remains unchanged.
 
    When implicit teardown is used to delete one or more S2L sub-LSPs, by
    modifying a Path message, a transit LSR may have to generate a
    PathTear message downstream to delete one or more of these S2L sub-
    LSPs. This can happen if as a result of the implicit deletion of S2L
    sub-LSP(s) there are no remaining S2L sub-LSPs to send in the corre-
@@ -865,68 +873,141 @@
    in the PathTear message.  The transit LSR may need to generate multi-
    ple PathTear messages for an incoming PathTear message if it had per-
    formed transit fragmentation for the corresponding incoming Path mes-
    sage.
 
    When a P2MP LSP is removed by the ingress, a PathTear message MUST be
    generated for each Path message used to signal the P2MP LSP.
 
 8. Notify and ResvConf Messages
 
-   This section is currently under discussion between the authors and
-   will be updated in the next revision.
+8.1. Notify Messages
 
-   Notify Request and Notify messages are described in [RFC3473].  If a
-   transit router sets the sub-group originator ID in the SENDER_TEM-
-   PLATE object of a Path message to its own address and the Path mes-
-   sage carries a Notify Request object then the router MUST set the
-   notify node address in the Notify Request object to its own address.
-   If this router receives a corresponding Notify message from down-
-   stream than it MUST generate a Notify message upstream towards the
-   Notify node address that the router had received in the incoming Path
-   message. The receiver of a Notify message MUST identify the sender
-   state referenced in the message based on the SESSION and SENDER_TEM-
-   PLATE objects.
+   The Notify Request object and Notify messages are described in
+   [RFC3473]. Both object and messages SHALL be supported for delivery
+   of upstream and downstream notification. Processing not detailed in
+   this section MUST comply to [RFC3473].
 
-   ResvConf messages are described in [RFC2205]. An egress LSR may
-   include a RESV_CONFIRM object that contains the egress LSR's address.
-   If a transit LSR is merging Resv messages received from more than
-   egress LSR and one or more of these Resv messages contain a RESV_CON-
-   FIRM object than the transit LSR MUST set its own address in the
-   RESV_CONFIRM object in the Resv message that it generates. Also if
-   the transit LSR changes the sub-group originator ID in the generated
-   Resv message and it includes a RESV_CONFIRM object in the Resv mes-
-   sage, it MUST set its own address in the RESV_CONFIRM object.  Upon
-   receiving a ResvConf message from upstream the transit LSR MUST gen-
-   erate a ResvConf message towards each of the downstream LSRs that had
-   included RESV_CONFIRM objects in the corresponding Resv messages.  As
-   with Notify messages, the receiver of a ResvConf message MUST iden-
-   tify the state referenced in the message based on the SESSION and
-   FILTER_SPEC objects.
+   1. Upstream Notification
+
+   If a transit LSR sets the Sub-Group Originator ID in the
+   SENDER_TEMPLATE object of a Path message to its own address and the
+   incoming Path message carries a Notify Request object then this LSR
+   MUST change the Notify node address in the Notify Request object to
+   its own address in the Path message that it sends.
+
+   If this router subsequently receives a corresponding Notify message
+   from a downstream LSR than it MUST:
+
+   - send a Notify message upstream toward the Notify
+     node address that the LSR received in the Path message.
+   - process the sub-group fields of the SENDER_TEMPLATE
+     object on the received Notify message, and modify their values
+     in the Notify message that is forwarded to match the sub-group
+     field values in the original Path message received from upstream.
+
+   The receiver of an (upstream) Notify message MUST identify the state
+   referenced in this message based on the SESSION and SENDER_TEMPLATE.
+
+   2. Downstream Notification
+
+   A transit LSR sets the Sub-Group Originator ID in the FILTER_SPEC
+   object(s) of a Resv message to the value, that was received in the
+   corresponding Path message. If the incoming Resv message carries a
+   Notify Request object then the LSR MUST set the Notify node address
+   in the Notify Request object to the value, that was received in the
+   corresponding Path message, in the Resv message that it sends
+   upstream.
+
+   If this router subsequently receives a corresponding Notify message
+   from upstream LSR than it MUST:
+   - send a Notify message downstream toward the Notify
+     node address that the LSR received in the Resv message.
+
+   - process the sub-group fields of the FILTER_SPEC object in the
+     received Notify message, and modify their values in the Notify
+     message that is forwarded to match the sub-group field values
+     in the original Path message sent downstream by this LSR.
+
+   The receiver of a (downstream) Notify message MUST identify the state
+   referenced in this message based on the SESSION and FILTER_SPEC
+   objects.
+
+   The consequence of these rules for a P2MP LSP is that an upstream
+   Notify message generated on a branch will result in a Notify being
+   delivered to the upstream Notify node address. The receiver of the
+   Notify message MUST NOT assume that the Notify message applies to all
+   downstream egresses, but MUST examine the information in the message
+   to determine to which egresses the message applies.
+
+   Downstream Notify messages MUST be replicated at branch LSRs accord-
+   ing to the Notify Request objects received on Resv messages.  Some
+   downstream branches might not request Notify messages, but all that
+   have requested Notify messages MUST receive them
+
+8.2. ResvConf Messages
+
+   ResvConf messages are described in [RFC2205]. ResvConf processing in
+   [RFC3473] and [RFC3209] is taken directly from [RFC2205]. An egress
+   LSR may include a RESV_CONFIRM object that contains the egress LSR's
+   address.  The object and message SHALL be supported for the confirma-
+   tion of receipt of the Resv message in P2MP TE LSPs. Processing not
+   detailed in this section MUST comply to [RFC2205].
+
+   A transit LSR sets the Sub-Group Originator ID in the FILTER_SPEC
+   object(s) of a Resv message to the value, that was received in the
+   corresponding Path message. If the incoming Resv message carries a
+   RESV_CONFIRM object then the LSR MUST include a RESV_CONFIRM object
+   in the corresponding Resv message that it sends upstream and MUST set
+   the receiver address in the RESV_CONFIRM object to the value that was
+   received in the corresponding Path message.
+
+   If this router subsequently receives a corresponding ResvConf message
+   from an upstream LSR than it MUST:
+   - send a ResvConf message downstream toward the receiver address that
+     the LSR received in the RESV_CONFIRM object in the Resv message.
+   - process the sub-group fields of the FILTER_SPEC object in the
+     received ResvConf message, and modify their values in the ResvConf
+     message that is forwarded to match the sub-group field values
+     in the original Path message sent downstream by this LSR.
+
+   The receiver of a ResvConf message MUST identify the state referenced
+   in this message based on the SESSION and FILTER_SPEC objects.
+
+   The consequence of these rules for a P2MP LSP is that a ResvConf mes-
+   sage generated at the ingress will result in a ResvConf message being
+   delivered to the branch and then to the receiver address in the orig-
+   inal RESV_CONFIRM object. The receiver of a ResvConf message MUST NOT
+   assume that the ResvConf message should be sent to all downstream
+   egresses, but MUST replicate the message according to the
+   RESV_CONFIRM objects received in Resv messages. Some downstream branches
+   branches might not request ResvConf messages, and ResvConf messages
+   SHOULD NOT be on these branches. All downstream branches that do
+   requested ResvConf messages MUST be sent such a message.
 
 9. Refresh Reduction
 
    The refresh reduction procedures described in [RFC2961] are equally
    applicable to P2MP LSP described in this document. Refresh reduction
    applies to individual messages and the state they install/maintain,
    and that continues to be the case for P2MP LSP.
 
 10. State Management
 
    State signaled by a P2MP Path message is managed by a local implemen-
    tation using the <P2MP ID, Tunnel ID, Extended Tunnel ID> as part of
    the SESSION object and <Tunnel Sender Address, LSP ID, Sub-Group
    Originator ID, Sub-Group ID> as part of the SENDER_TEMPLATE object.
 
-   Additional information signaled in the Path message is part of the
-   state created by a local implementation. This mandatorily includes
-   PHOP and SENDER_TSPEC object.
+   Additional information signaled in the Path/Resv message is part of
+   the state created by a local implementation. This mandatorily
+   includes PHOP/NHOP and SENDER_TSPEC/FILTER_SPEC object.
 
 10.1. Incremental State Update
 
    RSVP as defined in [RFC2205] and as extended by RSVP-TE [RFC3209] and
    GMPLS [RFC3473] uses the same basic approach to state communication
    and synchronization, namely full state is sent in each state adver-
    tisement message. Per [RFC2205] Path and Resv messages are idempo-
    tent. Also, [RFC2961] categorizes RSVP messages into two types: trig-
    ger and refresh messages and improves RSVP message handling and scal-
    ing of state refreshes but does not modify the full state advertise-
@@ -966,39 +1047,39 @@
    ferent Path messages in a single Path message in order to reduce the
    number of Path messages needed to maintain the P2MP LSP. This can
    also be done by a transit node that performed fragmentation and at a
    later point is able to combine multiple Path messages that it gener-
    ated into a single Path message. This may happen when one or more S2L
    sub-LSPs are pruned from the existing Path states.
 
    The new Path message is signaled by the node that is combining multi-
    ple Path messages with all the S2L sub-LSPs that are being combined
    in a single Path message. This Path message MAY contain a new Sub-
-   Group ID field value.  When a new Path and Resv message that is sig-
-   naled for an existing S2L sub-LSP is received by a transit LSR, state
-   including the new instance of the S2L sub-LSP is created.
+   Sub-Group ID field value.  When a new Path and Resv message that is
+   signaled for an existing S2L sub-LSP is received by a transit LSR,
+   state including the new instance of the S2L sub-LSP is created.
 
    The S2L sub-LSP SHOULD continue to be advertised in both the old and
    new Path messages until a Resv message listing the S2L sub-LSP and
    corresponding to the new Path message is received by the combining
    node. Hence until this point state for the S2L sub-LSP SHOULD be
    maintained as part of the Path state for both the old and the new
-   Path message [Section 3.1.3, 2205]. At that point the S2L sub-LSP
+   Path message [Section 3.1.3, RFC2205]. At that point the S2L sub-LSP
    SHOULD be deleted from the old Path state using the procedures of
    section 7.
 
-   A Path message with a sub-Group_ID(n) may signal a set of S2L sub-
-   LSPs that belong partially or entirely to an already existing Sub-
-   Group_ID(i), the SESSION object and <Sender Tunnel Address, LSP-ID,
-   Sub-Group Originator ID> being the same. Or it may signal a strictly
-   non-overlapping new set of S2L sub-LSPs with a strictly higher sub-
-   Group_ID value.
+   A Path message with a sub-Group_ID(n) may signal a set of S2L
+   sub-LSPs that belong partially or entirely to an already existing
+   Sub-Group_ID(i), the SESSION object and <Sender Tunnel Address,
+   LSP-ID, Sub-Group Originator ID> being the same. Or it may signal a
+   strictly non-overlapping new set of S2L sub-LSPs with a strictly higher
+   sub-Group_ID value.
 
    1) If sub-Group_ID(i) = sub-Group_ID(n), then either a full refresh
    is indicated by the Path message or a S2L Sub-LSP is added to/deleted
    from the group signaled by sub-Group_ID(n)
 
    2) If sub-Group_ID(i) != sub-Group_ID(n), then the Path message is
    signaling a set of S2L sub-LSPs that belong partially or entirely to
    an already existing Sub-Group_ID(i) or a strictly non-overlapping set
    of S2L sub-LSPs.
 
@@ -1009,22 +1090,22 @@
    lar S2L sub-LSP changes the state only for that S2L sub-LSP. Hence
    other S2L sub-LSPs are not impacted. In case the ingress node
    requests the maintenance of the 'LSP integrity', any error reported
    within the P2MP TE LSP must be reported at (least at) any other
    branching nodes belonging to this LSP. Therefore, reception of an
    error message for a particular S2L sub-LSP MAY change the state of
    any other S2L sub- LSP of the same P2MP TE LSP.
 
 11.1. PathErr Messages
 
-   The PathErr message will include one or more S2L_SUB_LSP objects. The
-   resulting modified format for a PathErr Message is:
+   The PathErr message will include one or more <S2L_SUB_LSP> objects.
+   The resulting modified format for a PathErr message is:
 
    <PathErr Message> ::=    <Common Header> [ <INTEGRITY> ]
                              [ [<MESSAGE_ID_ACK> |
                                 <MESSAGE_ID_NACK>] ... ]
                              [ <MESSAGE_ID> ]
                              <SESSION> <ERROR_SPEC>
                              [ <ACCEPTABLE_LABEL_SET> ... ]
                              [ <POLICY_DATA> ... ]
                              <sender descriptor>
                              [ <S2L sub-LSP descriptor list> ]
@@ -1033,22 +1114,22 @@
    Sub-Group Originator field and propagate a received PathErr message
    upstream MUST replace the Sub-Group fields received in the PathErr
    message with the value that was received in the Sub-Group fields of
    the Path message from the upstream neighbor.  Note the receiver of a
    PathErr message is able to identify the errored outgoing Path mes-
    sage, and outgoing interface, based on the Sub-Group fields received
    in the PathErr message.
 
 11.2. ResvErr Messages
 
-   The ResvErr message will include one or more S2L_SUB_LSP objects. The
-   resulting modified format for a ResvErr Message is:
+   The ResvErr message will include one or more <S2L_SUB_LSP> objects.
+   The resulting modified format for a ResvErr Message is:
 
    <ResvErr Message> ::=    <Common Header> [ <INTEGRITY> ]
                              [ [<MESSAGE_ID_ACK> |
                                 <MESSAGE_ID_NACK>] ... ]
                              [ <MESSAGE_ID> ]
                              <SESSION> <RSVP_HOP>
                              <ERROR_SPEC> [ <SCOPE> ]
                              [ <ACCEPTABLE_LABEL_SET> ... ]
                              [ <POLICY_DATA> ... ]
                              <STYLE> <flow descriptor list>
@@ -1066,35 +1147,35 @@
 
    During setup and during normal operation, PathErr messages may be
    received at a branch node. In all cases, a received PathErr message
    is first processed per standard processing rules. That is: the
    PathErr message is sent hop-by-hop to the ingress/branch LSR for that
    Path message.  Intermediate nodes until this ingress/branch LSR MAY
    inspect this message but take no action upon it. The behavior of a
    branch LSR that generates a PathErr message is under the control of
    the ingress LSR.
 
-   The default behavior is that the PathErr does not have the
+   The default behavior is that the PathErr message does not have the
    Path_State_Removed flag set. However, if the ingress LSR has set the
-   'LSP integrity' flag on the Path message (see LSP_ATTRIBUTE object in
+   LSP integrity flag on the Path message (see LSP_ATTRIBUTE object in
    section 20) and if the Path_State_Removed flag is supported, the LSR
    generating a PathErr to report the failure of a branch of the P2MP
    LSP SHOULD set the Path_State_Removed flag.
 
    A branch LSR that receives a PathErr message with the
    Path_State_Removed flag set MUST act according to the wishes of the
    ingress LSR. The default behavior is that the branch LSR clears the
    Path_State_Removed flag on the PathErr and sends it further upstream.
    It does not tear any other branches of the LSP. However, if the LSP
    integrity flag is set on the Path message, the branch LSR MUST send
-   PathTear on all downstream branches and send the PathErr message
-   upstream with the Path_State_Removed flag set.
+   PathTear on all other downstream branches and send the PathErr mes-
+   sage upstream with the Path_State_Removed flag set.
 
    A branch LSR that receives a PathErr message with the
    Path_State_Removed flag clear MUST act according to the wishes of the
    ingress LSR. The default behavior is that the branch LSR forwards the
    PathErr upstream and takes no further action. However, if the LSP
    integrity flag is set on the Path message, the branch LSR MUST send
    PathTear on all downstream branches and send the PathErr upstream
    with the Path_State_Removed flag set (per [RFC3473]).
 
    In all cases, the PathErr message forwarded by a branch LSR MUST con-
@@ -1160,26 +1241,26 @@
    ing to the new Path message is received by the re-optimizing node. At
    that point the egress SHOULD be deleted from the old Path state using
    the procedures of section 7.  Sub-tree re-optimization is then com-
    pleted.
 
    As is always the case, a node may choose to combine multiple path
    messages as described in section 10.2.
 
 15. Fast Reroute
 
-   [RSVP-FR] extensions can be used to perform fast reroute for the
+   [RFC4090] extensions can be used to perform fast reroute for the
    mechanism described in this document.
 
 15.1. Facility Backup
 
-   Facility backup as described in [RSVP-FR] can be used to protect P2MP
+   Facility backup as described in [RFC4090] can be used to protect P2MP
    LSPs.
 
    If link protection is desired, a bypass tunnel is used to protect the
    link between the PLR and next-hop. Thus all S2L sub-LSPs that use the
    link can be protected in the event of link failure. Note that all
    such S2L sub-LSPs belonging to a particular instance of a P2MP tunnel
    will share the same outgoing label on the link between the PLR and
    the next-hop. This is the P2MP LSP label on the link. Label stacking
    is used to send data for each P2MP LSP in the bypass tunnel. The
    inner label is the P2MP LSP label allocated by the nhop. During fail-
@@ -1187,43 +1268,43 @@
    sent to the MP, by the PLR. It is recommended that the PLR use the
    sender template specific method to identify these Path messages.
    Hence the PLR will set the source address in the sender template to a
    local PLR address. The MP will use the LSP-ID to identify the corre-
    sponding S2L sub-LSPs.
 
    The MP MUST not use the <sub-group originator ID, sub-group ID> while
    identifying the corresponding S2L sub-LSPs.
 
    In order to further process a S2L sub-LSP it will determine the pro-
-   tected S2L sub-LSP using the LSP-id and the S2L sub-LSP object.
+   tected S2L sub-LSP using the LSP-id and the <S2L_SUB_LSP> object.
 
    If node protection is desired, the bypass P2P tunnel must intersect
    the path of the protected S2L sub-LSPs on a LSR that is downstream
    from the PLR. This constrains the set of S2L sub-LSPs being backed-up
    via that bypass tunnel to those S2L sub-LSPs that pass through a com-
    mon downstream MP. This MP is the destination of the bypass tunnel.
    The MP will allocate the same label to all such S2L sub-LSPs belong-
    ing to a particular instance of a P2MP tunnel. This will be the inner
    label used during label stacking by the PLR when it sends data for
    each P2MP LSP in the bypass tunnel.  The outer label is the bypass
    tunnel label. During failure of the protected node the PLR will send
-   Path messages for the protected S2L Sub-LSPs to the MP using proce-
-   dures that are same as the link protection procedures described
+   Path messages for the protected S2L sub-LSPs to the MP using
+   procedures that are same as the link protection procedures described
    above. Node protection may require the PLR to be branch capable as
    multiple bypass tunnels may be required to backup the set of S2L sub-
    LSPs passing through the protected node. Else all the S2L sub-LSPs
    passing through the protected node must also pass through a MP that
    is downstream from the protected node.
 
 15.2. One to One Backup
 
-   One to one backup as described in [RSVP-FR] can be used to protect a
+   One to one backup as described in [RFC4090] can be used to protect a
    particular S2L sub-LSP against link and next-hop failure. Protection
    may be used for one or more S2L sub-LSPs between the PLR and the
    next-hop. All the S2L sub-LSPs corresponding to the same instance of
    the P2MP tunnel, between the PLR and the next-hop share the same P2MP
    LSP label.
 
    All or some of these S2L sub-LSPs may be protected.
 
    The detour S2L sub-LSPs may or may not share labels, depending on the
    detour path. Thus the set of outgoing labels and next-hops for a P2MP
@@ -1328,157 +1409,202 @@
    PE1 can setup a P2P LSP to P1 and use that as a LSP segment. The Path
    messages for PE3 and PE4 can now be tunneled over the LSP segment.
    Thus P3 is not aware of the P2MP LSP and does not process the P2MP
    control messages.
 
 18. P2MP LSP Remerging and Cross-Over
 
    This section is currently under discussion between the authors and
    will be updated in the next revision.
 
-   The functional description described so far assumes that multiple
-   Path messages received by a LSR for the same P2MP LSP arrive on the
-   same incoming interface. However this may not always be the case.
+   This section details the procedures for detecting and dealing with
+   re-merge and cross-over. The term re-merge refers to the case of an
+   ingress or transit node that creates a branch of a P2MP LSP, a re-
+   merge branch, which intersects the P2MP LSP at another node farther
+   down the tree.  This may occur due to such events as an error in path
+   calculation, an error in manual configuration, or network topology
+   changes during the establishment of the P2MP LSP.  If the procedures
+   detailed in this section are not followed, data duplication will
+   result.
 
-   P2MP tree remerging or cross-over occurs when a transit or egress
-   node receives the signaling state i.e. Path message for the same P2MP
-   TE LSP from more than one previous hop. If the remerged S2L sub-LSPs
-   are sent out on different interfaces there is no data plane issue.
-   However if the remerged S2L sub-LSPs are sent out on the same inter-
-   face it can result in data duplication downstream. In order to
-   describe identification of cross over and remerging by a LSR let us
-   list the various cases when state for a S2L sub-LSP is received by a
-   LSR.
+   The term cross-over refers to the case of an ingress or transit node
+   that creates a branch of a P2MP LSP, a cross-over branch, which
+   intersects the P2MP LSP at another node farther down the tree. It is
+   unlike re-merge in that at the intersecting node the cross-over
+   branch has a different outgoing interface as well as a different
+   incoming interface.  This may be necessary in certain combinations of
+   topology and technology; e.g., in a transparent optical network in
+   which different wavelengths are required to reach different leaf
+   nodes.
 
-   Case1: S2L sub-LSP already exist as part of an existing Path state.
-   The following are the various sub-cases.
-      a) The new S2L sub-LSP uses the same PHOP and outgoing interface
-   as the existing S2L sub-LSP. This is either a refresh or can occur
-   when multiple existing Path messages are combined in a new Path mes-
-   sage.
+   Normally, a P2MP LSP has a single incoming interface on which all of
+   the Path messages associated with that P2MP LSP are received.  The
+   incoming interface is identified by the IF_ID RSVP_HOP Object, if
+   present, and by interface over which the Path message was received if
+   the IF_ID RSVP_HOP Object is not present.  However, in the case of
+   dynamic LSP re-routing, the incoming interface may change.
 
-      b) The new S2L sub-LSP uses the same PHOP but different outgoing
-   interface as the existing S2L sub-LSP. This is a case of re-routing.
-      c) The new S2L sub-LSP uses a different PHOP and same outgoing
-   interface as the existing S2L sub-LSP. This is a case of re-routing.
-      d) The new S2L sub-LSP uses a different PHOP and a different out-
-   going interface as compared to the existing S2L sub-LSP. This is a
-   case of re-routing.
+   Similarly, in both the re-merge case and cross-over cases, a node
+   will receive a Path message for a given P2MP LSP on a different
+   incoming interface, and the node needs to be able to distinguish
+   between dynamic LSP re-routing and the re-merge/cross-over cases.
 
-   Case2: S2L sub-LSP does not exist as part of an existing Path state.
-   The following are the sub-cases.
-      a) The new S2L sub-LSP uses a PHOP and outgoing interface that is
-   same as the PHOP and outgoing interface used by an existing S2L sub-
-   LSP that belongs to the same P2MP LSP. This is a legal case of sig-
-   naling a new S2L sub-LSP.
-      b) The new S2L sub-LSP uses a PHOP that is same as that used by an
-   existing S2L sub-LSP. However the outgoing interface is different
-   from the outgoing interfaces used by existing S2L sub-LSPs belonging
-   to the same P2MP LSP. This is a legal case of signaling a new S2L
-   sub-LSP.
-      c) The new S2L sub-LSP uses a different PHOP than that used by any
-   of the existing S2L sub-LSP that belong to the same P2MP LSP . How-
-   ever the outgoing interface is same as the outgoing interface used by
-   an existing S2L sub-LSPs. This is a case of remerging.
-      d) The new S2L sub-LSP uses a different PHOP than that used by any
-   of the existing S2L sub-LSP that belong to the same P2MP LSP. Also
-   the outgoing interface is different from the outgoing interfaces used
-   by existing S2L sub-LSPs. This is a case of cross-over.
+   (Make-before-break represents yet another similar but different case,
+   in that the incoming interface associated with the make-before-break
+   P2MP LSP may be different than that associated with the original P2MP
+   LSP.  However, the two P2MP LSPs will be treated as distinct, but
+   related, LSPs because they will have different LSP ID field values in
+   their SENDER_TEMPLATE objects.)
 
-   Case 2(d) above identifies cross-over and this is considered legal.
-   Case 2(c) above identifies remerging in the data plane. If the LSR is
-   capable of remerging in the data plane this is considered legal.
+18.1. Procedures
 
-   The below procedure applies for remerging.
+   When a node receives a Path message, it MUST check whether it has
+   matching state for the P2MP LSP. Matching state is identified by com-
+   paring the SESSION and SENDER_TEMPLATE objects in the received Path
+   message with the SESSION and SENDER_TEMPLATE objects of each locally
+   maintained P2MP LSP Path state. The P2MP ID, Tunnel ID, and Extended
+   Tunnel ID in the SESSION Object and the sender address and LSP ID in
+   the SENDER_TEMPLATE object are used for the comparison.  If the node
+   has matching state and the incoming interface for the received Path
+   message is different than the incoming interface of the matching P2MP
+   LSP Path state, then the node MUST determine whether it is dealing
+   with dynamic LSP rerouting or re-merge/cross-over.
 
-   The remerge error case is detected by checking incoming Path messages
-   that represent new P2MP TE LSP state and seeing if they represent
-   both known LSP state and a different S2L sub-LSP list. Specifically,
-   the remerge check MUST be performed when processing Path messages
-   that contain SESSION, SENDER_TEMPLATE and RSVP_HOP objects that have
-   not previously been seen on a particular interface. The remerge check
-   consists of attempting to locate state that has the same values in
-   the SESSION object and in the tunnel sender address and LSP ID fields
-   of the SENDER_TEMPLATE object.
+   Dynamic LSP rerouting is identified by checking whether there is any
+   intersection between the set of SUB-LSP objects associated with the
+   matching P2MP LSP Path state and the set of SUB-LSP objects in the
+   received Path message.  If there is any intersection, then dynamic
+   re-routing has occurred.  If there is no intersection between the two
+   sets of SUB-LSP objects, then either re-merge or cross-over has
+   occurred. (Note that in the case of dynamic LSP rerouting, Path mes-
+   sages for the non-intersecting members of set of SUB-LSPs associated
+   with the matching P2MP LSP Path state will be received subsequently
+   on the new incoming interface.)
 
-   If no matching state is located, then there is no remerge condition.
+   In order to identify the re-merge case, the node processing the
+   received Path message MUST identify the outgoing interfaces associ-
+   ated with the matching P2MP Path state.  Re-merge has occurred if
+   there is any intersection between the set of outgoing interfaces
+   associated with the matching P2MP LSP Path state and the set of out-
+   going interfaces in the received Path message.
 
-   If matching state is found, then the list of S2L Sub-LSPs associated
-   with the new Path message is compared against the list present in the
-   located state.  If any addresses in the lists of S2L sub-LSPs match,
-   then it is the legal LSP rerouting case mentioned here above.
+18.1.1. Re-Merge Procedures
 
-   If there are no overlap in the lists, the node checks whether any of
-   the outgoing interfaces, as identified by the ERO/SUB_EROs, are an
-   outgoing interface already associated with the existing P2MP LSP. If
-   not, then legal LSP crossing is being performed. Else re-merging has
-   occurred and if the LSR is capable of remerging in the data plane,
-   this is considered legal. In that case the LSR will return the label
-   already associated with the existing S2L sub-LSP with the matching
-   egress interface, in the Resv message it sends upstream. If the LSR
-   is not capable of remerging in the data plane the new Path message
-   MUST be handled according to remerge error processing as described
-   below.
+   There are two approaches to dealing with re-merge case.  In the
+   first, the node detecting the re-merge case, i.e., the re-merge node,
+   allows the re-merge case to persist but data from all but one incom-
+   ing interface is dropped at the re-merge node.  In the second, the
+   re-merge node initiates the removal of the re-merge branch(es) via
+   signaling.  Which approach is used is a matter of local policy.  A
+   node MUST support both approaches and MUST allow user configuration
+   of which approach is to be used.
 
-   The LSR generates a PathErr message with Error Code "Routing Prob-
-   lem/P2MP Remerge Detected" towards the upstream node (i.e.  the node
-   that sent the Path message) until it reaches the node that caused the
-   remerge condition.  Identification of the offending node requires
-   special processing by the nodes upstream of the error.  A node that
-   receives a PathErr message that contains the error "Routing Prob-
-   lem/P2MP Remerge Detected" MUST check to see if it is the offending
-   node. This check is done by comparing the S2L sub-LSPs listed in the
-   PathErr message with existing LSP state. If any of the egresses are
-   already present in any Path state associated with the P2MP TE LSP
-   other than the one associated with the <SESSION, SENDER_TEMPLATE>
-   objects signaled in the PathErr message, then the node is the signal-
-   ing branch node that caused the remerge condition. This node SHOULD
-   then correct the remerge condition by adding all S2L sub-LSPs listed
-   in the offending Path state to the Path state (and Path message)
-   associated to these S2L sub-LSPs. Note that the new Path state may be
-   sent out the same outgoing interface in different Path messages in
-   order to meet IP packet size limitations.  If use of a new outgoing
-   interface violates one or more SERO constraint, then a PathErr mes-
-   sage containing the associated egresses and any identified valid
-   egresses SHOULD be generated with the error code "Routing Problem"
-   and error value of "ERO Resulted in Remerge".
+   When configured to allow a re-merge case to persist, the re-merge
+   node MUST validate consistency between the objects included the
+   received Path message and the matching P2MP LSP Path state. Any
+   inconsistencies MUST result in an appropriate PathErr message sent to
+   the previous hop of the received Path message.  The error code is set
+   to "Routing Problem" and the error value is set to "P2MP Re-Merge
+   Parameter Mistmatch".
 
-   This process may continue hop-by-hop until the ingress is reached.
-   The only case where this process will fail is when all the listed S2L
-   sub-LSPs are deleted prior to the PathErr message propagating to the
-   ingress. In this case, the whole process will be corrected on the
-   next (refresh or trigger) transmission of the offending Path message.
+   If there are no inconsistencies, the node logically merges, from the
+   downstream perspective, the control state of incoming Path message
+   with the matching P2MP LSP Path state.  Specifically, procedures
+   related to processing of messages received from upstream MUST NOT be
+   modified from the upstream perspective; this includes refresh and
+   state timeout related processing.  In addition to the standard
+   upstream related procedures, the node MUST ensure that each object
+   received from upstream is appropriately represented within the set of
+   Path messages sent downstream. For example, the received <S2L sub-LSP
+   descriptor list> MUST be included in the set of outgoing Path mes-
+   sages. If there are any NOTIFY_REQUEST request objects present, then
+   the procedures defined in Section 8 MUST be followed for both Path
+   and Resv messages.  Special processing is also required for Resv pro-
+   cessing.  Specifically, any Resv message received from downstream
+   MUST be mapped into an outgoing Resv message that is sent to the pre-
+   vious hop of the received Path message.  In practice, this translates
+   to decomposing the complete <S2L sub-LSP descriptor list> into sub-
+   sets that match the incoming Path messages and then constructing an
+   outgoing Resv message for each incoming Path message.
 
-   In all cases where a remerge error is not detected, normal processing
-   continues.
+   When configured to allow a re-merge case to persist, the re-merge
+   node receives data associated with the P2MP LSP on multiple incoming
+   interfaces, but it may only send the data from one of these inter-
+   faces to its outgoing interfaces, i.e., the node MUST drop data from
+   all but one incoming interface.  This ensures that duplicate data is
+   not sent on any outgoing interface.  The mechanism used to select the
+   incoming interface to use is implementation specific and is outside
+   the scope of this document.
+
+   When configured to correct the re-merge branch via signaling, the re-
+   merge node MUST send a PathErr message corresponding to the received
+   Path message. The PathErr message MUST include all of the objects
+   normally included in a PathErr message, as well as one or more SUB-
+   LSP objects from the set of sub-LSPs associated with the matching
+   P2MP LSP Path state.  A minimum of three SUB-LSP objects is RECOM-
+   MENDED. This will allow the node that caused the re-merge to identify
+   the outgoing Path state associated with the valid portion of the P2MP
+   LSP. The PathErr message MUST include the error code "Routing Prob-
+   lem" and error value of "P2MP Remerge Detected". The node MAY set the
+   Path_State_Removed flag [RFC3473].  As is always the case, the
+   PathErr message is sent to the previous hop of the received Path mes-
+   sage.
+
+   A node that receives a PathErr message that contains the error "Rout-
+   ing Problem/P2MP Remerge Detected" MUST determine if it is the node
+   that created the re-merge case.  This is done by checking whether
+   there is any intersection between the set of SUB-LSP objects associ-
+   ated with the matching P2MP LSP Path state and the set of SUB-LSP
+   objects in the received PathErr message.  If there is, then the node
+   created the re-merge case.
+
+   The node SHOULD remove the re-merge case by moving the SUB-LSP
+   objects included in the Path message associated with the received
+   PathErr message to the outgoing interface associated with the match-
+   ing P2MP LSP Path state.  A trigger Path message for the moved SUB-
+   LSP objects is then sent via that outgoing interface.  If the
+   received PathErr message did not have the Path_State_Removed flag
+   set, the node SHOULD send a PathTear via the outgoing interface asso-
+   ciated with the re-merge branch.
+
+   If use of a new outgoing interface violates one or more SERO con-
+   straint, then a PathErr message containing the associated egresses
+   and any identified SUB-LSP objects SHOULD be generated with the error
+   code "Routing Problem" and error value of "ERO Resulted in Remerge".
+
+   The only case where this process will fail is when all the listed
+   SUB-LSP objects are deleted prior to the PathErr message propagating
+   to the ingress.  In this case, the whole process will be corrected on
+   the next (refresh or trigger) transmission of the offending Path mes-
+   sage.
 
 19. New and Updated Message Objects
 
    This section presents the RSVP object formats as modified by this
    document.
 
 19.1. SESSION Object
 
-   A P2MP LSP SESSION object is used. This object uses the existing SES-
-   SION C-Num. New C-Types are defined to accommodate a logical P2MP
+   A P2MP LSP SESSION object is used. This object uses the existing
+   SESSION C-Num. New C-Types are defined to accommodate a logical P2MP
    destination identifier of the P2MP Tunnel. This SESSION object has a
    similar structure as the existing point to point RSVP-TE SESSION
-   object. However the destination address is set to the P2MP ID instead
-   of the unicast Tunnel Endpoint address. All S2L sub-LSPs part of the
-   same P2MP LSP share the same SESSION object. This SESSION object
-   identifies the P2MP Tunnel.
+   object.  However the destination address is set to the P2MP ID
+   instead of the unicast Tunnel Endpoint address. All S2L sub-LSPs part
+   of the same P2MP LSP share the same SESSION object. This SESSION
+   object identifies the P2MP Tunnel.
 
    The combination of the SESSION object, the SENDER_TEMPLATE object and
-   the S2L SUB-LSP object, identifies each S2L sub-LSP. This follows the
-   existing P2P RSVP-TE notion of using the SESSION object for identify-
-   ing a P2P Tunnel which in turn can contain multiple LSPs, each dis-
-   tinguished by a unique SENDER_TEMPLATE object.
+   the <S2L_SUB_LSP> object, identifies each S2L sub-LSP. This follows
+   the existing P2P RSVP-TE notion of using the SESSION object for iden-
+   tifying a P2P Tunnel which in turn can contain multiple LSPs, each
+   distinguished by a unique SENDER_TEMPLATE object.
 
 19.1.1. P2MP LSP Tunnel IPv4 SESSION Object
 
    Class = SESSION, P2MP_LSP_TUNNEL_IPv4 C-Type = TBA
 
        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
       +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
       |                       P2MP ID                                 |
       +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
@@ -1505,28 +1631,40 @@
       all zeros. Ingress nodes that wish to narrow the scope of a
       SESSION to the ingress-PID pair may place their IPv4 address
       here as a globally unique identifier [RFC3209].
 
 19.1.2. P2MP LSP Tunnel IPv6 SESSION Object
 
    This is same as the P2MP IPv4 LSP SESSION Object with the difference
    that the extended tunnel ID may be set to a 16 byte identifier
    [RFC3209].
 
+       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
+      +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
+      |                       P2MP ID                                 |
+      +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
+      |  MUST be zero                 |      Tunnel ID                |
+      +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
+      |                      Extended Tunnel ID (16 bytes)            |
+      |                                                               |
+      |                             .......                           |
+      +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
+
 19.2. SENDER_TEMPLATE object
 
-   The sender template contains the ingress-LSR source address. LSP ID
-   can be can be changed to allow a sender to share resources with
-   itself. Thus multiple instances of the P2MP tunnel can be created,
-   each with a different LSP ID. The instances can share resources with
-   each other, but use different labels. The S2L sub-LSPs corresponding
-   to a particular instance use the same LSP ID.
+   The SENDER_TEMPLATE object contains the ingress-LSR source address.
+   LSP ID can be can be changed to allow a sender to share resources
+   with itself. Thus multiple instances of the P2MP tunnel can be cre-
+   ated, each with a different LSP ID. The instances can share resources
+   with each other, but use different labels. The S2L sub-LSPs corre-
+   sponding to a particular instance use the same LSP ID.
 
    As described in section 4.2 it is necessary to distinguish different
    Path messages that are used to signal state for the same P2MP LSP by
    using a <Sub-Group ID Originator ID, Sub-Group ID> tuple. The
    SENDER_TEMPLATE object is modified to carry this information as shown
    below.
 
 19.2.1. P2MP LSP Tunnel IPv4 SENDER_TEMPLATE Object
 
    Class = SENDER_TEMPLATE, P2MP_LSP_TUNNEL_IPv4 C-Type = TBA
@@ -1592,55 +1730,55 @@
         IPv6 tunnel sender address
            See [RFC3209]
 
         Sub-Group Originator ID
             The Sub-Group Originator ID is set to the IPv6 TE Router ID
             of the LSR that originates the Path message. This is either
             the ingress LSR or a LSR which re-originates the Path
             message with its own Sub-Group Originator ID.
 
         Sub-Group ID
-           As above.
+           As above in section 19.2.2.
 
         LSP ID
            See [RFC3209]
 
-19.3. S2L SUB-LSP Object
+19.3. <S2L_SUB_LSP> Object
 
-   A new S2L Sub-LSP object identifies a particular S2L sub-LSP belong-
-   ing to the P2MP LSP.
+   A new <S2L_SUB_LSP> object identifies a particular S2L sub-LSP
+   belonging to the P2MP LSP.
 
-19.3.1. S2L SUB-LSP IPv4 Object
+19.3.1. <S2L_SUB_LSP> IPv4 Object
 
    SUB_LSP Class = 50, S2L_SUB_LSP_IPv4 C-Type = TBA
 
        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
       +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
       |                   IPv4 S2L Sub-LSP destination address        |
       +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
 
    IPv4 Sub-LSP destination address
 
       IPv4 address of the S2L sub-LSP destination.
 
-19.3.2. S2L SUB-LSP IPv6 Object
+19.3.2. <S2L_SUB_LSP> IPv6 Object
 
    SUB_LSP Class = 50, S2L_SUB_LSP_IPv6 C-Type = TBA
 
    This is same as the S2L IPv4 Sub-LSP object, with the difference that
    the destination address is a 16 byte IPv6 address.
 
        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
       +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
-      |                   IPv6 S2L Sub-LSP destination address        |
+      |        IPv6 S2L Sub-LSP destination address (16 bytes)        |
       |                        ....                                   |
       |                                                               |
       +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
 
 19.4. FILTER_SPEC Object
 
    The FILTER_SPEC object is canonical to the P2MP SENDER_TEMPLATE
    object.
 
 19.4.1. P2MP LSP_IPv4 FILTER_SPEC Object
@@ -1654,39 +1792,39 @@
 
    Class = FILTER SPEC, P2MP LSP_IPv6 C-Type = TBA
 
    The format of the P2MP LSP_IPv6 FILTER_SPEC object is identical to
    the P2MP LSP_IPv6 SENDER_TEMPLATE object.
 
 19.5. P2MP SECONDARY_EXPLICIT_ROUTE Object (SERO)
 
    The P2MP Secondary Explicit Route Object (SERO) is defined as identi-
    cal to the ERO.  The class of the P2MP SERO is the same as the SERO
-   defined in [RECOVERY] (TBA).  The P2MP SERO C-Type = TBA The sub-
+   defined in [RECOVERY]. The P2MP SERO uses a new C-Type = 2. The sub-
    objects are identical to those defined for the ERO.
 
 19.6. P2MP SECONDARY_RECORD_ROUTE Object (SRRO)
 
-   The P2MP Secondary Record Route Object (SRRO) is defined as identical
+   The P2MP SECONDARY_RECORD_ROUTE Object (SRRO) is defined as identical
    to the ERO.  The class of the P2MP SRRO is the same as the SRRO
-   defined in [RECOVERY] (TBA).  The P2MP SRRO C-Type = TBA.  The sub-
+   defined in [RECOVERY]. The P2MP SRRO uses a new C-Type = 2. The sub-
    objects are identical to those defined for the RRO.
 
 20. IANA Considerations
 
 20.1. New Class Numbers
 
    IANA is requested to assign the following Class Numbers for the new
    object classes introduced. The Class Types for each of them are to be
-   assigned via standards action. The sub-object types for the P2MP SEC-
-   ONDARY_EXPLICIT_ROUTE and P2MP_SECONDARY_RECORD_ROUTE follow the same
-   IANA considerations as those of the ERO and RRO [RFC3209].
+   assigned via standards action. The sub-object types for the P2MP
+   SECONDARY_EXPLICIT_ROUTE and P2MP_SECONDARY_RECORD_ROUTE follow the
+   same IANA considerations as those of the ERO and RRO [RFC3209].
 
    50  Class Name = SUB_LSP
 
    C-Type
       1   S2L_SUB_LSP_IPv4 C-Type
       2   S2L_SUB_LSP_IPv6 C-Type
 
 20.2. New Class Types
 
    IANA is requested to assign the following C-Type values:
@@ -1717,29 +1856,29 @@
 
    C-Type
       2  P2MP_SECONDARY_RECORD_ROUTE C-Type
 
 20.3. New Error Codes
 
    Four new Error Codes are defined for use with the Error Value "Rout-
    ing Problem". IANA is requested to assign values.
 
    The Error Code "Unable to Branch" indicates that a P2MP branch cannot
-   be formed by the reporting LSR. IANA is requested to assign value 20
+   be formed by the reporting LSR. IANA is requested to assign value 23
    to this Error Code.
 
    The Error Code "Unsupported LSP Integrity" indicates that a P2MP
    branch does not support the requested LSP integrity function. IANA is
-   requested to assign value 21 to this Error Code.
+   requested to assign value 24 to this Error Code.
 
    The Error Code "P2MP Remerge Detected" indicates that a node has
-   detected remerge. IANA is requested to assign value 22 to this Error
+   detected remerge. IANA is requested to assign value 25 to this Error
    Code.
 
 20.4. LSP Attributes Flags
 
    IANA has been asked to manage the space of flags in the Attibutes
    Flags TLV carried in the LSP_ATTRIBUTES Object [LSP-ATTRIB]. This
    document defines two new flags as follows:
 
    Suggested Bit Number:             3
    Meaning:                          LSP Integrity Required
@@ -2073,18 +2211,18 @@
 27. Full Copyright Statement
 
    Copyright (C) The Internet Society (2005). This document is subject
    to the rights, licenses and restrictions contained in BCP 78, and
    except as set forth therein, the authors retain all their rights.
 
    This document and the information contained herein are provided on an
    "AS IS" basis and THE CONTRIBUTOR, THE ORGANIZATION HE/SHE REPRESENTS
    OR IS SPONSORED BY (IF ANY), THE INTERNET SOCIETY AND THE INTERNET
    ENGINEERING TASK FORCE DISCLAIM ALL WARRANTIES, EXPRESS OR IMPLIED,
-   INCLUDING BUT NOT LIMITED TO ANY WARRANTY THAT THE USE OF THE INFORMATION
-   HEREIN WILL NOT INFRINGE ANY RIGHTS OR ANY IMPLIED WARRANTIES OF
-   MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE.
+   INCLUDING BUT NOT LIMITED TO ANY WARRANTY THAT THE USE OF THE INFOR-
+   MATION HEREIN WILL NOT INFRINGE ANY RIGHTS OR ANY IMPLIED WARRANTIES
+   OF MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE.
 
 28. Acknowledgement
 
    Funding for the RFC Editor function is currently provided by the
    Internet Society.