Network Working Group T. Bradley
Request for Comments: 1490 Wellfleet Communications, Inc.
Obsoletes: 1294 C. Brown
Wellfleet Communications, Inc.
A. Malis
Ascom Timeplex, Inc.
July 1993
Multiprotocol Interconnect over Frame Relay
Status of this Memo
This RFC specifies an IAB standards track protocol for the Internet
community, and requests discussion and suggestions for improvements.
Please refer to the current edition of the "IAB Official Protocol
Standards" for the standardization state and status of this protocol.
Distribution of this memo is unlimited.
Abstract
This memo describes an encapsulation method for carrying network
interconnect traffic over a Frame Relay backbone. It covers aspects
of both Bridging and Routing. Additionally, it describes a simple
fragmentation procedure for carrying large frames over a frame relay
network with a smaller MTU.
Systems with the ability to transfer both the encapsulation method
described in this document, and others must have a priori knowledge
of which virtual circuits will carry which encapsulation method and
this encapsulation must only be used over virtual circuits that have
been explicitly configured for its use.
Acknowledgements
Comments and contributions from many sources, especially those from
Ray Samora of Proteon, Ken Rehbehn of Netrix Corporation, Fred Baker
and Charles Carvalho of Advanced Computer Communications and Mostafa
Sherif of AT&T have been incorporated into this document. Special
thanks to Dory Leifer of University of Michigan for his contributions
to the resolution of fragmentation issues and Floyd Backes from DEC
and Laura Bridge from Timeplex for their contributions to the
bridging descriptions. This document could not have been completed
without the expertise of the IP over Large Public Data Networks
working group of the IETF.
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RFC 1490 Multiprotocol over Frame Relay July 1993
1. Conventions and Acronyms
The following language conventions are used in the items of
specification in this document:
o Must, Shall or Mandatory -- the item is an absolute
requirement of the specification.
o Should or Recommended -- the item should generally be
followed for all but exceptional circumstances.
o May or Optional -- the item is truly optional and may be
followed or ignored according to the needs of the
implementor.
All drawings in this document are drawn with the left-most bit as the
high order bit for transmission. For example, the dawings might be
labeled as:
Drawings that would be too large to fit onto one page if each octet
were presented on a single line are drawn with two octets per line.
These are also drawn with the left-most bit as the high order bit for
transmission. There will be a "+" to distinguish between octets as
in the following example.
The following are common acronyms used throughout this document.
BECN - Backward Explicit Congestion Notification
BPDU - Bridge Protocol Data Unit
C/R - Command/Response bit
DCE - Data Communication Equipment
DE - Discard Eligibility bit
DTE - Data Terminal Equipment
FECN - Forward Explicit Congestion Notification
PDU - Protocol Data Unit
PTT - Postal Telephone & Telegraph
SNAP - Subnetwork Access Protocol
2. Introduction
The following discussion applies to those devices which serve as end
stations (DTEs) on a public or private Frame Relay network (for
example, provided by a common carrier or PTT. It will not discuss
the behavior of those stations that are considered a part of the
Frame Relay network (DCEs) other than to explain situations in which
the DTE must react.
The Frame Relay network provides a number of virtual circuits that
form the basis for connections between stations attached to the same
Frame Relay network. The resulting set of interconnected devices
forms a private Frame Relay group which may be either fully
interconnected with a complete "mesh" of virtual circuits, or only
partially interconnected. In either case, each virtual circuit is
uniquely identified at each Frame Relay interface by a Data Link
Connection Identifier (DLCI). In most circumstances, DLCIs have
strictly local significance at each Frame Relay interface.
The specifications in this document are intended to apply to both
switched and permanent virtual circuits.
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3. Frame Format
All protocols must encapsulate their packets within a Q.922 Annex A
frame [1,2]. Additionally, frames shall contain information
necessary to identify the protocol carried within the protocol data
unit (PDU), thus allowing the receiver to properly process the
incoming packet. The format shall be as follows:
* Q.922 addresses, as presently defined, are two octets and
contain a 10-bit DLCI. In some networks Q.922 addresses
may optionally be increased to three or four octets.
The control field is the Q.922 control field. The UI (0x03) value is
used unless it is negotiated otherwise. The use of XID (0xAF or
0xBF) is permitted and is discussed later.
The pad field is used to align the remainder of the frame to a two
octet boundary. There may be zero or one pad octet within the pad
field and, if present, must have a value of zero.
The Network Level Protocol ID (NLPID) field is administered by ISO
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RFC 1490 Multiprotocol over Frame Relay July 1993
and CCITT. It contains values for many different protocols including
IP, CLNP and IEEE Subnetwork Access Protocol (SNAP)[10]. This field
tells the receiver what encapsulation or what protocol follows.
Values for this field are defined in ISO/IEC TR 9577 [3]. A NLPID
value of 0x00 is defined within ISO/IEC TR 9577 as the Null Network
Layer or Inactive Set. Since it cannot be distinguished from a pad
field, and because it has no significance within the context of this
encapsulation scheme, a NLPID value of 0x00 is invalid under the
Frame Relay encapsulation. The Appendix contains a list of some of
the more commonly used NLPID values.
There is no commonly implemented minimum maximum frame size for Frame
Relay. A network must, however, support at least a 262 octet
maximum. Generally, the maximum will be greater than or equal to
1600 octets, but each Frame Relay provider will specify an
appropriate value for its network. A Frame Relay DTE, therefore,
must allow the maximum acceptable frame size to be configurable.
The minimum frame size allowed for Frame Relay is five octets between
the opening and closing flags assuming a two octet Q.922 address
field. This minimum increases to six octets for three octet Q.922
address and seven octets for the four octet Q.922 address format.
4. Interconnect Issues
There are two basic types of data packets that travel within the
Frame Relay network: routed packets and bridged packets. These
packets have distinct formats and therefore, must contain an
indicator that the destination may use to correctly interpret the
contents of the frame. This indicator is embedded within the NLPID
and SNAP header information.
For those protocols that do not have a NLPID already assigned, it is
necessary to provide a mechanism to allow easy protocol
identification. There is a NLPID value defined indicating the
presence of a SNAP header.
All stations must be able to accept and properly interpret both the
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RFC 1490 Multiprotocol over Frame Relay July 1993
NLPID encapsulation and the SNAP header encapsulation for a routed
packet.
The three-octet Organizationally Unique Identifier (OUI) identifies
an organization which administers the meaning of the Protocol
Identifier (PID) which follows. Together they identify a distinct
protocol. Note that OUI 0x00-00-00 specifies that the following PID
is an Ethertype.
4.1. Routed Frames
Some protocols will have an assigned NLPID, but because the NLPID
numbering space is so limited, not all protocols have specific NLPID
values assigned to them. When packets of such protocols are routed
over Frame Relay networks, they are sent using the NLPID 0x80 (which
indicates a SNAP follows) followed by SNAP. If the protocol has an
Ethertype assigned, the OUI is 0x00-00-00 (which indicates an
Ethertype follows), and PID is the Ethertype of the protocol in use.
There will be one pad octet to align the protocol data on a two octet
boundary as shown below.
In the few cases when a protocol has an assigned NLPID (see
appendix), 48 bits can be saved using the format below:
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Format of Routed NLPID Protocol
+-------------------------------+
| Q.922 Address |
+---------------+---------------+
|Control 0x03 | NLPID |
+---------------+---------------+
| Protocol Data |
+-------------------------------+
| FCS |
+-------------------------------+
The NLPID encapsulation does not require a pad octet for alignment,
so none is permitted.
In the case of ISO protocols, the NLPID is considered to be the first
octet of the protocol data. It is unnecessary to repeat the NLPID in
this case. The single octet serves both as the demultiplexing value
and as part of the protocol data (refer to "Other Protocols over
Frame Relay for more details). Other protocols, such as IP, have a
NLPID defined (0xCC), but it is not part of the protocol itself.
Format of Routed IP Datagram
+-------------------------------+
| Q.922 Address |
+---------------+---------------+
|Control 0x03 | NLPID 0xCC |
+---------------+---------------+
| IP Datagram |
+-------------------------------+
| FCS |
+-------------------------------+
4.2. Bridged Frames
The second type of Frame Relay traffic is bridged packets. These
packets are encapsulated using the NLPID value of 0x80 indicating
SNAP. As with other SNAP encapsulated protocols, there will be one
pad octet to align the data portion of the encapsulated frame. The
SNAP header which follows the NLPID identifies the format of the
bridged packet. The OUI value used for this encapsulation is the
802.1 organization code 0x00-80-C2. The PID portion of the SNAP
header (the two bytes immediately following the OUI) specifies the
form of the MAC header, which immediately follows the SNAP header.
Additionally, the PID indicates whether the original FCS is preserved
within the bridged frame.
The 802.1 organization has reserved the following values to be used
with Frame Relay:
In addition, the PID value 0x00-0E, when used with OUI 0x00-80-C2,
identifies bridged protocol data units (BPDUs) as defined by
802.1(d) or 802.1(g) [12].
A packet bridged over Frame Relay will, therefore, have one of the
following formats:
Format of Bridged Ethernet/802.3 Frame
+-------------------------------+
| Q.922 Address |
+---------------+---------------+
|Control 0x03 | pad 0x00 |
+---------------+---------------+
| NLPID 0x80 | OUI 0x00 |
+---------------+ --+
| OUI 0x80-C2 |
+-------------------------------+
| PID 0x00-01 or 0x00-07 |
+-------------------------------+
| MAC destination address |
: :
| |
+-------------------------------+
| (remainder of MAC frame) |
+-------------------------------+
| LAN FCS (if PID is 0x00-01) |
+-------------------------------+
| FCS |
+-------------------------------+
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Format of Bridged 802.4 Frame
+-------------------------------+
| Q.922 Address |
+---------------+---------------+
|Control 0x03 | pad 0x00 |
+---------------+---------------+
| NLPID 0x80 | OUI 0x00 |
+---------------+ --+
| OUI 0x80-C2 |
+-------------------------------+
| PID 0x00-02 or 0x00-08 |
+---------------+---------------+
| pad 0x00 | Frame Control |
+---------------+---------------+
| MAC destination address |
: :
| |
+-------------------------------+
| (remainder of MAC frame) |
+-------------------------------+
| LAN FCS (if PID is 0x00-02) |
+-------------------------------+
| FCS |
+-------------------------------+
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Format of Bridged 802.5 Frame
+-------------------------------+
| Q.922 Address |
+---------------+---------------+
|Control 0x03 | pad 0x00 |
+---------------+---------------+
| NLPID 0x80 | OUI 0x00 |
+---------------+ --+
| OUI 0x80-C2 |
+-------------------------------+
| PID 0x00-03 or 0x00-09 |
+---------------+---------------+
| pad 0x00 | Frame Control |
+---------------+---------------+
| MAC destination address |
: :
| |
+-------------------------------+
| (remainder of MAC frame) |
+-------------------------------+
| LAN FCS (if PID is 0x00-03) |
| |
+-------------------------------+
| FCS |
+-------------------------------+
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Format of Bridged FDDI Frame
+-------------------------------+
| Q.922 Address |
+---------------+---------------+
|Control 0x03 | pad 0x00 |
+---------------+---------------+
| NLPID 0x80 | OUI 0x00 |
+---------------+ --+
| OUI 0x80-C2 |
+-------------------------------+
| PID 0x00-04 or 0x00-0A |
+---------------+---------------+
| pad 0x00 | Frame Control |
+---------------+---------------+
| MAC destination address |
: :
| |
+-------------------------------+
| (remainder of MAC frame) |
+-------------------------------+
| LAN FCS (if PID is 0x00-04) |
| |
+-------------------------------+
| FCS |
+-------------------------------+
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RFC 1490 Multiprotocol over Frame Relay July 1993
Format of Bridged 802.6 Frame
+-------------------------------+
| Q.922 Address |
+---------------+---------------+
| Control 0x03 | pad 0x00 |
+---------------+---------------+
| NLPID 0x80 | OUI 0x00 |
+---------------+ --+
| OUI 0x80-C2 |
+-------------------------------+
| PID 0x00-0B |
+---------------+---------------+ -------
| Reserved | BEtag | Common
+---------------+---------------+ PDU
| BAsize | Header
+-------------------------------+ -------
| MAC destination address |
: :
| |
+-------------------------------+
| (remainder of MAC frame) |
+-------------------------------+
| |
+- Common PDU Trailer -+
| |
+-------------------------------+
| FCS |
+-------------------------------+
Note that in bridge 802.6 PDUs, there is only one choice for the PID
value, since the presence of a CRC-32 is indicated by the CIB bit in
the header of the MAC frame.
The Common Protocol Data Unit (CPDU) Header and Trailer are conveyed
to allow pipelining at the egress bridge to an 802.6 subnetwork.
Specifically, the CPDU Header contains the BAsize field, which
contains the length of the PDU. If this field is not available to
the egress 802.6 bridge, then that bridge cannot begin to transmit
the segmented PDU until it has received the entire PDU, calculated
the length, and inserted the length into the BAsize field. If the
field is available, the egress 802.6 bridge can extract the length
from the BAsize field of the Common PDU Header, insert it into the
corresponding field of the first segment, and immediately transmit
the segment onto the 802.6 subnetwork. Thus, the bridge can begin
transmitting the 802.6 PDU before it has received the complete PDU.
One should note that the Common PDU Header and Trailer of the
encapsulated frame should not be simply copied to the outgoing 802.6
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RFC 1490 Multiprotocol over Frame Relay July 1993
subnetwork because the encapsulated BEtag value may conflict with the
previous BEtag value transmitted by that bridge.
Format of BPDU Frame
+-------------------------------+
| Q.922 Address |
+-------------------------------+
| Control 0x03 |
+-------------------------------+
| PAD 0x00 |
+-------------------------------+
| NLPID 0x80 |
+-------------------------------+
| OUI 0x00-80-C2 |
+-------------------------------+
| PID 0x00-0E |
+-------------------------------+
| |
| BPDU as defined by |
| 802.1(d) or 802.1(g)[12] |
| |
+-------------------------------+
4. Data Link Layer Parameter Negotiation
Frame Relay stations may choose to support the Exchange
Identification (XID) specified in Appendix III of Q.922 [1]. This
XID exchange allows the following parameters to be negotiated at the
initialization of a Frame Relay circuit: maximum frame size N201,
retransmission timer T200, and the maximum number of outstanding
Information (I) frames K.
A station may indicate its unwillingness to support acknowledged mode
multiple frame operation by specifying a value of zero for the
maximum window size, K.
If this exchange is not used, these values must be statically
configured by mutual agreement of Data Link Connection (DLC)
endpoints, or must be defaulted to the values specified in Section
5.9 of Q.922:
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RFC 1490 Multiprotocol over Frame Relay July 1993
N201: 260 octets
K: 3 for a 16 Kbps link,
7 for a 64 Kbps link,
32 for a 384 Kbps link,
40 for a 1.536 Mbps or above link
T200: 1.5 seconds [see Q.922 for further details]
If a station supporting XID receives an XID frame, it shall respond
with an XID response. In processing an XID, if the remote maximum
frame size is smaller than the local maximum, the local system shall
reduce the maximum size it uses over this DLC to the remotely
specified value. Note that this shall be done before generating a
response XID.
The following diagram describes the use of XID to specify non-use of
acknowledged mode multiple frame operation.
Fragmentation allows the exchange of packets that are greater than
the maximum frame size supported by the underlying network. In the
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RFC 1490 Multiprotocol over Frame Relay July 1993
case of Frame Relay, the network may support a maximum frame size as
small as 262 octets. Because of this small maximum size, it is
recommended, but not required, to support fragmentation and
reassembly.
Unlike IP fragmentation procedures, the scope of Frame Relay
fragmentation procedure is limited to the boundary (or DTEs) of the
Frame Relay network.
The general format of fragmented packets is the same as any other
encapsulated protocol. The most significant difference being that
the fragmented packet will contain the encapsulation header. That
is, a packet is first encapsulated (with the exception of the address
and control fields) as defined above. Large packets are then broken
up into frames appropriate for the given Frame Relay network and are
encapsulated using the Frame Relay fragmentation format. In this
way, a station receiving fragments may reassemble them and then put
the reassembled packet through the same processing path as a packet
that had not been fragmented.
Within Frame Relay fragments are encapsulated using the SNAP format
with an OUI of 0x00-80-C2 and a PID of 0x00-0D. Individual fragments
will, therefore, have the following format:
The sequence field is a two octet identifier that is incremented
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RFC 1490 Multiprotocol over Frame Relay July 1993
every time a new complete message is fragmented. It allows detection
of lost frames and is set to a random value at initialization.
The reserved field is 4 bits long and is not currently defined. It
must be set to 0.
The final bit is a one bit field set to 1 on the last fragment and
set to 0 for all other fragments.
The offset field is an 11 bit value representing the logical offset
of this fragment in bytes divided by 32. The first fragment must have
an offset of zero.
The following figure shows how a large IP datagram is fragmented over
Frame Relay. In this example, the complete datagram is fragmented
into two Frame Relay frames.
Fragments must be sent in order starting with a zero offset and
ending with the final fragment. These fragments must not be
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RFC 1490 Multiprotocol over Frame Relay July 1993
interrupted with other packets or information intended for the same
DLC. An end station must be able to re-assemble up to 2K octets and
is suggested to support up to 8K octet re-assembly. If at any time
during this re-assembly process, a fragment is corrupted or a
fragment is missing, the entire message is dropped. The upper layer
protocol is responsible for any retransmission in this case. Note
that there is no reassembly timer, nor is one needed. This is
because the Frame Relay service is required to deliver frames in
order.
This fragmentation algorithm is not intended to reliably handle all
possible failure conditions. As with IP fragmentation, there is a
small possibility of reassembly error and delivery of an erroneous
packet. Inclusion of a higher layer checksum greatly reduces this
risk.
7. Address Resolution
There are situations in which a Frame Relay station may wish to
dynamically resolve a protocol address. Address resolution may be
accomplished using the standard Address Resolution Protocol (ARP) [6]
encapsulated within a SNAP encoded Frame Relay packet as follows:
ar$hrd - assigned to Frame Relay is 15 decimal
(0x000F) [7].
ar$pro - see assigned numbers for protocol ID number for
the protocol using ARP. (IP is 0x0800).
ar$hln - length in bytes of the address field (2, 3, or 4)
ar$pln - protocol address length is dependent on the
protocol (ar$pro) (for IP ar$pln is 4).
ar$op - 1 for request and 2 for reply.
ar$sha - Q.922 source hardware address, with C/R, FECN,
BECN, and DE set to zero.
ar$tha - Q.922 target hardware address, with C/R, FECN,
BECN, and DE set to zero.
Because DLCIs within most Frame Relay networks have only local
significance, an end station will not have a specific DLCI assigned
to itself. Therefore, such a station does not have an address to put
into the ARP request or reply. Fortunately, the Frame Relay network
does provide a method for obtaining the correct DLCIs. The solution
proposed for the locally addressed Frame Relay network below will
work equally well for a network where DLCIs have global significance.
The DLCI carried within the Frame Relay header is modified as it
traverses the network. When the packet arrives at its destination,
the DLCI has been set to the value that, from the standpoint of the
receiving station, corresponds to the sending station. For example,
in figure 1 below, if station A were to send a message to station B,
it would place DLCI 50 in the Frame Relay header. When station B
received this message, however, the DLCI would have been modified by
the network and would appear to B as DLCI 70.
If you know about frame relay, you should understand the
correlation between DLCI and Q.922 address. For the uninitiated,
the translation between DLCI and Q.922 address is based on a two
byte address length using the Q.922 encoding format. The format
is:
For ARP and its variants, the FECN, BECN, C/R and DE bits are
assumed to be 0.
When an ARP message reaches a destination, all hardware addresses
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will be invalid. The address found in the frame header will,
however, be correct. Though it does violate the purity of layering,
Frame Relay may use the address in the header as the sender hardware
address. It should also be noted that the target hardware address,
in both ARP request and reply, will also be invalid. This should not
cause problems since ARP does not rely on these fields and in fact,
an implementation may zero fill or ignore the target hardware address
field entirely.
As an example of how this address replacement scheme may work, refer
to figure 1. If station A (protocol address pA) wished to resolve
the address of station B (protocol address pB), it would format an
ARP request with the following values:
ARP request from A
ar$op 1 (request)
ar$sha unknown
ar$spa pA
ar$tha undefined
ar$tpa pB
Because station A will not have a source address associated with it,
the source hardware address field is not valid. Therefore, when the
ARP packet is received, it must extract the correct address from the
Frame Relay header and place it in the source hardware address field.
This way, the ARP request from A will become:
ARP request from A as modified by B
ar$op 1 (request)
ar$sha 0x1061 (DLCI 70) from Frame Relay header
ar$spa pA
ar$tha undefined
ar$tpa pB
Station B's ARP will then be able to store station A's protocol
address and Q.922 address association correctly. Next, station B
will form a reply message. Many implementations simply place the
source addresses from the ARP request into the target addresses and
then fills in the source addresses with its addresses. In this case,
the ARP response would be:
ARP response from B
ar$op 2 (response)
ar$sha unknown
ar$spa pB
ar$tha 0x1061 (DLCI 70)
ar$tpa pA
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Again, the source hardware address is unknown and when the request is
received, station A will extract the address from the Frame Relay
header and place it in the source hardware address field. Therefore,
the response will become:
ARP response from B as modified by A
ar$op 2 (response)
ar$sha 0x0C21 (DLCI 50)
ar$spa pB
ar$tha 0x1061 (DLCI 70)
ar$tpa pA
Station A will now correctly recognize station B having protocol
address pB associated with Q.922 address 0x0C21 (DLCI 50).
Reverse ARP (RARP) [8] will work in exactly the same way. Still
using figure 1, if we assume station C is an address server, the
following RARP exchanges will occur:
RARP request from A RARP request as modified by C
ar$op 3 (RARP request) ar$op 3 (RARP request)
ar$sha unknown ar$sha 0x1401 (DLCI 80)
ar$spa undefined ar$spa undefined
ar$tha 0x0CC1 (DLCI 60) ar$tha 0x0CC1 (DLCI 60)
ar$tpa pC ar$tpa pC
Station C will then look up the protocol address corresponding to
Q.922 address 0x1401 (DLCI 80) and send the RARP response.
RARP response from C RARP response as modified by A
ar$op 4 (RARP response) ar$op 4 (RARP response)
ar$sha unknown ar$sha 0x0CC1 (DLCI 60)
ar$spa pC ar$spa pC
ar$tha 0x1401 (DLCI 80) ar$tha 0x1401 (DLCI 80)
ar$tpa pA ar$tpa pA
This means that the Frame Relay interface must only intervene in the
processing of incoming packets.
In the absence of suitable multicast, ARP may still be implemented.
To do this, the end station simply sends a copy of the ARP request
through each relevant DLC, thereby simulating a broadcast.
The use of multicast addresses in a Frame Relay environment is
presently under study by Frame Relay providers. At such time that
the issues surrounding multicasting are resolved, multicast
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RFC 1490 Multiprotocol over Frame Relay July 1993
addressing may become useful in sending ARP requests and other
"broadcast" messages.
Because of the inefficiencies of broadcasting in a Frame Relay
environment, a new address resolution variation was developed. It is
called Inverse ARP [11] and describes a method for resolving a
protocol address when the hardware address is already known. In
Frame Relay's case, the known hardware address is the DLCI. Using
Inverse ARP for Frame Relay follows the same pattern as ARP and RARP
use. That is the source hardware address is inserted at the
receiving station.
In our example, station A may use Inverse ARP to discover the
protocol address of the station associated with its DLCI 50. The
Inverse ARP request would be as follows:
InARP Request from A (DLCI 50)
ar$op 8 (InARP request)
ar$sha unknown
ar$spa pA
ar$tha 0x0C21 (DLCI 50)
ar$tpa unknown
When Station B receives this packet, it will modify the source
hardware address with the Q.922 address from the Frame Relay header.
This way, the InARP request from A will become:
Station B will format an Inverse ARP response and send it to station
A as it would for any ARP message.
8. IP over Frame Relay
Internet Protocol [9] (IP) datagrams sent over a Frame Relay network
conform to the encapsulation described previously. Within this
context, IP could be encapsulated in two different ways.
Although both of these encapsulations are supported under the given
definitions, it is advantageous to select only one method as the
appropriate mechanism for encapsulating IP data. Therefore, IP data
shall be encapsulated using the NLPID value of 0xCC indicating IP as
shown in option 1 above. This (option 1) is more efficient in
transmission (48 fewer bits), and is consistent with the
encapsulation of IP in X.25.
9. Other Protocols over Frame Relay
As with IP encapsulation, there are alternate ways to transmit
various protocols within the scope of this definition. To eliminate
the conflicts, the SNAP encapsulation is only used if no NLPID value
is defined for the given protocol.
As an example of how this works, ISO CLNP has a NLPID defined (0x81).
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RFC 1490 Multiprotocol over Frame Relay July 1993
Therefore, the NLPID field will indicate ISO CLNP and the data packet
will follow immediately. The frame would be as follows:
In this example, the NLPID is used to identify the data packet as
CLNP. It is also considered part of the CLNP packet and as such, the
NLPID should not be removed before being sent to the upper layers for
processing. The NLPID is not duplicated.
Other protocols, such as IPX, do not have a NLPID value defined. As
mentioned above, IPX would be encapsulated using the SNAP header. In
this case, the frame would be as follows:
The model for bridging in a Frame Relay network is identical to the
model for remote bridging as described in IEEE P802.1g "Remote MAC
Bridging" [13] and supports the concept of "Virtual Ports". Remote
bridges with LAN ports receive and transmit MAC frames to and from
the LANS to which they are attached. They may also receive and
transmit MAC frames through virtual ports to and from other remote
bridges. A virtual port may represent an abstraction of a remote
bridge's point of access to one, two or more other remote bridges.
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Remote Bridges are statically configured as members of a remote
bridge group by management. All members of a remote bridge group are
connected by one or more virtual ports. The set of remote MAC bridges
in a remote bridge group provides actual or *potential* MAC layer
interconnection between a set of LANs and other remote bridge groups
to which the remote bridges attach.
In a Frame Relay network there must be a full mesh of Frame Relay VCs
between bridges of a remote bridge group. If the frame relay network
is not a full mesh, then the bridge network must be divided into
multiple remote bridge groups.
The frame relay VCs that interconnect the bridges of a remote bridge
group may be combined or used individually to form one or more
virtual bridge ports. This gives flexibility to treat the Frame
Relay interface either as a single virtual bridge port, with all VCs
in a group, or as a collection of bridge ports (individual or grouped
VCs).
When a single virtual bridge port provides the interconnectivity for
all bridges of a given remote bridge group (i.e. all VCs are combined
into a single virtual port), the standard Spanning Tree Algorithm may
be used to determine the state of the virtual port. When more than
one virtual port is configured within a given remote bridge group
then an "extended" Spanning Tree Algorithm is required. Such an
extended algorithm is defined in IEEE 802.1g [13]. The operation of
this algorithm is such that a virtual port is only put into backup if
there is a loop in the network external to the remote bridge group.
The simplest bridge configuration for a Frame Relay network is the
LAN view where all VCs are combined into a single virtual port.
Frames, such as BPDUs, which would be broadcast on a LAN, must be
flooded to each VC (or multicast if the service is developed for
Frame Relay services). Flooding is performed by sending the packet to
each relevant DLC associated with the Frame Relay interface. The VCs
in this environment are generally invisible to the bridge. That is,
the bridge sends a flooded frame to the frame relay interface and
does not "see" that the frame is being forwarded to each VC
individually. If all participating bridges are fully connected (full
mesh) the standard Spanning Tree Algorithm will suffice in this
configuration.
Typically LAN bridges learn which interface a particular end station
may be reached on by associating a MAC address with a bridge port.
In a Frame Relay network configured for the LAN-like single bridge
port (or any set of VCs grouped together to form a single bridge
port), however, the bridge must not only associated a MAC address
with a bridge port, but it must also associate it with a connection
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identifier. For Frame Relay networks, this connection identifier is
a DLCI. It is unreasonable and perhaps impossible to require bridges
to statically configure an association of every possible destination
MAC address with a DLC. Therefore, Frame Relay LAN-modeled bridges
must provide a mechanism to allow the Frame Relay bridge port to
dynamically learn the associations. To accomplish this dynamic
learning, a bridged packet shall conform to the encapsulation
described within section 7. In this way, the receiving Frame Relay
interface will know to look into the bridged packet to gather the
appropriate information.
A second Frame Relay bridging approach, the point-to-point view,
treats each Frame Relay VC as a separate bridge port. Flooding and
forwarding packets are significantly less complicated using the
point-to-point approach because each bridge port has only one
destination. There is no need to perform artificial flooding or to
associate DLCIs with destination MAC addresses. Depending upon the
interconnection of the VCs, an extended Spanning Tree algorithm may
be required to permit all virtual ports to remain active as long as
there are no true loops in the topology external to the remote bridge
group.
It is also possible to combine the LAN view and the point-to-point
view on a single Frame Relay interface. To do this, certain VCs are
combined to form a single virtual bridge port while other VCs are
independent bridge ports.
The following drawing illustrates the different possible bridging
configurations. The dashed lines between boxes represent virtual
circuits.
+-------+
-------------------| B |
/ -------| |
/ / +-------+
/ |
+-------+/ \ +-------+
| A | -------| C |
| |-----------------------| |
+-------+\ +-------+
\
\ +-------+
\ | D |
-------------------| |
+-------+
Since there is less than a full mesh of VCs between the bridges in
this example, the network must be divided into more than one remote
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bridge group. A reasonable configuration is to have bridges A, B,
and C in one group, and have bridges A and D in a second.
Configuration of the first bridge group combines the VCs
interconnection the three bridges (A, B, and C) into a single virtual
port. This is an example of the LAN view configuration. The second
group would also be a single virtual port which simply connects
bridges A and D. In this configuration the standard Spanning Tree
Algorithm is sufficient to detect loops.
An alternative configuration has three individual virtual ports in
the first group corresponding to the VCs interconnecting bridges A, B
and C. Since the application of the standard Spanning Tree Algorithm
to this configuration would detect a loop in the topology, an
extended Spanning Tree Algorithm would have to be used in order for
all virtual ports to be kept active. Note that the second group
would still consist of a single virtual port and the standard
Spanning Tree Algorithm could be used in this group.
Using the same drawing, one could construct a remote bridge scenario
with three bridge groups. This would be an example of the point-to-
point case. Here, the VC connecting A and B, the VC connecting A and
C, and the VC connecting A and D are all bridge groups with a single
virtual port.
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11. Appendix A
List of Commonly Used NLPIDs
0x00 Null Network Layer or Inactive Set
(not used with Frame Relay)
0x80 SNAP
0x81 ISO CLNP
0x82 ISO ESIS
0x83 ISO ISIS
0xCC Internet IP
List of PIDs of OUI 00-80-C2
with preserved FCS w/o preserved FCS Media
------------------ ----------------- --------------
0x00-01 0x00-07 802.3/Ethernet
0x00-02 0x00-08 802.4
0x00-03 0x00-09 802.5
0x00-04 0x00-0A FDDI
0x00-0B 802.6
0x00-0D Fragments
0x00-0E BPDUs as defined by
802.1(d) or
802.1(g)[12].
12. Appendix B - Connection Oriented procedures.
This appendix contains additional information and instructions for
using CCITT Q.933 and other CCITT standards for encapsulating data
over frame relay. The information contained here is similar (and in
some cases identical) to that found in Annex F to ANSI T1.617 written
by Rao Cherukuri of IBM. The authoritative source for this
information is in Annex F and is repeated here only for convenience.
The Network Level Protocol ID (NLPID) field is administered by ISO
and CCITT. It contains values for many different protocols including
IP, CLNP (ISO 8473) CCITT Q.933, and ISO 8208. A figure summarizing
a generic encapsulation technique over frame relay networks follows.
The scheme's flexibility consists in the identification of multiple
alternative to identify different protocols used either by
- end-to-end systems or
- LAN to LAN bride and routers or
- a combination of the above.
For those protocols which do not have a NLPID assigned or do not have
a SNAP encapsulation, the NLPID value of 0x08, indicating CCITT
Recommendation Q.933 should be used. The four octets following the
NLPID include both layer 2 and layer 3 protocol identification. The
code points for most protocols are currently defined in ANSI T1.617
low layer compatibility information element. There is also an escape
for defining non-standard protocols.
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Format of Other Protocols
using Q.933 NLPID
+-------------------------------+
| Q.922 Address |
+---------------+---------------+
|Control 0x03 | NLPID 0x08 |
+---------------+---------------+
| L2 Protocol ID |
| octet 1 | octet 2 |
+-------------------------------+
| L3 Protocol ID |
| octet 2 | octet 2 |
+-------------------------------+
| Protocol Data |
+-------------------------------+
| FCS |
+-------------------------------+
Note 1: Indicates the code point for user specified
layer 3 protocol.
Note 2: Control field is two octets for I-format and
S-format frames (see 88002/2)
Encapsulations using I frame (layer 2)
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The Q.922 I frame is for supporting layer 3 protocols which require
acknowledged data link layer (e.g., ISO 8208). The C/R bit (T1.618
address) will be used for command and response indications.
Format of ISO 8208 frame
Modulo 8
+-------------------------------+
| Q.922 Address |
+---------------+---------------+
| ....Control I frame |
+---------------+---------------+
| 8208 packet (modulo 8) Note 3 |
| |
+-------------------------------+
| FCS |
+-------------------------------+
Note 3: First octet of 8208 packet also identifies the
NLPID which is "..01....".
Format of ISO 8208 frame
Modulo 128
+-------------------------------+
| Q.922 Address |
+---------------+---------------+
| ....Control I frame |
+---------------+---------------+
| 8208 packet (modulo 128) |
| Note 4 |
+-------------------------------+
| FCS |
+-------------------------------+
Note 4: First octet of 8208 packet also identifies the
NLPID which is "..10....".
13. References
[1] International Telegraph and Telephone Consultative Committee,
"ISDN Data Link Layer Specification for Frame Mode Bearer
Services", CCITT Recommendation Q.922, 19 April 1991.
[2] American National Standard For Telecommunications - Integrated
Services Digital Network - Core Aspects of Frame Protocol for Use
with Frame Relay Bearer Service, ANSI T1.618-1991, 18 June 1991.
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RFC 1490 Multiprotocol over Frame Relay July 1993
[3] Information technology - Telecommunications and Information
Exchange between systems - Protocol Identification in the Network
Layer, ISO/IEC TR 9577: 1990 (E) 1990-10-15.
[4] Baker, F., Editor, "Point to Point Protocol Extensions for
Bridging", RFC 1220, ACC, April 1991.
[5] International Standard, Information Processing Systems - Local
Area Networks - Logical Link Control, ISO 8802-2: 1989 (E), IEEE
Std 802.2-1989, 1989-12-31.
[6] Plummer, D., "An Ethernet Address Resolution Protocol - or -
Converting Network Protocol Addresses to 48.bit Ethernet Address
for Transmission on Ethernet Hardware", STD 37, RFC 826, MIT,
November 1982.
[7] Reynolds, J. and J. Postel, "Assigned Numbers", STD 2, RFC 1340,
USC/Information Sciences Institute, July 1992.
[8] Finlayson, R., Mann, R., Mogul, J., and M. Theimer, "A Reverse
Address Resolution Protocol", STD 38, RFC 903, Stanford
University, June 1984.
[9] Postel, J. and Reynolds, J., "A Standard for the Transmission of
IP Datagrams over IEEE 802 Networks", RFC 1042, USC/Information
Sciences Institute, February 1988.
[10] IEEE, "IEEE Standard for Local and Metropolitan Area Networks:
Overview and architecture", IEEE Standards 802-1990.
[11] Bradley, T., and C. Brown, "Inverse Address Resolution Protocol",
RFC 1293, Wellfleet Communications, Inc., January 1992.
[12] IEEE, "IEEE Standard for Local and Metropolitan Networks: Media
Access Control (MAC) Bridges", IEEE Standard 802.1D-1990.
[13] PROJECT 802 - LOCAL AND METROPOLITAN AREA NETWORKS, Draft
Standard 802.1G: Remote MAC Bridging, Draft 6, October 12, 1992.
14. Security Considerations
Security issues are not discussed in this memo.
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15. Authors' Addresses
Terry Bradley
Wellfleet Communications, Inc.
15 Crosby Drive
Bedford, MA 01730
