Rfc | 5332 |
Title | MPLS Multicast Encapsulations |
Author | T. Eckert, E. Rosen, Ed., R.
Aggarwal, Y. Rekhter |
Date | August 2008 |
Format: | TXT, HTML |
Updates | RFC3032, RFC4023 |
Status: | PROPOSED STANDARD |
|
Network Working Group T. Eckert
Request for Comments: 5332 E. Rosen, Ed.
Category: Standards Track Cisco Systems, Inc.
Updates: 3032, 4023 R. Aggarwal
Y. Rekhter
Juniper Networks, Inc.
August 2008
MPLS Multicast Encapsulations
Status of This Memo
This document specifies an Internet standards track protocol for the
Internet community, and requests discussion and suggestions for
improvements. Please refer to the current edition of the "Internet
Official Protocol Standards" (STD 1) for the standardization state
and status of this protocol. Distribution of this memo is unlimited.
Abstract
RFC 3032 established two data link layer codepoints for MPLS, used to
distinguish whether the data link layer frame is carrying an MPLS
unicast or an MPLS multicast packet. However, this usage was never
deployed. This specification updates RFC 3032 by redefining the
meaning of these two codepoints. Both codepoints can now be used to
carry multicast packets. The second codepoint (formerly the
"multicast codepoint") is now to be used only on multiaccess media,
and it is to mean "the top label of the following label stack is an
upstream-assigned label".
RFC 3032 does not specify the destination address to be placed in the
"MAC DA" (Medium Access Layer Destination Address) field of an
ethernet frame that carries an MPLS multicast packet. This document
provides that specification.
This document updates RFC 3032 and RFC 4023.
Table of Contents
1. Introduction ....................................................2
2. Specification of Requirements ...................................3
3. Upstream-Assigned vs. Downstream-Assigned .......................3
4. Ethernet Codepoints .............................................6
5. PPP Protocol Field ..............................................6
6. GRE Protocol Type ...............................................6
7. IP Protocol Number ..............................................7
8. Ethernet MAC DA for Multicast MPLS ..............................7
9. IANA Considerations .............................................8
10. Security Considerations ........................................8
11. Normative References ...........................................9
1. Introduction
RFC 3031 [RFC3031] defines the "Next Hop Label Forwarding Entry"
(NHLFE). The NHLFE for a particular label maps the label into a next
hop (among other things). When an MPLS packet is received, its top
label is mapped to an NHLFE, and the packet is sent to the next hop
specified by the NHLFE.
We define a particular MPLS label to be a "multicast label" in a
particular context if the NHLFE to which it is mapped, in that
context, specifies a set of next hops, with the semantics that the
packet is to be replicated and a copy of the packet sent to each of
the specified next hops. Note that this definition accommodates the
case where the set of next hops contains a single member. What makes
a label a multicast label in a particular context is the semantics
attached to the set, i.e., the intention to replicate the packet and
transmit to all members of the set if the set has more than one
member.
RFC 3032 [RFC3032] established two data link layer codepoints for
MPLS: one to indicate that the data link layer frame is carrying an
MPLS unicast packet, and the other to indicate that the data link
layer frame is carrying an MPLS multicast packet. The term
"multicast packet" is not precisely defined in RFC 3032, though one
may presume that the "multicast" codepoint is intended to identify
the packet's top label as a multicast label. However, the multicast
codepoint has never been deployed, and further development of the
procedures for MPLS multicast have shown that, while there is a need
for two codepoints, the use of the two codepoints is not properly
captured by RFC 3032.
In particular, there is no need for the codepoint to indicate whether
the top MPLS label is a multicast label. When the receiver of an
MPLS packet looks up the top label, the NHLFE will specify whether or
not the label is a multicast label.
This document updates RFC 3032 and RFC 4023 by re-specifying the use
of the codepoints. The old use of the "multicast codepoint", as
specified in those two RFCs, is hereby deprecated.
Note that an implementation that does MPLS multicast according to RFC
3032 and/or 4023 will be unable to interoperate with implementations
that do MPLS multicast according to this document. There may be some
deployed platforms that support the deprecated use of the codepoints,
but those platforms do not support the control plane mechanisms to
support MPLS multicast. The absence of the control plane will
prevent a system that implements the deprecated use of codepoints
from attempting to interoperate with a system that uses the
codepoints as specified herein. (If an MPLS multicast control plane
were to be implemented on a platform that only supports the
deprecated codepoint, interoperability problems such as black holes
and/or misrouting would arise. This does not seem like a potential
problem in practice.)
While RFC 3032 allows an MPLS packet to be carried in an ethernet
multicast frame, it fails to specify how the Medium Access Layer
Destination Address (MAC DA) field is to be set in that case. This
document provides that specification.
2. Specification of Requirements
The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
"SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this
document are to be interpreted as described in [RFC2119].
3. Upstream-Assigned vs. Downstream-Assigned
Suppose a labeled packet P is sent from Label Switching Router (LSR)
R1 to LSR R2, where R1 puts label L on the packet's label stack, and
R2 has to look up label L in order to determine the corresponding
Forwarding Equivalence Class (FEC), call it F.
If the binding between L and F was made by R2 and advertised to R1,
then the label binding is known as "downstream-assigned". RFC 3031
only discusses downstream-assigned label bindings.
If the binding between L and F was made by R1 and advertised to R2,
then the label binding is known as "upstream-assigned".
If the binding between L and F was made by a third party, say R3, and
then advertised to both R1 and R2, we also refer to the label binding
as "upstream-assigned".
Upstream-assigned labels are not required to come from the same
"label space" as downstream-assigned labels. See Section 3.14 of
[RFC3031] and especially [RFC5331] for a discussion of the notion of
"label space". The procedures for properly interpreting an upstream-
assigned label are given in [RFC5331].
If Ru and Rd are LSP adjacencies, then they transmit an MPLS packet
to each other through one of the following mechanisms:
1. by putting the MPLS packet in a data link layer frame and
transmitting the frame,
2. by transmitting the MPLS packet through an MPLS tunnel, i.e.,
by pushing an additional label (or labels) onto the label
stack, and then invoking mechanism 1, or
3. by transmitting the MPLS packet through an IP-based tunnel
(e.g., via RFC 4023 [RFC4023]), and then invoking mechanisms 1
and/or 2.
In short, an MPLS packet is transmitted through a data link, through
an MPLS tunnel, or through an IP tunnel. In any of those cases, when
the packet emerges through the tunnel, the downstream LSR must know
whether the label that now appears at the top of the label stack has
an upstream-assigned label binding or a downstream-assigned label
binding. For convenience, we will speak of a label with an
upstream-assigned label binding as an "upstream-assigned label".
Under certain conditions, specified below, multicast labels MAY be
upstream-assigned. The ability to use upstream-assigned labels is an
OPTIONAL feature. Upstream-assigned labels MUST NOT be used unless
it is known that the downstream LSR supports them. How this is known
is outside the scope of this document.
This document makes no changes to the procedures regarding unicast
labels.
We discuss three different types of data link or tunnel:
- Point-to-Point. A point-to-point data link or tunnel associates
two systems, such that transmissions on that link or tunnel made
by one are received by the other, and only by the other.
For a given direction of a given point-to-point data link or
tunnel, the following MUST be the case: either every MPLS
packet will carry an upstream-assigned label, or else every MPLS
packet will carry a downstream-assigned label. The procedures
for determining whether upstream-assigned or downstream-assigned
labels are being used are outside the scope of this
specification. However, in the absence of any other
information, the use of downstream-assigned labels MUST be
presumed by default.
- Point-to-Multipoint. A point-to-multipoint link or tunnel
associates n systems, such that only one of them can transmit
onto the link or tunnel, and the transmissions may be received
by the other n-1 systems.
The top labels (before applying the data link or tunnel
encapsulation) of all MPLS packets that are transmitted on a
particular point-to-multipoint data link or tunnel MUST be of
the same type; either all upstream-assigned or all downstream-
assigned. This means that all the receivers on the MPLS or IP
tunnel must know a priori whether upstream-assigned or
downstream-assigned labels are being used in the tunnel. How
this is known is outside the scope of this document.
- Multipoint-to-Multipoint. A multipoint-to-multipoint link or
tunnel associates n systems, such that any of them can transmit
on the link or tunnel, and the transmissions may be received by
the other n-1 systems.
If MPLS packets are transmitted on a particular multipoint-to-
multipoint link or tunnel, one of the following scenarios
applies:
1. It is known (by methods outside the scope of this document)
that the top label of every MPLS packet on the link or
tunnel is downstream-assigned.
2. It is known (by methods outside the scope of this document)
that the top label of every MPLS packet on the link or
tunnel is upstream-assigned.
3. Some MPLS packets on the link may have upstream-assigned top
labels while some may have downstream-assigned top labels.
If (and only if) the third scenario applies, the data link or
tunnel encapsulation MUST provide a codepoint that specifies
whether the top label of the encapsulated MPLS packet is
upstream-assigned or downstream-assigned. If a particular type of
data link or tunnel does not provide such a codepoint, then the
third scenario MUST NOT be used.
The remainder of this document specifies procedures for setting the
data link layer codepoints and address fields.
4. Ethernet Codepoints
Ethernet is an example of a multipoint-to-multipoint data link.
Ethertype 0x8847 is used whenever a unicast ethernet frame carries an
MPLS packet.
Ethertype 0x8847 is also used whenever a multicast ethernet frame
carries an MPLS packet, EXCEPT for the case where the top label of
the MPLS packet has been upstream-assigned.
Ethertype 0x8848, formerly known as the "MPLS multicast codepoint",
is to be used only when an MPLS packet whose top label is upstream-
assigned is carried in a multicast ethernet frame.
5. PPP Protocol Field
PPP is an example of a point-to-point data link. When a PPP frame is
carrying an MPLS packet, the PPP Protocol field is always set to
0x0281.
6. GRE Protocol Type
RFC 4023 is modified as described below.
If the IP destination address of the Generic Routing Encapsulation
(GRE) is a unicast IP address, then the ethertype value 0x8847 MUST
be used in all cases for the MPLS-in-GRE encapsulation.
If the IP destination address of the GRE encapsulation is a multicast
IP address, then:
- the ethertype value 0x8847 MUST be used when the top label of
the encapsulated MPLS packet is downstream-assigned,
- the ethertype value 0x8848 MUST be used when the top label of
the encapsulated MPLS packet is upstream-assigned.
Through procedures that are outside the scope of this specification,
it may be known that if the destination address of a GRE packet is a
multicast IP address, then the top label of the GRE payload is
upstream-assigned. In such a case, the occurrence of the 8847
codepoint in a GRE packet with a multicast destination IP address
MUST be considered an error, and the packet MUST be discarded.
7. IP Protocol Number
RFC 4023 is modified as follows: the IPv4 Protocol Number field or
the IPv6 Next Header field is always set to 137, whether or not the
encapsulated MPLS packet is an MPLS multicast packet.
If the IP destination address of the IP encapsulation is an IP
multicast address, the IP tunnel may be considered to be a point-to-
multipoint tunnel or a multipoint-to-multipoint tunnel. In either
case, either all encapsulated MPLS packets in the particular tunnel
have a downstream-assigned label at the top of the stack, or all
encapsulated MPLS packets in that tunnel have an upstream-assigned
label at the top of the stack. The means by which this is determined
for a particular tunnel is outside the scope of this specification.
8. Ethernet MAC DA for Multicast MPLS
When an LSR transmits a multicast MPLS packet in a multicast ethernet
frame, it MUST set the MAC Destination Address to the value
01-00-5e-8v-wx-yz, where vwxyz is a 20-bit (five-nibble) value set as
follows:
1. vwxyz MAY be set to 0,
2. vwxyz MAY be set to the value of one of the MPLS labels on the
packet's label stack.
Which of these procedures is the default procedure in any particular
LSR is implementation-dependent. However, LSRs using the two
different procedures MUST interoperate. That is, an LSR MUST NOT
filter packets for which vwxyz has been set to zero, and it MUST NOT
indiscriminately filter all packets for which vwxyz has not been set
to zero.
If an LSR follows the procedure of setting vwxyz to the value of one
of the MPLS labels on the packet's label stack, and if that label
stack contains two or more labels, then by default, vwxyz MUST be set
to the value of the second MPLS label on the packet's label stack.
By "the second label", we mean the label that is in the label stack
entry that immediately follows the topmost label stack entry. The
LSR MAY, if configured to do so, allow a label other than the second
to be used for this purpose. If the MPLS packet has only one label,
the value of that label will be used instead of the value of the
(non-existent) second label.
It is expected that the LSR will follow the procedures of [RFC5331],
pushing on two labels, with the topmost label being a "context label"
that is the same for all MPLS packets being transmitted by the LSR
onto the ethernet, but with the second label being different for
different LSPs. Thus, if the MAC DA value is a function of the
second label, more of the LSP-specific information about the packet
appears in the MAC DA field. This can be used to filter multicast
packets with "unexpected" non-zero values of vwxyz. Further
discussion of such filtering or its uses is outside the scope of this
document.
The use of ethernet and/or IP broadcast addresses (as distinguished
from multicast addresses) does not fall within the scope of this
specification.
9. IANA Considerations
IANA already owns the set of ethernet multicast addresses in the
range 01-00-5e-00-00-00 to 01-00-5e-ff-ff-ff. Addresses in the range
01-00-5e-00-00-00 to 01-00-5e-7f-ff-ff are already reserved for use
when an ethernet multicast frame carries an IP multicast packet.
IANA has reserved ethernet addresses in the range 01-00-5e-80-00-00
to 01-00-5e-8f-ff-ff for use when an ethernet multicast frame carries
an MPLS multicast packet. Addresses in this range are valid when
used with ethertype 8847 or 8848.
As this document modifies the usage of ethertypes 8847 and 8848, IANA
has changed the description of these ethertypes as follows.
Ethertype 8847 is defined as "MPLS", as defined in RFC 3032 and in
this document. Ethertype 8848 is defined as "MPLS with upstream-
assigned label", as defined in this document.
10. Security Considerations
The security considerations of RFC 3032 and RFC 4023 apply.
Malicious changing of the codepoint may result in loss or misrouting
of packets. However, altering the codepoint without also altering
the label does not result in a predictable effect.
Malicious alteration of the MAC DA on an ethernet can result in
packets being received by a third party, rather than by the intended
recipient.
11. Normative References
[RFC2119] Bradner, S., "Key words for use in RFCs to Indicate
Requirement Levels", BCP 14, RFC 2119, March 1997.
[RFC3031] Rosen, E., Viswanathan, A., and R. Callon, "Multiprotocol
Label Switching Architecture", RFC 3031, January 2001.
[RFC3032] Rosen, E., Tappan, D., Fedorkow, G., Rekhter, Y.,
Farinacci, D., Li, T., and A. Conta, "MPLS Label Stack
Encoding", RFC 3032, January 2001.
[RFC4023] Worster, T., Rekhter, Y., and E. Rosen, Ed., "Encapsulating
MPLS in IP or Generic Routing Encapsulation (GRE)", RFC
4023, March 2005.
[RFC5331] Aggarwal, R., Rekhter, Y., and E. Rosen, "MPLS Upstream
Label Assignment and Context-Specific Label Space", RFC
5331, August 2008.
Authors' Addresses
Toerless Eckert
Cisco Systems, Inc.
170 Tasman Drive
San Jose, CA, 95134
EMail: eckert@cisco.com
Eric C. Rosen
Cisco Systems, Inc.
1414 Massachusetts Avenue
Boxborough, MA 01719
EMail: erosen@cisco.com
Rahul Aggarwal
Juniper Networks
1194 North Mathilda Ave.
Sunnyvale, CA 94089
EMail: rahul@juniper.net
Yakov Rekhter
Juniper Networks
1194 North Mathilda Ave.
Sunnyvale, CA 94089
EMail: yakov@juniper.net
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