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From: "James V. Luciani" <luciani@BayNetworks.com>
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Date: Sat, 22 Jun 1996 16:58:58 -0400
Folks....
I was not able to send this rev of the SCSP draft in on time and it will not
be showing up prior to the meeting on Monday. My sincere apologies for
the tardiness.
This rev includes support for pt-mpt and running SCSP as a standalone
protocol. It also includes some text to clarify (hopefully) some areas
of confusion.
I did not have a chance to to run this by the other co-authors so
Mea Culpa for any major errors introduced in this rev.
--JIm
----------------------------cut here---------------------------------
�
Routing Over Large Clouds Working Group James V. Luciani
INTERNET-DRAFT (Bay Networks)
<draft-luciani-rolc-scsp-03.txt> Grenville Armitage
(Bellcore)
Joel Halpern
(Newbridge)
Expires December 1996
Server Cache Synchronization Protocol (SCSP) - NBMA
Status of this Memo
This document is an Internet-Draft. Internet-Drafts are working
documents of the Internet Engineering Task Force (IETF), its areas,
and its working groups. Note that other groups may also distribute
working documents as Internet-Drafts.
Internet-Drafts are draft documents valid for a maximum of six months
and may be updated, replaced, or obsoleted by other documents at any
time. It is inappropriate to use Internet-Drafts as reference
material or to cite them other than as ``work in progress.''
To learn the current status of any Internet-Draft, please check the
``1id-abstracts.txt'' listing contained in the Internet-Drafts Shadow
Directories on ds.internic.net (US East Coast), nic.nordu.net
(Europe), ftp.isi.edu (US West Coast), or munnari.oz.au (Pacific
Rim).
Abstract
This document describes the Server Cache Synchronization Protocol
(SCSP) for Non Broadcast Multiple Access (NBMA) networks. SCSP
attempts to solve the generalized server synchronization/cache-
replication problem wherein a set of server entities which are bound
to a Server Group (SG) through some means (e.g., all servers
belonging to the same Logical IP Subnet (LIS)[1]) wish to synchronize
the contents (or a portion thereof) of their caches. These caches
contain information on the state of the clients within the scope of
interest of the SG. An example of types of information that must be
synchronized can be seen in NHRP using IP where the information
includes the REGISTERED clients' IP to NBMA mappings in the SG LIS.
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1. Introduction
It is perhaps an obvious goal for any protocol to not limit itself to
a single point of failure such as having a single server in a
client/server paradigm. Even when there are redundant servers, there
still remains the problem of cache synchronization; i.e., when one
server becomes aware of a change in state of cache information then
that server must propagate the knowledge of the change in state to
all servers which are actively mirroring that state information.
Further, this must be done in a timely fashion without putting undo
resource strains on the servers. Assuming that the state information
kept in the server cache is the state of clients of the server, then
in order to minimize the burden placed upon the client it is also
highly desirable that clients need not have complete knowledge of all
servers which they may use. However, any mechanism for
synchronization should not preclude a client from having access to
several (or all) servers. Of course, any solution must be reasonably
scalable, capable of using some autoconfiguration service, and lend
itself to a wide range of authentication methodologies
This document describes the Server Cache Synchronization Protocol
(SCSP). SCSP solves the generalized server synchronization/cache-
replication problem while addressing the issues described above.
SCSP synchronizes caches (or a portion of the caches) of a set of
server entities which are bound to a Server Group (SG) through some
means (e.g., all NHRP servers belonging to a Logical IP Subnet
(LIS)[1]) and may exist in any topology as long as the resultant
graph spans the set of servers that need to be synchronized. These
caches contain information on the state of the clients within the
scope of interest of the SG. An example of types of information that
must be synchronized can be seen in NHRP[2] using IP where the
information includes the REGISTERED clients' IP to NBMA mappings in
the SG LIS.
Only the first few pages of this document constitute the SCSP
description proper. However, this document also includes a
description of the use of SCSP by a number of protocols (e.g., NHRP,
ATMARP, etc.) and some optional functionality which may be
implemented as deemed appropriate. It is hoped that these appendices
will spark interest in applying SCSP to the server synchronization
needs of other protocols by supplying examples of SCSP's use.
2. Overview
SCSP places no topological requirements upon upon the SG. Obviously,
however, the resultant graph must span the set of servers to be
synchronized. SCSP borrows heavily from the link state protocols
[3,4]. However, unlike those technologies, there is no Shortest Path
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First (SPF) calculation and there is little or no additional memory
requirements imposed above and beyond that which is required to save
the cached information which would exist regardless of the
synchronization technology.
In order to give a frame of reference for the following discussion,
the terms Local Server (LS), Directly Connected Server (DCS), and
Remote Server (RS) are introduced. The LS is the server under
scrutiny; i.e., all statements are made from the perspective of the
LS when discussing the SCSP protocol. The DCS is a server which is
directly connected to the LS; e.g., there exists a VC between the LS
and DCS. Thus, every server is a DCS with respect to every other
server which connects to it directly, and every server is an LS which
has zero or more DCSs directly connected to it. An RS is a server
that is neither an LS nor a DCS; i.e, an RS is always two or more
hops away from an LS (whereas a DCS is always one hop away from an
LS).
SCSP contains three sub protocols: the "Hello" protocol, the "Cache
Alignment" protocol, and the "Client State Update" protocol. The
"Hello" protocol is used to ascertain whether a DCS is operational
and whether the connection between the LS and DCS is bidirectional,
unidirectional, or non-functional. The "Cache Alignment" (CA)
protocol allows an LS to synchronize its entire cache with that of
the cache of its DCSs. The "Client State Update" (CSU) protocol is
used to update the state of cache entries in servers for a given SG.
Sections 2.1, 2.2, and 2.3 contain a more in depth explanation of the
Hello, CA, and CSU protocols and the messages they use.
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+---------------+
| |
+-------@| DOWN |@-------+
| | | |
| +---------------+ |
| | @ |
| | | |
| | | |
| | | |
| @ | |
| +---------------+ |
| | | |
| | WAITING | |
| +--| |--+ |
| | +---------------+ | |
| | @ @ | |
| | | | | |
| @ | | @ |
+---------------+ +---------------+
| BIDIRECTION |----@| UNIDIRECTION |
| | | |
| CONNECTION |@----| CONNECTION |
+---------------+ +---------------+
Figure 1: Hello Finite State Machine (HFSM)
2.1 Hello Protocol
"Hello" messages ascertain whether a DCS is operational and whether
the connections between the LS and DCS are bidirectional,
unidirectional, or non-functional. Every LS MUST periodically send
Hello messages to each of its DCSs. An LS must be configured with a
list of DCS NBMA addresses. The mechanism for this configuration is
beyond the scope of this document although one possible mechanisms
would be an autoconfiguration server.
An LS has a Hello Finite State Machine (HFSM) associated with each of
its DCSs (see Figure 1) for each SG. Thus, for example, if a
particular connection has two servers connected by a point to point
connection and each server belongs to two server groups then each
server has two HFSMs running (one per SG). The HFSM monitors the
state of the connectivity between the LS and a particular DCS. The
HFSM starts in the "Down" State and transitions to the "Waiting"
State after NBMA level connectivity has been established. Once in
the Waiting State, the LS starts sending Hello messages to the DCS.
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The Hello message includes: a Sender ID which is set to the LS's ID
(LSID), zero or more Receiver IDs which identify the DCSs from which
the LS has heard a Hello message, and a HelloInterval and DeadFactor
which will be described below. At this point, the DCS may or may not
be sending its own Hello messages to the LS. In either case, upon
receiving the LS's Hello, the DCS copies the LSID from the Sender ID
(SID) field of the LS's Hello message. When the DCS sends its next
Hello, the DCS will includes the LSID in one of the Receiver ID
fields, it will increment the "Number of Receiver IDs Heard" count
and place its own ID (the DCSID) in the Sender ID field. When the LS
receives the DCS's Hello message, it will know that the DCS has
received the LS's Hello message and thus bidirectional communication
is possible at which point the HFSM transitions from the Waiting
State to the "Bidirectional Connection" State.
If an LS which is not in the down state receives a Hello message from
a DCS and that message does not have the LSID in one of the Receiver
ID fields then the HFSM for that DCS transitions to the
"Unidirectional Connection" State. If while in the Unidirectional
State, the LS receives a subsequent Hello message from that DCS and
that message contains a Receiver ID equal to the LSID then the HFSM
transitions to the Bidirectional Connection State. Any abnormal
event, such as receiving a malformed Hello message, causes the HFSM
to transition to the Waiting State; however, a loss of NBMA
connectivity causes the HFSM to transition to the Down State.
Hello messages also contain a HelloInterval and a DeadFactor. The
Hello interval advertises the time between sending of consecutive
Hello messages by a server. That is, if the time between reception
of Hello messages from a DCS exceeds the HelloInterval advertised by
that DCS then the next Hello message is to be considered late by the
LS. If the LS does not receive a Hello message within the interval
HelloInterval*DeadFactor seconds then the LS MUST consider the DCS to
be stalled at which point the LS should transition the HFSM for that
DCS to the Waiting State and remove the DCSID from the Receiver ID
list. Note that the Hello Protocol is on a per SG basis. Note also
that a list of Receiver IDs has been included in the Hello Protocol
so that it could leverage point to multipoint connections; there is
still one HFSM per DCS however.
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+------------+
| |
+---@| DOWN |
| | |
| +------------+
| |
| |
| @
| +------------+
| |Master/Slave|
|----| |@---+
| |Negotiation | |
| +------------+ |
| | |
| | |
| @ |
| +------------+ |
| | Cache | |
|----| |----|
| | Summarize | |
| +------------+ |
| | |
| | |
| @ |
| +------------+ |
| | Update | |
|----| |----|
| | Cache | |
| +------------+ |
| | |
| | |
| @ |
| +------------+ |
| | | |
+----| Aligned |----+
| |
+------------+
Figure 2: Cache Alignment Finite State Machine
2.2 Cache Alignment Protocol
"Cache Alignment" (CA) messages allow an LS to synchronize its entire
cache with that of the cache of its DCSs. That is, CA messages allow
a booting LS to synchronize with its DCSs. A CA message contains a
CA header followed by zero or more Client State Advertisement Summary
records (CSAS records).
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An LS has a Cache Alignment Finite State Machine (CAFSM) associated
(see Figure 2) with each of its DCSs on a per SG basis. Thus, for
example, if a particular connection has two servers connected by a
point to point connection and each server belongs to two server
groups then each server has two CAFSMs running (one per SG). The
CAFSM starts in the Down State. When the HFSM reaches the
Bidirectional State, the CAFSM transitions to the Master/Slave
Negotiation State. The Master/Slave Negotiation State causes either
the LS or DCS to take on the role of master over the cache alignment
process.
When the LS's CAFSM reaches the Master/Slave Negotiation State, the
LS will send a CA message to the DCS associated with the CAFSM. The
first CA message which the LS sends includes no CSAS records and a CA
header which contains the LSID in the Sender ID field, the DCSID in
the Receiver ID field, a sequence number, and three bits. These
three bits are the M (Master/Slave) bit, the I (Initialization of
master) bit, and the O (More) bit. In the first CA message sent by
the LS to a particular DCS, the M, O, and I bits are set to one. If
the LS does not receive a CA message from the DCS in CAReXmtInterval
seconds then it resends the CA message it just sent. The LS
continues to do this until the CAFSM transitions to the Cache
Summarize State or until the HFSM transitions out of the
Bidirectional State. Any time the HFSM transitions out of the
Bidirectional State, the CAFSM transitions to the Down State.
When the LS receives a CA message from the DCS while in the
Master/Slave Negotiation State, the role the LS plays in the exchange
depends on packet processing as follows:
1) If the CA from the DCS has the M, I, and O bits set to one and there are
no CSAS records in the CA message and the SenderID as specified in the
DCS's CA is larger than the LSID then
a) The timer counting down the CAReXmtInterval is stopped.
b) The CAFSM corresponding to that DCS transitions to the Cache Summarize
State and the LS takes on the role of slave.
c) The LS adopts the sequence number it received in the CA message as its
own sequence number.
d) The LS sends a CA message to the DCS which is formated as follows:
the M and I bits are set to zero, the Sender ID field is set to the
LSID, the Receiver ID field is set to the DCSID, and the sequence
number is set to the sequence number that appeared in the DCS's
CA message. If there are CSAS records to be sent (i.e., if the LS's
cache is not empty) then the O bit is set to one and the initial set
of CSAS records are included in the CA message.
2) If the CA message from the DCS has the M and I bits off and the Sender ID
as specified in the DCS's CA message is smaller than the LSID then
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a) The timer counting down the CAReXmtInterval is stopped.
b) The CAFSM corresponding to that DCS transitions to the Cache Summarize
State and the LS takes on the role of master.
c) The LS must process any CSAS records in the received CA.
An explanation of record processing is given below.
d) The LS sends a CA message to the DCS which is formated as follows:
the M bit is set to one, I bit is set to zero, the Sender ID
field is set to the LSID, the Receiver ID field is set to the DCSID,
and the LS's current sequence number is incremented by one and placed
in the CA message. If there are any CSAS records to be sent from the
LS to the DCS (i.e., if the LS's cache is not empty) then the O bit is
set to one and the initial set of CSAS records are included in the
CA message that the LS is sending to the DCS.
3) Otherwise, the packet must be ignored.
At any given time, the master or slave have at most one outstanding
CA message. Once the LS's CAFSM has transitioned to the Cache
Summarize State the sequence of exchanges of CA messages occurs as
follows.
1) If the LS receives a CA message with the M bit set incorrectly
(e.g., the M bit is set in the CA of the DCS and the LS is master)
or if the I bit is set then the CAFSM transitions back to the
Master/Slave Negotiation State.
2) If the LS is master and the LS receives a CA message with a sequence
number which is one less than the LS's current sequence number then
the message is a duplicate and the message MUST be discarded.
3) If the LS is master and the LS receives a CA message with a sequence
number which is equal to the LS's current sequence number then the
CA message MUST be processed. An explanation of message processing
is given below. As a result of having received the CA message from
the DCS the following will occur:
a) The timer counting down the CAReXmtInterval is stopped.
b) The LS must process any CSAS records in the received CA message.
c) Increment the LS's sequence number by one.
d) The cache exchange continues as follows:
1) If the LS has no more CSAS records to send and the received CA
message has the O bit off then the CAFSM transitions to the Update
Cache State.
2) If the LS has no more CSAS records to send and the received CA
message has the O bit on then the LS sends back a CA message
(with new sequence number) which contains no CSAS records and
with the O bit off. Reset the timer counting down the
CAReXmtInterval.
3) If the LS has more CSAS records to send then the LS sends the next
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CA message with the LS's next set of CSAS records. If LS is sending
its last set of CSAS records then the O bit is set off otherwise the
O bit is set on. Reset the timer counting down the CAReXmtInterval.
4) If the LS is slave and the LS receives a CA message with a sequence
number which is equal to the LS's current sequence number then the
CA message is a duplicate and the LS MUST resend the CA message
which it had just sent to the DCS.
5) If the LS is slave and the LS receives a CA message with a sequence
number which is one more than the LS's current sequence number then
the message is valid and MUST be processed. An explanation of message
processing is given below. As a result of having received the CA
message from the DCS the following will occur:
a) The LS must process any CSAS records in the received CA message.
b) Set the LS's sequence number to the sequence number in the CA
message.
c) The cache exchange continues as follows:
1) If the LS had just sent a CA message with the O bit off and the
received CA message has the O bit off then the CAFSM transitions to
the Update Cache State and the LS sends a CA message with no CSAS
records and with the O bit off.
2) If the LS still has CSAS records to send then the LS MUST send
a CA message with CSAS records in it. If the message being sent
from the LS to the DCS contains the last CSAS records that the
LS needs to send then the CA is sent with the O bit off.
6) If the LS is slave and the LS receives a CA message with a sequence
that is neither equal to or one more than the current LS's sequence
number then an error has occurred and the CAFSM transitions to the
Master/Slave Negotiation State.
CA message processing occurs as follows:
The LS makes a list of those cache entries which are more "up to
date" in the DCS than the LS's own cache. A CSA record is more "up
to date" than the corresponding cache entry in the LS if
1) the sequence number in the CSA record is "larger than that found in the
LS's corresponding cache entry
2) the combination of the Client ID and CSA Originator ID do not exist
in the LS's cache
During this process, the DCS makes a similar list with respect to the
LS. The previously mentioned list is called the CSA Request List
(CRL). If the CRL of the LS is empty upon transition into the Update
Cache State then the CAFSM immediately transitions into the Aligned
State. If the CRL is not empty then the LS solicits the relevant CSA
records from the DCS associated with the CAFSM and when the LS has
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all the updated CSA record information it transitions into the
Aligned State. The LS solicits the relevant CSA records by forming
CSU Solicit (CSUS) messages from the CRL. CSUS messages contain a
CSUS header and CSAS records from the CRL. The LS then sends the
CSUS messages to the DCS. The DCS responds to the CSUS messages by
sending CSU messages containing the appropriate CSA records to the
LS. The DCS acts in a similar manner as does the LS with respect to
acquiring updated CSA records for the CSAS records in the CRL. In
this way, both LS and DCS databases are synchronized. At most one
CSUS message will be outstanding at any given time.
Just before the first CSUS message is sent from an LS to the DCS
associated with the CAFSM, a timer is set to CSUSReXmtInterval
seconds. If all the CSA records corresponding to the CSAS records in
the CSUS message have not been received by the time that the timer
expires then a new CSUS message will be created which includes all
the outstanding CSA records plus additional CSAS records not covered
in the previous CSUS message. The new CSUS message is then sent to
the DCS. If, at some point before the timer expires, all CSA record
updates have been received for all the CSAS records included in the
previously sent CSUS message then the timer is stopped and if there
are additional CSAS records that were not covered in the previous
CSUS message but were in the CRL then the timer is reset and a new
CSUS message is created which contains CSAS records from the CRL
which have not yet been sent to the DCS. This process continues
until all the CSAS records that were in the CRL have been updated in
the LS. When the LS has a completely updated cache then the LS's
CAFSM transitions to the Aligned State as previously mentioned.
If an LS receives a CSUS message or a CA message with a Receiver ID
which is not the LSID and is not zero then the message must be
discarded and ignored. This is necessary since cache alignment is
done on a per SG per server basis and if a point to multipoint
connection exists and/or if the given connection is being used to
keep multiple SGs synchronized then an LS will receive CA and CSUS
messages which are bound for another server and/or another SG. It
may be possible to specify a Receiver ID of zero which says that the
CA or CSUS message applies to all servers in the SG specified which
are reachable through the given connection; this usage is for futher
study.
2.3. Client State Update Protocol
"Client State Update" (CSU) messages are used to update the state of
cache entries in servers. CSU messages contain zero or more "Client
State Advertisement" (CSA) records each of which contains a SGID in
the record. Thus CSU messages may service more than one SG as long
as the sending and receiving servers in a given SG have a CAFSM in
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the Aligned state (or sometimes the Update Cache state). This is a
fundamental difference between the CSU protocol and either the Hello
protocol or the Cache Alignment protocol. An LS may send/receive a
CSU to/from a DCS only when the corresponding CAFSM is in either the
Aligned State or the Update Cache State.
A CSU message is sent from an LS to each of its DCSs when the LS
observes changes in the state of one or more clients in the SG. The
change in state of a particular client is noted in a CSU message via
a CSA record within the CSU. In this way, state changes are
propagated throughout the SG.
Examples of such changes in state are as follows:
1) an LS receives a request to add an entry to its cache
(e.g., NHRP Registration Request or an administrative
intervention),
2) an LS receives a request to remove an entry from its cache
(e.g., NHRP Purge Request or administrative intervention),
3) a cache entry has timed out in the LS's cache, has been refreshed
in the LS's cache, or has been administratively modified
(e.g., in NHRP, an Internetworking address to NBMA address binding
has timed out or has been refreshed).
After receiving a CSU, an LS acknowledges it by sending a CSU Reply.
Each CSA which the LS has not already seen is propagated to each of
the "appropriate" DCSs. The choice of which DCSs to which the CSU
needs to be propagated is specific to the instance of SCSP being
executed; i.e., one instance of SCSP might require that the CSU is
propagated to every DCS except the DCS from which the LS originally
received the CSU while another instance of SCSP might choose to
propagate the CSU to only specific DCSs (e.g., this would be the case
if the database being synchronized is one which is encompassed within
LNNI[6]).
A LS responds to CSUS messages by sending CSU messages containing the
appropriate CSA records to the DCS.
If an LS receives a CSUS message containing a CSAS record for an
entry which is no longer in its database (e.g., the entry timed out
and was discarded after the Cache Alignment exchange completed but
before the entry was requested through a CSUS message), then the LS
will respond with a CSU message containing a CSA record which
indicates a client state of "client entry does not exist" as
appropriate for the protocol being synchronized.
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If an LS receives a CSU with a Receiver ID which is not equal to the
LSID and is not zero then the CSU must be disgarded and ignored.
This is necessary since the LS may be a leaf of a point to multipoint
connection. It may be possible to specify a Receiver ID of zero which
says that the CSU message applies to all servers in the SG specified
which are reachable through the given connection; this usage is for
futher study.
Conclusions
While the above text is couched in terms of synchronizing the
knowledge of the state of a client within the cache of servers
contained in a server grouping, this solution generalizes easily to
any number of database synchronization problems (e.g., LECS
synchronization). In such a case, the Client ID (CID) and Client
state would be replaced by a unique token and an octet string
describing the database entry being synchronized. The appendices
below show examples of how SCSP is to be implemented for the
specified protocols.
Appendix A: Terminology
This appendix introduces the terminology associated with SCSP.
A.1 Abbreviations
CA - Cache Alignment Message
CAFSM - Cache Alignment Finite State Machine
CID - Client ID
CRL - CSA Request List
CSA - Client State Advertisement
CSAS - Client State Advertisement Summary
CSU - Client State Update
CSUS - Client State Update Solicit
DCS - Directly Connected Server
HFSM - Hello Finite State Machine
I - Initialize bit
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LS - Local Server
LSID - Local Server ID
M - Master/Slave bit
O - More bit
RS - Remote Server
SG - Server Group
SID - Server ID
A.2 Definitions
Cache Alignment message (CA message)
These messages allow an LS to synchronize its entire cache
with that of the cache of one of its DCSs.
Cache Alignment Finite State Machine (CAFSM)
The CAFSM monitors the state of the cache alignment between an LS
and a particular DCS. There exists one CAFSM per DCS as seen from
an LS.
Client ID (CID)
The CID is an unique token which identifies a client whose state
is being kept in a server's cache. This value
might be taken from the protocol address of the client.
CSA Request List (CRL)
When CA messages are exchanged between an LS and one of its DCSs,
the LS makes a list of those cache entries which are more recent
in the DCS (based on a CSAS sequence number) than the LS's own
entry and adds to that list any entry in the DCS which is not already
in its cache. This list is the CRL.
Client State Advertisement record (CSA record)
A CSA is a record within a CSU message which identifies an update
to the status of a "particular" client.
Client State Advertisement Summary record (CSAS record)
A CSAS contains a summary of the information in a CSA. A server will
send CSAS records describing its cache entries to another server
during the cache alignment process. CSAS records are also included
in a CSUS messages when an LS wants to request the entire CSA from
the DCS. The LS is requesting the CSA from the DCS because the LS
believes that the DCS has a more recent view of the state of the
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cache entry in question.
Client State Update message (CSU message)
This is a message sent from an LS to its DCSs when the LS
becomes aware of a change in state of a client.
Client State Update Solicit message (CSUS message)
This message is sent by an LS to its DCS after the LS and DCS
have exchanged CA messages. The CSUS message contains one or more
CSAS records which represent solicitations for entire CSA records
(as opposed to just the summary information held in the CSAS).
Directly Connected Server (DCS)
The DCS is a server which is directly connected to the LS;
e.g., there exists a VC between the LS and DCS.
This term, along with the terms LS and RS, is used to give a frame
of reference when talking about servers and their synchronization.
Unless explicitly stated to the contrary, there is no implied
difference in functionality between a DCS, LS, and RS.
Hello Finite State Machine (HFSM)
An LS has a HFSM associated with each of its DCSs. The HFSM monitors
the state of the connectivity between the LS and a particular DCS.
Initialize bit (I bit)
This bit is included in a CA message. When set, this bit indicates
that the sender of the CA wishes to negotiate for Master/Slave server
status in the cache alignment process.
Local Server (LS)
The LS is the server under scrutiny; i.e., all statements are made
from the perspective of the LS.
This term, along with the terms DCS and RS, is used to give a frame
of reference when talking about servers and their synchronization.
Unless explicitly stated to the contrary, there is no implied
difference in functionality between a DCS, LS, and RS.
Local Server ID (LSID)
The LSID is a unique token that identifies an LS. This value
might be taken from the protocol address of the LS.
Master/Slave bit (M bit)
This bit is included in a CA message. When set, this bit indicates
that the sender of the CA wishes to be Master of the cache alignment
process.
More bit (O bit)
This bit is included in a CA message. When set, this bit indicates
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that the sender of the CA has more CA messages to send above and
beyond the message it is currently sending.
Remote Server (RS)
An RS is a server that is neither an LS nor a DCS and unless otherwise
stated an RS refers to a server in the SG.
This term, along with the terms LS and DCS, is used to give a frame
of reference when talking about servers and their synchronization.
Unless explicitly stated to the contrary, there is no implied
difference in functionality between a DCS, LS, and RS.
Server Group (SG)
The SCSP synchronizes caches (or a portion of the caches) of a set
of server entities which are bound to a SG through some means
(e.g., all servers belonging to a Logical IP Subnet (LIS)[1]). Thus
an SG is just a grouping of servers around some commonality.
Server Group ID (SGID)
This ID is a 32 bit identification field that uniquely identifies the
SG instance. Thus multiple SG instances may be running concurrently
and this field may be used to demux them.
Server ID (SID)
The SID is a unique token that identifies a given server. This value
might be taken from the protocol address of the server.
Appendix B: Packet Formats
B.1 SCSP Message Formats
This section of the appendix includes the message formats for SCSP.
SCSP messages may be contained as TLVs within a given protocol's
packet or it may be used as the mandatory part of separate packet
types as in NHRP (see Section B.2) or it may be run as a stand-alone
protocol. When SCSP is running as a stand alone protocol then it is
LLC/SNAP encapsulated with an LLC=0xAAAA03 and OUI=0x00005e and
PID=0x0005.
SCSP has 3 parts to every packet: the fixed part, the mandatory part,
and the TLV part. The fixed part of the message exists in every
packet and is shown below. The mandatory part is specific to the
particular message type (i.e., CA, CSU Request/Reply, Hello, CSUS).
The TLV part has not yet been defined for SCSP but it will contain
the set of TLVs for a particular SCSP message.
Fixed Header:
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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
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Version | Type Code | Packet Size |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Checksum | Start Of TLVs |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Version
This is the version of the SCSP protocol being used. The current
version is 1.
Type Code
This is the code for the message type (e.g., Hello (5), CSU
Request(2), CSU Reply(3), CSUS (4), CA (1)).
Packet Size
The total length of the SCSP packet, in octets (excluding link
layer and/or other protocol encapsulation).
Checksum
The standard IP checksum over the entire NHRP packet (starting with
the fixed header). If only the hop count field is changed, the
checksum is adjusted without full recomputation. The checksum is
completely recomputed when other header fields are changed.
Start Of TLVs
There are no TLVs currently specified for SCSP. This field will be
coded as zero until such time that TLVs are defined at which point
this field will be coded with the offset from the top of the fixed
header to the beginning of the first TLV.
B.1.1 Cache Alignment (CA)
The Cache Alignment (CA) message allows an LS to synchronize its
entire cache with that of the cache of its DCSs within a server
group. The CA message type code is 1. The CA message format is as
follows:
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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
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Sender ID Len | Recvr ID Len |M|I|O| unused | No. of CSASs |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| CA Sequence Number |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Server Group ID |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Sender ID (variable length) |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Receiver ID (variable length) |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| CSAS Record |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
.......
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| CSAS Record |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Sender ID Len
This field holds the length in octets of the Sender ID.
Recvr ID Len
This field holds the length in octets of the Receiver ID.
M
This bit is part of the negotiation process for the cache
alignment. When this bit is set then the sender of the CA message
is indicating that it wishes to lead the alignment process. This
bit is the "Master/Slave bit".
I
When set, this bit indicates that the sender of the CA message
believes that it is in a state where it is negotiating for the
status of master or slave. This bit is the "Initialization bit".
O
This bit indicates that the sender of the CA message has more CSAS
records to send. This implies that the cache alignment process
must continue. This bit is the "More bit" despite its dubious
name.
No. of CSASs
This field contains the number of Client State Advertisements
Summaries (CSASs) contained in the CA message.
CA Sequence Number
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A value which provides a unique identifier to aid in the sequencing
of the cache alignment process. The slave server always copies the
sequence number from the master server's previous CA message into
its current CA message thus acknowledging the master's CA message.
When the slave receives a "higher" sequence number then the number
that the slave previously sent then the slave's previous CA message
is acknowledged. A "larger" sequence number means a more recent CA
message.
Server Group ID
This ID is a 32 bit identification field that uniquely identifies
the SG instance. Thus multiple SG instances may be running
concurrently and this field may be used to demux them.
Sender ID
This is the protocol address of the server which is sending the CA
message.
Receiver ID
This is the protocol address of the server which is to receive the
CA message.
CSAS record
See Section B.1.1.1.
B.1.1.1 Client State Advertisement Summary Record (CSAS record)
CSAS records contain a generic header and a protocol specific part.
The generic header is shown below and the protocol specific part is
shown in the protocol specific section in subsequent appendices. See
the specific protocol appendix or the appropriate other document for
the protocol specific part of the CSAS.
Note that CSAS records do not contain a Server Group ID (SGID) since
cache alignments are performed on a per SG basis.
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
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Protocol ID | unused |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| CSA Sequence Number |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Protocol ID
The assignment of Protocol IDs for this field should be given over
to IANA. This field contains the protocol number for the given
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CSA:
1 - ATMARP
2 - NHRP
3 - MARS
4 - MCS
5 - LNNI
CSA Sequence Number
This field contains a sequence number that identifies the CSA
record instance for the given client. A "larger" sequence number
means a more recent advertisement.
B.1.2 Client State Update Request (CSU Request)
The Client State Update Request (CSU Request) message is used to
update the state of cache entries in servers which are attached to
the server sending the message. A CSU Request message is sent from
one server (the LS) to another directly connected server (the DCS)
when the LS observes changes in the state of one or more clients.
This observation may be a result of receiving a CSU from another DCS
or as a result of some event occurring for a client that has
registered with it. The change in state of a "particular" client is
noted in a CSU message via a "Client State Advertisement" (CSA)
record within the CSU. The CSU Request message type code is 2. The
CSU Request message format is as follows:
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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
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Sender ID Len | Recvr ID Len | unused | No. of CSAs |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| CSU Sequence Number |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Sender ID (variable length) |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Receiver ID (variable length) |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| CSA Record |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
.......
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| CSA Record |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Sender ID Len
This field holds the length in octets of the Sender ID.
Recvr ID Len
This field holds the length in octets of the Receiver ID.
No. of CSAs
This field contains the number of Client State Advertisements
(CSAs) contained in the CSU message.
CSU Sequence Number
A value which, when coupled with the address of the source,
provides a unique identifier for the CSU Request This value is
equivalent to the CSU Sequence Number in SCSP. A "larger" sequence
number means a more recent advertisement.
Sender ID
This is the protocol address of the server which is sending the CSU
message.
Receiver ID
This is the protocol address of the server which is to receive the
CSU message.
CSA Record
See Section B.1.2.1.
B.1.2.1 Client State Advertisement Record (CSA record)
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CSA records contain a generic header and a protocol specific part.
The generic header is shown below and the protocol specific part is
shown in the protocol specific section in subsequent appendices. See
the specific protocol appendix or the appropriate other document for
the protocol specific part of the CSA.
Note that CSA records do contain a Server Group ID (SGID) since CSU
messages may carry CSA records from multiple SGs.
The Cache State Advertisement (CSA) record contains the information
necessary to relate the current state of a client in an SG to the
servers being synchronized. There are zero or more CSA records in an
CSU Request message. The contents of a record is as follows:
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
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Protocol ID | TTL |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| CSA Sequence Number |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Server Group ID |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Protocol ID
The assignment of Protocol IDs for this field should be given over
to IANA. This field contains the protocol number for the given
CSA:
1 - ATMARP
2 - NHRP
3 - MARS
4 - MCS
5 - LNNI
TTL
Time to live for the packet. This represents the number of hops
that the CSA takes before it is dropped. Note this is on a CSA
basis not CSU.
CSA Sequence Number
This field contains a sequence number that identifies the CSA
record instance for the given client. A "larger" sequence number
means a more recent advertisement.
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Server Group ID
This ID is a 32 bit identification field that uniquely identifies
the SG instance. Thus multiple SG instances may be running
concurrently and this field may be used to demux them.
B.1.3 Client State Update Reply (CSU Reply)
The Client State Update Reply (CSU Reply) message is used to
acknowledge the reception of Client State Update Request. A CSU
Reply message is sent from one server (the DCS) to the server (the
LS) which sent the original CSU Request. The CSU Reply message type
code is 3. The CSU Reply message format is the same as that of the
CSU Request so that when an server receives an CSU Request all that
needs to be done to reply to it is to change the type code to 3 and
send the message back.
B.1.4 Client State Update Solicit Message (CSUS message)
This message allows one server (LS) to solicit the entirety of CSA
data stored in the cache of a directly connected server (DCS). The
DCS responds with CSU messages containing the appropriate CSAs. The
CSUS message type code is 4. The CSUS message format is the same as
that of the CA message; however the M, I, and O bits are not
meaningful in this context and are set to zero. Also, the CSUS
Sequence Number is from a different numbering space than the CA
Sequence number. CSUS messages solicit CSUs from only one server of
a SG at a time. That SG is the one identified by the SGID in the CSUS
header and the server is identified by the Receiver ID field in CSUS
header.
B.1.5 Hello:
The Hello message is used to check connectivity between the sending
server (the LS) and one of its directly connected neighbor servers
(the DCSs). The Hello message type code is 5. The Hello message
format is as follows:
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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
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Sender ID Len | Recvr ID Len | Number of Receiver IDs Heard |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| HelloInterval | DeadFactor |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Server Group ID |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Sender ID (variable length) |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Receiver ID (variable length) |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
.........
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Receiver ID (variable length) |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Sender ID Len
This field holds the length in octets of the Sender ID.
Recvr ID Len
This field holds the length in octets of the Receiver ID.
Number of Receiver IDs Heard
This field holds the count of the Receiver ID which are listed in
this packet.
HelloInterval
The hello interval advertises the time between sending of
consecutive Hello Messages by an LS. If the time between Hello
messages exceeds the HelloInterval then the Hello is to be
considered late by the DCS. On the other hand, if the LS does not
receive a Hello Reply within its HelloInterval then the LS resends
the same Hello message it sent previously
DeadFactor
This is a multiplier to the HelloInterval. If a DCS does not
receive a Hello message within the interval
HelloInterval*DeadFactor from an LS that advertised the
HelloInterval then the DCS MUST consider the LS to be stalled at
which point the DCS should transition to the Waiting State. On
the other hand, if the LS does not receive a Hello Reply within
DeadFactor*HelloInterval then one of two things happens: 1) if the
LS has received Hello messages from the DCS during this time then
the LS transitions to the Unidirectional State; otherwise, 2) the
LS transitions to the Waiting State.
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Server Group ID
This ID is a 32 bit identification field that uniquely identifies
the SG instance. Thus multiple SG instances may be running
concurrently and this field may be used to demux them.
Sender ID
This is the protocol address of the server which is sending the
Hello.
Receiver ID
This is the ID of a DCS from which the LS has heard a recent Hello.
If the LS has not heard from any such DCS then the LS sets the
"Number of Receiver IDs Heard" field to zero and allocates no
storage for the Receiver ID in the Hello message.
B.2: Packet Formats For NHRP
For NHRP, SCSP functionality may be obtained by using the SCSP packet
formats as described in Section B.1 (minus the LLC/SNAP and SCSP Fixed
part) by including them as the "mandatory part" part of an NHRP message
with the appropriate NHRP packet type code (described in Section B.2.1
through B.2.5). This usage of SCSP is not the preferred method.
However, for consistency with previous revisions of SCSP, Sections B.2.1
through B.2.5 have been included below.
Obtaining SCSP functionality by having the CA, CSU, and Hello sub-
protocols run as a stand-alone protocol as previously described (i.e.,
with the LLC/SNAP code point and SCSP Fixed Part) is strongly
encouraged.
Regardless of what method is used to obtain SCSP functionality, Section
B.2.6 shows the correct format for the NHRP specific portion of the CSA
and CSAS records.
B.2.1 CA message as an NHRP mandatory part
The NHRP CA packet has an SCSP CA message as its mandatory part and
this NHRP packet has a type code of 11.
B.2.2 CSU Request message as an NHRP mandatory part
The NHRP CSU Request packet has an SCSP CSU Request message as its
mandatory part and this NHRP packet has a type code of 12.
B.2.3 CSU Reply message as an NHRP mandatory part
The NHRP CSU Reply packet has an SCSP CSU Reply message as its
mandatory part and this NHRP packet has a type code of 13.
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B.2.4 CSU Solicit message as an NHRP mandatory part
The NHRP CSU Solicit packet has an SCSP CSU Solicit message as its
mandatory part and this NHRP packet has a type code of 14.
B.2.5 Hello message as an NHRP mandatory part
The NHRP Hello packet has an Hello message as its mandatory part and
this NHRP packet has a type code of 15.
B.2.6 CSA record and CSAS record for NHRP
The CSA record and CSAS record are protocol specific (e.g., NHRP,
IPMC, ATMARP, etc.) because they carry protocol specific data. This
section describes the information carried in CSA records and CSAS
records for NHRP.
B.2.6.1 CSA Record
The Client State Advertisement (CSA) record contains the information
necessary to relate the current state of a client to the servers
being synchronized. There are zero or more CSA records in an CSU
Request message. This section contains the NHRP specific portion of
the CSA. The NHRP specific portion of the CSA is made up of a Client
Information Entry (CIE) as defined in [2] where the CIE Code field
gives the "State" of the client and the previously unused field has
been used as a "Flags" field which contains cache entry specific
information which was registered with the server (see below for
example). Appended to the CIE is an "Other State" field which
contains other information about the cache entry. The format of the
NHRP specific part of the CSA record is as follows:
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
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| State | Prefix Length | Flags |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Maximum Transmission Unit | Holding Time |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Cli Addr T/L | Cli SAddr T/L | Cli Proto Len | Preference |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Client NBMA Address (variable length) |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Client NBMA Subaddress (variable length) |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Client Protocol Address (variable length) |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Other State (variable length) |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
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State
This field contains a value which represents the change in state of
the client. For example:
0 - Client is registered and available.
1 - Holding timer expired for client.
2 - Client reregistered.
3 - Client has been purged.
4 - No such client data in server cache
Prefix Length
This field is message specific. See the relevant message sections
below. In general, however, this fields is used to indicate that
Flags
Defined flags are as follows:
0 1
0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
|U| unused |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
U
This is the Uniqueness bit.
Maximum Transmission Unit
This field gives the maximum transmission unit for the relevant
client station. If this value is 0 then either the default MTU is
used or the MTU negotiated via signaling is used if such
negotiation is possible for the given NBMA.
Holding Time
The Holding Time field specifies the number of seconds for which
the Next Hop NBMA information specified in the CIE is considered to
be valid. Cached information SHALL be discarded when the holding
time expires. This field must be set to 0 on a NAK.
Cli Addr T/L
Type & length of next hop NBMA address specified in the CIE. This
field is interpreted in the context of the 'address family number'
indicated by ar$afn (e.g., ar$afn=0x0003 for ATM).
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Cli SAddr T/L
Type & length of next hop NBMA subaddress specified in the CIE.
This field is interpreted in the context of the 'address family
number' indicated by ar$afn (e.g., ar$afn=0x0015 for ATM makes the
address an E.164 and the subaddress an ATM Forum NSAP address).
When an NBMA technology has no concept of a subaddress, the
subaddress is always null with a length of 0. When the address
length is specified as 0 no storage is allocated for the address.
Cli Proto Len
This field holds the length in octets of the Client Protocol
Address specified in the CIE.
Preference
This field specifies the preference for use of the specific CIE
relative to other CIEs. Higher values indicate higher preference.
Action taken when multiple CIEs have equal or highest preference
value is a local matter.
Client NBMA Address
This is the client's NBMA address.
Client NBMA SubAddress
This is the client's NBMA subaddress.
Client Protocol Address
This is the client's internetworking layer address specified.
Other State
At present, the other state record contains only the CSA Originator
ID information and a place holder for Vendor private information:
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
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
|CSA Orig ID Len| CSA Originator ID (variable length) |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Vendor Private Information (variable length) |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
CSA Orig ID Len
This field holds the length in octets of the CSA Originator ID.
CSA Originator ID
This field contains the protocol address of the server which
originated the CSA record.
Vendor Private Information
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This is a variable length octet string which is potentially
vendor specific. This may be encoded in a way similar to the
Vendor Private extension of [2].
B.2.6.2 Client State Advertisement Summary Record (CSAS record):
The client state advertisement summary is a summarization of the CSA.
A CSAS contains the following:
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
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Cli Proto Len |CSA Orig ID Len| unused |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Client Protocol Address (variable length) |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| CSA Originator Protocol Address (variable length) |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Cli Proto Len
This field holds the length in octets of the Client Protocol
Address.
CSA Orig ID Len
This field holds the length in octets of the CSA Originator ID.
Client Protocol Address
This is the client's internetworking layer address specified.
CSA Originator ID
This field contains the protocol address of the server which
originated the CSA record.
B.3 Packet Formats For ATMARP
For ATMARP, SCSP functionality may be obtained by using the SCSP
packet formats as described in Section B.1 (minus the LLC/SNAP and
SCSP Fixed part) by including them part of an ATMARP message with the
appropriate ATMARP packet type code (described in Section B.3.1
through B.3.5). This usage of SCSP is not the preferred method.
However, for consistency with previous revisions of SCSP, Sections
B.3.1 through B.3.5 have been included below. When using this method
to obtain SCSP functionality an ATMARP header/fixed-part needs to be
appended to the SCSP packets which makes them look like every other
ATMARP packet. The format of that header is given below. Consult
Section 6.6 and 6.7 of [1] for more details.
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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
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| ar$hrd | ar$pro |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| unused | ar$op |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| ATMARP "mandatory parts" |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
ar$hrd
The "Hardware type" is assigned to ATM Forum address family and is
19 decimal (0x0013).
ar$pro
The "Protocol type" is (see Assigned Numbers) for protocol type
number for the protocol using ATMARP. (IP is 0x0800).
ar$op
The operation type value is 3 for SCSP.
ATMARP "mandatory parts"
This part depends on the value of ar$op. This part/field is
analogous to the use of the mandatory part in NHRP while the
preceding fields are directly analogous to the "Fixed" part in
NHRP. See Sections B.3.1 through B.3.5 for details of packet
content based on the value in ar$op.
Obtaining SCSP functionality by having the CA, CSU, and Hello sub-
protocols run as a stand-alone protocol as described in Section B.1
(i.e., with the LLC/SNAP code point and SCSP Fixed Part) is strongly
encouraged.
Regardless of what method is used to obtain SCSP functionality, Section
B.3.6 shows the correct format for the ATMARP specific portion of the
CSA and CSAS records.
B.3.1 CA message as an ATMARP mandatory part
The ATMARP CA packet has an SCSP CA message as its mandatory part and
this ATMARP packet has a ar$op value of 3.
B.3.2 CSU Request message as an ATMARP mandatory part
The ATMARP CSU Request packet has an SCSP CSU Request message as its
mandatory part and this ATMARP packet has a ar$op value of 4. For
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ATMARP, since ATMARP clients have no concept of a sequence number,
SCSP must generate a sequence number for each client request which
causes a database update to occur since SCSP cannot acquire a unique
sequence number from the client for the given update.
B.3.3 CSU Reply message as an ATMARP mandatory part
The ATMARP CSU Reply packet has an SCSP CSU Reply message as its
mandatory part and this ATMARP packet has a ar$op value of 5.
B.3.4 CSU Solicit message as an ATMARP mandatory part
The ATMARP CSU Solicit packet has an SCSP CSU Solicit message as its
mandatory part and this ATMARP packet has a ar$op value of 6.
B.3.5 Hello message as an ATMARP mandatory part
The ATMARP Hello packet has an Hello message as its mandatory part
and this ATMARP packet has a ar$op value of 7.
B.3.6 CSA record and CSAS record for ATMARP
These records are the same as those found in Sections B.2.6.1 and
B.2.6.2 of this document with several exceptions:
1) The Holding Time is always set to 1200 seconds.
2) The "Cli NBMA T/L" and "Cli NBMA SubT/L" fields are coded in a
manner similar to ar$sstl and ar$shtl respectively as seen in
Section 6.6 of [1].
3) Prefix length is always set to 0xff.
4) Preference is always set to zero.
B.4 Packet Formats For MARS
********************************************************************
********************************************************************
This section is NOT up to date. It will be removed and placed in a
separate document in the next revision of this draft. It is here for
informational purposes only and is relevant only to the prior draft of
this document!
********************************************************************
********************************************************************
The MARS model does not currently specify the nature of any
distributed-MARS, but contains a vaguely implicit assumption that a
dynamic information that the MARS is required to keep on behalf of
its Cluster - the CMIs, the Cluster/ServerControlVCs (the actual sets
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of registered Cluster members and MCSs), ClusterSequenceNumbers, and
ServerSequenceNumbers. The minimal goal of a distributed-MARS is to
ensure that members of the ServerGroup could take over running the
Cluster if the designated MARS failed. Allowing cluster members to
terminate on any one of the component MARSs in the ServerGroup is a
more difficult goal, which nevertheless needs to be pursued in the
longer term.
B.4.1 The MARS Sub-caches.
This description will assume a 'Designated MARS' model (see
Appendix C).
The overall MARS state is made up of the following components:
Cluster membership list.
Cluster Member IDs.
Cluster Sequence Number.
(Multicast) Server membership list.
(Multicast) Server Sequence Number.
Absolute maximum and minimum group addresses for protocol being
supported.
Member map (hostmap) for each Layer 3 group.
(MCS) Servermap for each Layer 3 group.
Block-join map.
For the rest of this description, combinations of these components
may be referred to as MARS sub-caches.
The Cluster membership list is the most fundamental object for a
MARS. It contains the ATM addresses of every cluster member, and
explicitly maps ATM addresses to Cluster Member IDs. Both of these
pieces of information will be combined into a single sub-cache and
carried in the same CSAS and/or CSA Records. (This list allows a
backup MARS to construct backup ClusterControlVCs as necessary.)
The ClusterSequenceNumber (CSN) is a single integer value, which
increments every time a MARS control message is transmitted on
ClusterControlVC. It is essential that backup MARSs are reasonably
uptodate with their concept of CSN. Unfortunately, the CSN increments
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more often that database changes occur. It is possible that the
designated MARSs should treat every increment of the CSN as a reason
to issue an update to the ServerGroup. It may not be sufficient for
the CSN to only be updated whenever another cache state change needed
to be propagated from the designated MARS. (During a failover from
designated MARS to a backup MARS, this could result in the advertised
CSN being older that what the cluster members expect to see - opening
a window of opportunity for cluster members to lose a subsequent
message on the backup ClusterControlVC and not realize it.)
The (Multicast)Server membership list is essential to enable
construction of a backup ServerControlVC by any one of the backup
MARSs. The ServerSequenceNumber poses a similar problem to the
ClusterSequenceNumber - it is likely that backup MARSs really need to
keep it up to date with the latest value.
Each layer 3 group that has members and/or MCSs registered for it
will have database entries in the designated MARS. The (MCS)
servermaps are likely to change far less frequently that the (host)
membership maps, and so (for the same layer 3 multicast group) the
hostmaps and servermaps are treated as separate sub-caches. To
simplify and shorten the CSAS and CSA Records, members of these maps
be identified by indexes into the respective Cluster Membership list
or Server Membership list (rather than enumerating their actual ATM
addresses in CSA updates, etc). The Cluster/Server Membership lists
are the most important parts of the cache for the distributed-MARS to
get right.
The block-join map represents all currently valid block MARS_JOINs
registered with the MARS. This allows the preceding, group-specific
hostmaps to be simplified. (The CSA Records representing the hostmap
for a given group only lists nodes that have issued a specific
single-group MARS_JOIN for that group.) Internally, the MARS builds
whatever database structure is required to ensure that replies to
MARS_REQUESTs, and general hole-punching activities, take the block-
join map's contents into account.
B.4.2 Client State Advertisement Summary (CSAS) records.
These are combined with the Cache Alignment message define in section
B.1.1. Since a number of different sub-caches exist in a MARS (as
described above) a number of different CSAS record types are defined.
The general form is:
csas$type 16 bits Type of sub-cache in this CSAS record.
csas$contents n octets CSAS contents, determined by csas$type.
Available CSAS record types are:
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CSAS_CLUSTER_LIST 1
CSAS_MCS_LIST 2
CSAS_HOST_MAP 3
CSAS_MCS_MAP 4
CSAS_BLOCK_JOINS 5
The specific formats of the associated csas$contents field is
described in the following sub-sections.
B.4.2.1 CSAS_CLUSTER_LIST.
The complete CSAS Record looks like:
csas$type 16 bits Set to 1 (CSAS_CLUSTER_LIST)
csas$orig_len 8 bits Length of csas$origin field.
csas$unused 8 bits unused.
csas$sequence 32 bits CSAS Sequence number.
csas$origin x octets Originator's protocol address.
For this CSAS, the sequence number is incremented every time a new
cluster member registers, or an old one is considered to have died or
deregistered.
B.4.2.2 CSAS_MCS_LIST.
The complete CSAS Record looks like:
csas$type 16 bits Set to 2 (CSAS_MCS_LIST)
csas$orig_len 8 bits Length of csas$origin field.
csas$unused 8 bits unused.
csas$sequence 32 bits CSAS Sequence number.
csas$origin x octets Originator's protocol address.
For this CSAS, the sequence number is incremented every time a new
MCS registers, or an old one is considered to have died or
deregistered.
B.4.2.3 CSAS_HOST_MAP.
The complete CSAS Record looks like:
csas$type 16 bits Set to 3 (CSAS_HOST_MAP)
csas$orig_len 8 bits Length of csas$origin field.
csas$group_len 8 bits Length of group address.
csas$sequence 32 bits CSAS Sequence number.
csas$origin x octets Originator's protocol address.
csas$group y octets Hostmap's group address.
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For this CSAS, the sequence number is incremented whenever a cluster
member joins or leaves the group.
B.4.2.4 CSAS_MCS_MAP.
The complete CSAS Record looks like:
csas$type 16 bits Set to 4 (CSAS_MCS_MAP)
csas$orig_len 8 bits Length of csas$origin field.
csas$group_len 8 bits Length of group address.
csas$sequence 32 bits CSAS Sequence number.
csas$origin x octets Originator's protocol address.
csas$group y octets Servermap's group address.
For this CSAS, the sequence number is incremented whenever an MCS
joins or leaves the group.
B.4.2.5 CSAS_BLOCK_JOINS.
The complete CSAS Record looks like:
csas$type 16 bits Set to 5 (CSAS_BLOCK_JOINS)
csas$orig_len 8 bits Length of csas$origin field.
csas$unused 8 bits unused.
csas$sequence 32 bits CSAS Sequence number.
csas$origin x octets Originator's protocol address.
For this CSAS, the sequence number is incremented whenever a block
MARS_JOIN, or matching block MARS_LEAVE, occurs.
B.4.3 Client State Advertisement (CSA) Records.
The amount of information needed to update, e.g., a cluster
membership list or group membership list, may exceed the size of a
link layer PDU. Hence, MARS related CSA Records relating to a single
sub-cache may be fragmented across a number of CSU Request messages.
This may be considered analogous to the fragmentation of a a group's
membership list across a number of MARS_MULTIs when a MARS replies to
a single MARS_REQUEST.
To match the CSAS records, a set of CSA record types are defined.
CSA_CLUSTER_LIST 1
CSA_MCS_LIST 2
CSA_HOST_MAP 3
CSA_MCS_MAP 4
CSA_BLOCK_JOINS 5
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Every type allows for fragmentation of the CSA Record across multiple
CSU Request messages. Analogous to MARS_MULTIs, CSA Record fragments
carry a 15 bit fragment number and 1 bit 'end of fragment' (EOF)
flag. Re-assembly of fragments requires collecting CSA Record
fragments referring to the same sub-cache type and entry, until the
EOF flag is set. The re-assembled CSA Record is then processed.
A sequence of CSU Requests carrying a fragmented CSA Record SHALL
carry the same CSU Sequence Number (appendix B.1.2). If the CSU
Sequence Number changes during the re-assembly of a CSA Record, the
fragments collected so far are discarded.
A sequence of CSA Record fragments of the same CSA Record type SHALL
carry the same CSA Sequence Number. If the CSA Sequence Number
changes during the re-assembly of a fragmented CSA Record, the
fragments so far are discarded. (The CSA Sequence number for any
given type of cache information is derived in the same way as the
CSAS Sequence number for the equivalent CSAS message, as described in
the previous section).
The 15 bit fragment number in consecutive fragments of a CSA Record
SHALL start at 1 and increment by 1 for each fragment. Fragments
SHALL be transmitted in order of their fragment sequence numbers. All
but the final fragment shall have the EOF flag set to 0. The final
(or first, if there is only one) fragment SHALL have the EOF flag set
to 1.
If the fragment sequence number skips by more than one at the
receiver, the CSA Record being re-assembled is considered in error.
It is discarded after the final fragment is received. If the final
fragment does not arrive within 10 seconds of the last received
fragment, the CSA Record re-assembly is terminated and the fragments
collected so far are discarded.
B.4.3.1 CSA_CLUSTER_LIST.
This CSA Record carries the entire membership of the current cluster,
along with the Cluster Member IDs (CMIs) assigned by the MARS they
registered with. These CMIs are then used in other CSA Record types
as a short-form representation of actual cluster members.
csa$type 16 bits Set to 1 (CSA_CLUSTER_LIST).
csa$orig_len 8 bits Length of csa$origin.
csa$unused 8 bits unused.
csa$sequence 32 bits CSA Sequence number.
csa$flagxy 16 bits Fragment number and EOF flag.
csa$cnum 16 bits Number of entries in this fragment.
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csa$thtl 8 bits Type and length of ATM addresses.
csa$tstl 8 bits Type and length of ATM sub-addresses.
csa$origin x octets Originator's protocol address.
csa$atmaddr.1 q octets ATM address of member 1.
csa$subaddr.1 r octets ATM sub-address of member 1.
csa$cmi.1 16 bits Cluster Member ID for entry 1.
[..etc..]
csa$atmaddr.N q octets ATM address of member N.
csa$subaddr.N r octets ATM sub-address of member N.
csa$cmi.N 16 bits Cluster Member ID for entry N.
B.4.3.2 CSA_MCS_LIST.
This CSA Record carries the entire list of currently registered
Multicast Servers (MCSs). Each MCS is also assigned an internal ID by
the MARS they registered with - this is used to compress the size of
subsequent CSA_HOST_MAP messages.
csa$type 16 bits Set to 2 (CSA_MCS_LIST).
csa$orig_len 8 bits Length of csa$origin.
csa$unused 8 bits unused.
csa$sequence 32 bits CSA Sequence number.
csa$flagxy 16 bits Fragment number and EOF flag.
csa$cnum 16 bits Number of entries in this fragment.
csa$thtl 8 bits Type and length of ATM addresses.
csa$tstl 8 bits Type and length of ATM sub-addresses.
csa$origin x octets Originator's protocol address.
csa$atmaddr.1 q octets ATM address of MCS 1.
csa$subaddr.1 r octets ATM sub-address of MCS 1.
csa$cmi.1 16 bits Internal MCS ID for entry 1.
[..etc..]
csa$atmaddr.N q octets ATM address of member N.
csa$subaddr.N r octets ATM sub-address of member N.
csa$cmi.N 16 bits Internal MCS ID for entry N.
B.4.3.3 CSA_HOST_MAP
This CSA Record carries the list of cluster members who have joined a
specified group using a single-group MARS_JOIN operation. The Cluster
Member IDs are used to represent each group member with each CSA
Record fragment. A recipient MARS uses this CSA in conjunction with
the current Cluster membership list to derive the actual ATM
addresses of group members.
csa$type 16 bits Set to 3 (CSA_HOST_MAP).
csa$orig_len 8 bits Length of csas$origin.
csa$group_len 8 bits Length of csa$group.
csa$sequence 32 bits CSA Sequence number.
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csa$flagxy 16 bits Fragment number and EOF flag.
csa$cnum 16 bits Number of entries in this fragment.
csa$origin x octets Originator's protocol address.
csa$group y octets Multicast group's protocol address.
csa$cmi.1 16 bits Cluster Member ID for entry 1.
csa$cmi.2 16 bits Cluster Member ID for entry 2.
[..etc..]
csa$cmi.N 16 bits Cluster Member ID for entry N.
B.4.3.4 CSA_MCS_MAP
This CSA Record carries the list of MCSs who have joined to support a
specified group. The internal MCS IDs from prior CSA_MCS_LIST CSA
Records are used to represent each MCS. A recipient MARS uses this
CSA in conjunction with the current MCS membership list to derive the
actual ATM addresses of group members.
csa$type 16 bits Set to 4 (CSA_MCS_MAP).
csa$orig_len 8 bits Length of csas$origin.
csa$group_len 8 bits Length of csa$group.
csa$sequence 32 bits CSA Sequence number.
csa$flagxy 16 bits Fragment number and EOF flag.
csa$cnum 16 bits Number of entries in this fragment.
csa$origin x octets Originator's protocol address.
csa$group y octets Multicast group's protocol address.
csa$cmi.1 16 bits Internal MCS ID for entry 1.
csa$cmi.2 16 bits Internal MCS ID for entry 2.
[..etc..]
csa$cmi.N 16 bits Internal MCS ID for entry N.
B.4.3.5 CSA_BLOCK_JOINS
This CSA Record carries the list of Cluster Members who have joined
blocks of the layer 3 group address space. The Cluster Member IDs
from prior CSA_CLUSTER_LIST CSA Records are used to represent each
cluster member and associate it with a specific <min,max> pair.
csa$type 16 bits Set to 5 (CSA_BLOCK_JOINS).
csa$orig_len 8 bits Length of csas$origin.
csa$group_len 8 bits Lengths of csa$min and csa$max fields.
csa$sequence 32 bits CSA Sequence number.
csa$flagxy 16 bits Fragment number and EOF flag.
csa$cnum 16 bits Number of entries in this fragment.
csa$origin x octets Originator's protocol address.
csa$min.1 y octets <min> group address of block 1.
csa$max.1 y octets <max> group address of block 1.
csa$cmi.1 16 bits Cluster Member ID for block 1.
[..etc..]
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csa$min.N y octets <min> group address of block N.
csa$max.N y octets <max> group address of block N.
csa$cmi.N 16 bits Cluster Member ID for block N.
B.4.4 CSAS and CSA priorities.
The most important cache types for a MARS to exchange are the
CSA_CLUSTER_LIST and CSA_MCS_LIST. Without alignment of these caches,
the backup MARSs cannot know the cluster's membership or the
currently registered MCSs. They will also be unable to interpret the
other CSA Record types, which identify nodes using ID values supplied
in the CSA_CLUSTER_LIST and CSA_MCS_LIST records.
B.5: Packet Formats For LECS
Work in progress.
Appendix C: A Canonical Point Of Query
The following sections of this appendix describe optional Designated
Server (DS) functionality which is not completely within the realm of
server synchronization but is closely related. One use of this
Designated Server functionality might be to have a dynamically elected
server be responsible for assigning CMIs [5] to clients in an IPMC
implementation.
One way to obtain a Designated Server is described below while another
may be simply run a spanning tree like protocol over all servers in a
server group.
CSU messages are used to elect the "Designated" Server (DS) from the set
of "Eligible" Servers (ESs). A server must also be configured with its
Designated Server Priority (DSP) which relates its priority in the
election of a DS. An ES is a server that is eligible to become the DS
by virtue of the fact that it has a DSP which is greater than zero.
C.1 Additional Abbreviations
DS - Designated Server
DSID - Designated Server ID
DSP - Designated Server Priority
ES - Eligible Server
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C.2 Additional Definitions
Designated Server (DS)
The DS is the contact point within the SG for off-SG stations
wishing to query the state of the SG.
Designated Server ID (DSID)
The DSID is a unique token that identifies the DS in an SG. This value
might be taken from the protocol address of the DS.
Designated Server Priority (DSP)
The DSP identifies the priority of a given server to become
the DS. If the DSP is 0 then the server is ineligible to become
the DS.
Eligible Server (ES)
An ES is a server that is eligible to become the DS as a result
of having a DSP greater than zero.
C.3 The Designated Server Functionality
The remainder of this section assumes that the canonical point of
query functionality is to be implemented.
C.3.1 Overview
When an LS has one or more CAFSMs in the Aligned State, the LS
participates in the Designated Server (DS) election process for the
given SG. Once a CAFSM has reached the Aligned State, the LS starts
the DSTimer which is set to DSInitTime. Before this DSTimer expires,
the LS MUST not include a Preferred DSID or Preferred DSP in the CSU
messages it originates. While the DSTimer is running, the LS keeps
track of its preferred DS from knowledge contained in its cache and
from knowledge of its own DS Priority (DSP) and LSID. The preferred
DS is the server with the highest DSP and in the case of a tie, the
largest Server ID (SID) wins. CSU messages contain CSA records. Each
CSA contains the following additional fields: a DS bit (which
proclaims that the originator believes that it is DS) and a C/S bit
(which proclaims that the cache entry refers to a Client (bit is
zero) or a Server (bit is set to one)). Further, if the C/S bit is
set then the CSA also contains a Preferred DSID field and a Preferred
DSP field. Note that clients are assumed to have a DSP of zero.
Servers are clients of themselves in the sense of keeping their own
state in their own cache; thus a server always advertises itself.
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C.3.2 The Election Algorithm
When the DSTimer expires the LS chooses its preferred DS and starts
advertising it as well as the preferred DSP. The LS then does the
following:
1) If the LS thinks that it is the preferred DS then
a) If all known servers have chosen this LS as leader then
the LS becomes the DS (see below)
b) If one or more servers are advertising a different DS from the LS then
1) Start the DSOverrideTimer with DSOverrideInterval in it
2) When the DSOverrideTimer expires
a) If 2/3 of the servers believe the LS to be leader then
the LS becomes the DS (see below)
2) If the LS becomes DS it does the following:
a) It increases its DSP by DSPIncrement or to DSPMax whichever is least
b) It sends out a CSU message with its new DSP in Preferred DSP field,
its LSID in the preferred DSID field, the DS bit set, the
Originator ID field set to its LSID, and the Originator DSP field set
to its new DSP.
3) At all times an LS is listening for a new DS with higher DSP then
the current preferred DSP (and preferred DSID).
If at any time the LS sees a DSP higher then the preferred DSP or a
DSP which is equal to the current preferred DSP but with an
associated DSID which is larger than the preferred DSID then the LS
acts as follows:
1) If the LS was the DS then
a) The LS announces that the other server is the DS by sending out a CSU
message with the new DS's DSID in the preferred DSID, with the new
DS's DSP in the preferred DSP field, the DS bit set off,
and the Originator DSP field set to its original DSP (not its
incremented DSP).
b) The LS sets its DSP to its original value.
2) If the LS was not the DS then
a) If the new preferred DS is not the LS then
the LS simply advertises the new information pertaining to the new DS
b) If the new preferred DS is the LS then
restart the election process as if the DSTimer had just expired.
If the LS loses "connectivity" with the DS (e.g., the cache entry in
the LS for the DS is removed) then the LS acts as follows:
1) The LS starts a Re-electionTimer
a) If connectivity is reestablished before the timer expires then
stop the timer and continue as normal
b) else restart the election process as if the DSTimer had just expired
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If at any time the last CAFSM of the LS for the given SG leaves the
Aligned State then all memory of the DS for that SG is erased from
the LS and re-election will not take place until at least one CAFSM
of the LS for the given SG reaches the Aligned State at which point
the election process will start from the beginning.
C.3.3 Message Additions
A CSU message carries 0 or more CSA records. When designated server
functionality is used, CSA records have the following fields appended
to them:
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
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| DS Proto Len | Pref DSP | unused |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Preferred Designated NHS Protocol Address |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
DS Proto Len
This field holds the length in octets of the Preferred Designated
NHS's Protocol Address.
Pref DSP
This field contains the priority of the preferred Designated NHS as
seen from the perspective of the server creating the CSA record.
This field does not exist in a record when the C/S bit is zero.
Preferred DSID
This field contains the ID of the preferred designated as seen from
the perspective of the server creating the CSA record. This field
does not exist in a record when the C/S bit is zero.
References
[1] "Classical IP and ARP over ATM", Laubach, RFC 1577.
[2] "NBMA Next Hop Resolution Protocol (NHRP)", Luciani, Katz, Piscitello,
Cole, draft-ietf-rolc-nhrp-08.txt.
[3] "OSPF Version 2", Moy, RFC1583.
[4] "PNNI Draft Specification", Dykeman, Goguen, ATM Forum 94-0471R16
(Straw Vote), 1996.
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[5] "Support for Multicast over UNI 3.0/3.1 based ATM Networks.",
Armitage, draft-ietf-ipatm-ipmc-12.txt.
[6] LAN Emulation over ATM Version 2 - LNNI specification - Draft 3
ATM Forum 95-1082R3, April 1996
[7] Assigned Numbers, J. Reynolds and J. Postel, RFC 1700.
Acknowledgments
This I-D is a distillation of issues raised during private
discussions, on the IP-ATM mailing list, and during the Dallas IETF
(12/95). Thanks to all who have contributed but particular thanks to
Andy Malis, Raj Nair, and Matthew Doar of Ascom Nexion. I would also
like to thank James Watt of Newbridge for comments that lead to a
tighter document.
Author's Address
James V. Luciani
Bay Networks, Inc.
3 Federal Street, BL3-04
Billerica, MA 01821
phone: +1-508-439-4734
email: luciani@baynetworks.com
Grenville Armitage
Bellcore, 445 South Street
Morristown, NJ, 07960
Email: gja@thumper.bellcore.com
Ph. +1 201 829 2635
Joel M. Halpern
Newbridge Networks Corp.
593 Herndon Parkway
Herndon, VA 22070-5241
Phone: +1-703-708-5954
Email: jhalpern@Newbridge.COM
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