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Updated by: 5494 INTERNET STANDARD
Network Working Group K. Hardwick
Request for Comments: 1044 NSC
J. Lekashman
NASA-Ames GE
February 1988
Internet Protocol on Network Systems HYPERchannel
Protocol Specification
STATUS OF THIS MEMO
The intent of this document is to provide a complete discussion of
the protocols and techniques used to embed DoD standard Internet
Protocol datagrams (and its associated higher level protocols) on
Network Systems Corporation's HYPERchannel [1] equipment.
Distribution of this memo is unlimited.
This document is intended for network planners and implementors who
are already familiar with the TCP/IP protocol suite and the
techniques used to carry TCP/IP traffic on common networks such as
the DDN or Ethernet. No great familiarity with NSC products is
assumed; an appendix is devoted to a review of NSC technologies and
protocols.
At the time of this first RFC edition, the contents of this document
has already been reviewed by about a dozen vendors and users active
in the use of TCP/IP on HYPERchannel media. Comments and suggestions
are still welcome (and implementable,) however.
Any comments or questions on this specification may be directed to:
Ken Hardwick
Director, Software Technology
Network Systems Corporation MS029
7600 Boone Avenue North
Brooklyn Park, MN 55428
Phone: (612) 424-1607
John Lekashman
Nasa Ames Research Center. NAS/GE
MS 258-6
Moffett Field, CA, 94035
lekash@orville.nas.nasa.gov
Phone: (415) 694-4359
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RFC 1044 IP on Network Systems HYPERchannel February 1988
TABLE OF CONTENTS
Status of this memo . . . . . . . . . . . . . . . . . . . . . . 1
Goals of this document . . . . . . . . . . . . . . . . . . . . 3
Basic HYPERchannel network messages . . . . . . . . . . . . . . 4
Basic (16-bit address) Message Proper header . . . . . . . . . 5
TO addresses and open driver architecture . . . . . . . . . . 7
Extended (32-bit address) Message Proper header . . . . . . . . 8
Address Recognition and message forwarding . . . . . . . . . . 10
32-bit message fields . . . . . . . . . . . . . . . . . . . . 12
Broadcasting . . . . . . . . . . . . . . . . . . . . . . . . . 14
PROTOCOL SPECIFICATION . . . . . . . . . . . . . . . . . . . . 17
Basic (16-bit) Message Encapsulation . . . . . . . . . . . . 18
Compatibility with existing implementations . . . . . . . . . . 21
Extended (32-bit) Message Encapsulation . . . . . . . . . . . 24
Address Resolution Protocol . . . . . . . . . . . . . . . . . 27
Maximum Transmission Unit . . . . . . . . . . . . . . . . . . . 31
ADDRESS RESOLUTION . . . . . . . . . . . . . . . . . . . . . . 32
Local Address Resolution . . . . . . . . . . . . . . . . . . . 33
Configuration file format . . . . . . . . . . . . . . . . . . 34
ARP servers . . . . . . . . . . . . . . . . . . . . . . . . . 35
Broadcast ARP . . . . . . . . . . . . . . . . . . . . . . . . 36
Appendix A.
NSC Product Architecture and Addressing . . . . . . . . . . . . 38
Appendix B.
Network Systems HYPERchannel protocols . . . . . . . . . . . . 42
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GOALS OF THIS DOCUMENT
In this document, there are four major technical objectives:
1. To bless a "de facto" standard for IP on HYPERchannel that has
been implemented by Tektronix, Cray, NASA Ames, and others.
We are attempting to resolve some interoperability problems with
this standard so as to minimize the changes to existing IP on
HYPERchannel software. If any ambiguities remain in the de facto
standard, we wish to assist in their resolution.
2. To address larger networks, NSC's newer network products are
moving to a 32-bit address from the current 16-bit TO address.
This document would introduce the addressing extension to the
user community and specify how IP datagrams would work in the
new addressing mode.
3. To define an Address Resolution Protocol for HYPERchannel and
other NSC products. It is probably well known that current NSC
products do not support the broadcast modes that make ARP
particularly useful. However, many have expressed interest in
"ARP servers" at a known network address. These servers could
fade away as NSC products with broadcast capability come into
existence. Host drivers that can generate and recognize this
ARP protocol would be prepared to take advantage of it as the
pieces fall into place.
4. Part of this effort is to standardize the unofficial "message
type" field that reserves byte 8 of the HYPERchannel network
message. To permit better interoperability, NSC will initiate a
"network protocol registry" where any interested party may
obtain a unique value in byte 8 (or bytes 8 and 9) for their own
public, private, commercial or proprietary protocol. Lists of
assigned protocol type numbers and their "owners" will be
periodically published by NSC and would be available to
interested parties.
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BASIC HYPERCHANNEL NETWORK MESSAGES
Unlike most datagram delivery systems, the HYPERchannel network
message consists of two parts:
Message Proper
+--------------------+
| |
| |
| 10-64 bytes |
| |
| |
+--------------------+
Associated Data
+----------------------------------------------------+
| |
| |
| |
| |
| Unlimited length |
| |
| |
| |
| |
+----------------------------------------------------+
The first part is a message header that can be up to 64 bytes in
length. The first 10 bytes contain information required for the
delivery of the entire message, and the remainder can be used by
higher level protocols. The second part of the message, the
"Associated Data," can be optionally included with the message
proper. In most cases (transmission over HYPERchannel A trunks), the
length of the associated data is literally unlimited. Others (such
as HYPERchannel B or transmission within a local HYPERchannel A A400
adapter) limit the size of the Associated Data to 4K bytes. If the
information sent can be contained within the Message Proper, then the
Associated Data need not be sent.
HYPERchannel lower link protocols treat messages with and without
Associated Data quite differently; "Message only" transmissions are
sent using abbreviated protocols and can be queued in the receiving
network adapter, thus minimizing the elapsed time needed to send and
receive the messages. When associated data is provided, the
HYPERchannel A adapters free their logical resources towards driving
the host interface and coaxial trunks.
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BASIC (16-BIT ADDRESS) MESSAGE PROPER HEADER
The first 10 bytes of the network Message Proper are examined by the
network adapters to control delivery of the network message. Its
format is as follows:
byte Message Proper
+------------------------------+-----------------------------+
0 | Trunks to Try | Message Flags |
| TO trunks | FROM trunks | |EXC|BST|A/D|
+--------------+---------------+-----------------+---+---+---+
2 | Access code |
| |
+------------------------------+-----------------------------+
4 | Physical addr of | | TO Port |
| destination adapter (TO) | | number |
+------------------------------+-----------------------------+
6 | Physical addr of source | |FROM port|
| adapter (FROM) | | number |
+------------------------------+-----------------------------+
8 | Message type |
| |
+------------------------------+-----------------------------+
10 | |
| Available for higher level protocols |
| |
| |
+------------------------------+-----------------------------+
TRUNKS TO TRY
Consists of two four bit masks indicating which of four possible
HYPERchannel A coaxial data trunks are to be used to transmit the
message and to return it. If a bit in the mask is ON, then the
adapter firmware will logically AND it with the mask of installed
trunk interfaces and use the result as a candidate list of
interfaces. Whenever one of the internal "frames" are sent to
communicate with the destination adapter, the transmission hardware
electronically selects the first non-busy trunk out of the list of
candidates. Thus, selection of a data trunk is best performed by the
adapter itself rather than by the host. "Dedicating" trunks to
specific applications only makes sense in very critical real time
applications such as streaming data directly from high speed
overrunnable peripherals.
A second Trunk mask is provided for the receiving adapter when it
sends frames back to the transmitter, as it is possible to build
"asymmetric" configurations of data trunks where trunk 1 on one box
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RFC 1044 IP on Network Systems HYPERchannel February 1988
is connected to the trunk 3 interface of a second. Such
configurations are strongly discouraged, but the addressing structure
supports it if needed.
The "trunks to try" field is only used by HYPERchannel A. To assure
maximum interoperability, a value of 0xFF should be placed in this
field to assure delivery over any technology. Other values should
only be used if the particular site hardware is so configured to not
be physically connected via those trunks.
MESSAGE FLAGS
Contains options in message delivery. In the basic type of message,
three bits are used:
ASSOCIATED DATA PRESENT (A/D) is ON if an Associated Data block
follows the Message Proper. 0 if only a message proper is present in
the network message. The value of this bit is enforced by the
network adapter firmware.
BURST MODE (BST) Enables a special mode for time critical transfers
where a single HYPERchannel A coaxial trunk is dedicated during
transmission of the network message. Not recommended for anything
that won't cause peripheral device overruns if data isn't delivered
once message transmission starts.
EXCEPTION (EXC) Indicates to some channel programmed host interfaces
that the message is "out of band" in some way and requires special
processing.
ACCESS CODE
A feature to permit adapters to share use of a cable yet still permit
an "access matrix" of which adapter boxes and physically talk to
which others. Not currently in use by anyone, support is being
discontinued.
TO ADDRESS
Consists of three parts. The high order 8-bits contains the physical
address of the network adapter box which is to receive the message.
The low order 8-bits are interpreted in different ways depending on
the nature of the receiving network adapter. If the receiving
adapter has different host "ports," then the low order bits of the TO
field are used to designate which interface is to receive the
message. On IBM data channels, the entire "logical" TO field is
interpreted as the subchannel on which the incoming data is to be
presented. Parts of the logical TO field that are not interpreted by
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RFC 1044 IP on Network Systems HYPERchannel February 1988
the network adapter are passed to the host for further
interpretation.
FROM ADDRESS
The FROM address is not physically used during the process of
transmitting a network message, but is passed through to the
receiving host so that a response can be returned to the point of
origin. In general, reversing the TO and FROM 16-bit address fields
and the TO and FROM trunk masks can reliably return a message to its
destination.
MESSAGE TYPE
The following two bytes are reserved for NSC. Users have been
encouraged to put a zero in byte 8 and anything at all in byte 9 so
as to not conflict with internal processing of messages by NSC
firmware. In the past, this field has been loosely defined as
carrying information of interest to NSC equipment carrying the
message and not as a formal protocol type field. For example, 0xFF00
in bytes 8 and 9 of the message will cause the receiving adapter to
"loop back" the message without delivering it to the attached host.
Concurrent with this document, it is NSC's intent to use both bytes 8
and 9 as a formal "protocol type" designator. Major protocols will
be assigned a unique value in byte 8 that will (among good citizens)
not duplicate a value generated by a different protocol. Minor
protocols will have 16-bit values assigned to them so that we won't
run out when 256 protocols turn up. Any interested party could
obtain a protocol number or numbers by application to NSC. In this
document, protocol types specific to IP protocols are assigned.
TO ADDRESSES AND OPEN DRIVER ARCHITECTURE
Since not all 16-bits of the TO address are used for the physical
delivery of the network message, the remainder are considered
"logical" in that their meaning is physically determined by host
computer software or (in cases such as the FIPS data channel) by
hardware in the host interface.
Since HYPERchannel is and will be used to support a large variety of
general and special purpose protocols, it is desirable that several
independent protocol servers be able to independently share the
HYPERchannel network interface. The implementation of many of NSC's
device drivers as well as those of other parties (such as Cray
Research) support this service. Each protocol server that wishes to
send or receive HYPERchannel network messages logically "connects" to
a HYPERchannel device driver by specifying the complete 16-bit TO
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RFC 1044 IP on Network Systems HYPERchannel February 1988
address it will "own" in the sense that any network message with that
TO address will be delivered to that protocol server.
The logical TO field serves a function similar to the TYPE byte in
the Ethernet 802.2 message header, but differs from it in that the
width of the logical TO field varies from host to host, and that no
values of the logical TO address are reserved for particular
protocols. On the other hand, it is possible to have several
"identical" protocols (such as two independent copies of IP with
different HYPERchannel addresses) sharing the same physical
HYPERchannel interface. This makes NSC's addressing approach
identical to the OSI concept that the protocol server to reach is
embedded within the address, rather than the IP notion of addressing
a "host" and identifying a server through a message type.
Since the HYPERchannel header also has a "message type" field, there
is some ambiguity concerning the respective roles of the message type
and logical TO fields:
o The logical TO field is always used to identify the protocol
server which will receive the message. Once a server has
specified the complete TO address for the messages it wishes to
receive, the message will not be delivered to a different
protocol server regardless of the contents of the message type
field.
o Although the "type" field cannot change the protocol server at
the final destination of the message, the type field can be used
by intermediate processes on the network to process the message
before it reaches the server destination. An obvious example is
the 0xFF00 message loopback type function, where network
processing to loop back the message results in nondelivery to
the TO address. In the future, intermediate nodes may process
"in transit" messages based on the message type only for
purposes such as security validation, aging of certain
datagrams, and network management.
EXTENDED (32-BIT ADDRESS) MESSAGE PROPER HEADER
In the original days of HYPERchannel, the limitation of 256 adapter
"boxes" that could be addressed in a network message was deemed
sufficient as 40 or so adapters was considered a "large" network. As
with the Ethernet, more recent networks have resulted in a need to
address larger networks. Although a few ad hoc modes have existed to
address larger HYPERchannel networks for some years, newer
technologies of HYPERchannel equipment have logically extended the
network message to support 32-bits of addressing, with 24 of those
bits to designate a physical network adapter.
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This 32-bit header has been designed so that existing network
adapters are capable of sending and receiving these messages. Only
the network bridges need the intelligence to select messages
designated for them.
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RFC 1044 IP on Network Systems HYPERchannel February 1988
+------------------------------+-----------------------------+
0 | Trunks to Try | Message Flags |
| TO trunks | FROM trunks |GNA|CRC| |SRC|EXC|BST|A/D|
+--------------+---------------+---+---+--+--+---+---+---+---+
2 | TO Domain # | TO Network # |
| | |
+------------------------------+-----------------------------+
4 |O| Physical addr of | | TO Port |
|N| destination adapter (TO) | | number |
+------------------------------+-----------------------------+
6 |O| Physical addr of source | |FROM port|
|N| adapter (FROM) | | number |
+------------------------------+-----------------------------+
8 | Message type |
| |
+------------------------------+-----------------------------+
10 | FROM Domain # | FROM Network # |
| | |
+------------------------------+-----------------------------+
12 | - reserved - | age count |
| | |
+------------------------------+-----------------------------+
14 | Next Header Offset | Header End Offset |
| (normally 16) | (normally 16) |
+------------------------------+-----------------------------+
16 | Start of user protocol |
| bytes 16 - 64 of message proper |
| |
+------------------------------+-----------------------------+
Associated Data
+-----------------------------------------------------------------+
| |
| As with basic format network messages |
| |
+-----------------------------------------------------------------+
ADDRESS RECOGNITION AND MESSAGE FORWARDING
With the 32-bit form of addressing, NSC is keeping with the premise
that the native HYPERchannel address bears a direct relation to the
position of the equipment in an extended HYPERchannel network.
Each collection of "locally" attached NSC network adapters that are
connected by coax or fiber optic cable (with the possible addition of
nonselective repeaters such as the ATRn series) is considered a
"network". Each network can have up to 256 directly addressable
adapters attached to it which can be reached by the basic format
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RFC 1044 IP on Network Systems HYPERchannel February 1988
network message.
Existing bridges or "link adapters" can be programmed to become
"selective repeaters" in that they can receive network messages
containing a subset of network addresses send them over the bridge
medium (if present) and reintroduce them on the other network. Such
interconnected local area networks are considered a single network
from an addressing point of view.
A large NSC network can have up to 64K networks which can be
complexly interconnected by network bridges and/or "backbone"
networks which distribute data between other networks. To simplify
the mechanics of message forwarding, the 16-bit network field is
divided into two eight quantities, a "network number" identifying
which network is to receive the message and a "domain number" which
specifies which network of networks is the recipient.
The bridge technology adapters which move messages between networks
have address recognition hardware which examines all the 24-bits in
bytes 2-5 of the network message header to determine if the bridge
should accept the message for forwarding. At any given instant of
time in the network, each bridge will have a list of networks and
domains that it should accept for forwarding to a network at the
other end of the bridge. Each Adapter (Including Newer Technology
host adapters) contains in address recognition hardware:
o domainmask -- a 256-bit mask of domain numbers that should be
accepted for forwarding (not local processing) by this adapter.
o MyDomain -- the value of the domain on which this host
adapter or bridge end is installed.
o NetworkMask -- a 256-bit mask of network numbers that should be
accepted for forwarding by this adapter.
o MyNetwork - the value of the network on which this host
adapter or bridge end is installed.
o AddressMask -- A 256-bit mask of the local network addresses
that should be accepted by the adapter.
o MyAddress -- the "base address" of the box, which must be
supplied in any message that is directed to control processes
within the adapter, such as a loopback message.
Address recognition takes place using the algorithm:
IF Domain IN DomainMask OR
IF (Domain = MyDomain AND Network IN NetworkMask) OR
IF (Domain = MyDomain AND Network = MyNetwork AND
Address IN AddressMask) THEN accept-message
ELSE ignore-message.
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RFC 1044 IP on Network Systems HYPERchannel February 1988
This algorithm means that an adapter's hardware address recognition
logic will accept any messages to the box itself, any secondary or
aliased local addresses owned by the adapter, and any message
directed to a remote network or domain that that particular adapter
is prepared to forward.
32-BIT MESSAGE FIELDS
TRUNK MASK
Is as in the basic network message. Messages that are to be
delivered outside the immediate network should have 0xFF in this byte
so that all possible trunks in intermediate networks should be tried.
Locally delivered 32-bit messages may still contain specially
tailored trunk masks to satisfy local delivery needs.
MESSAGE FLAGS
The currently defined bits remain as before. Three new bits have
been defined since that time.
CRC (END-END MESSAGE INTEGRITY). Newer technology host adapters are
capable of generating a 32-bit CRC for the entire network message as
soon as it is received over the channel or bus interface from the
host. This 32-bit CRC is appended to the end of the associated data
block and is preserved through the entire delivery process until it
is checked by the host adapter that is the ultimate recipient of the
message, which removes it. This end to end integrity checking is
designed to provide a high degree of assurance that data has been
correctly moved through all intermediate LAN's, geographic links, and
internal adapter hardware and processes.
SRC (SOURCE FROM ADDRESS CORRECT). This bit is provided to take
advantage of the physical nature of the network address to optionally
verify that the 32-bit FROM address provided in the network message
is in fact the location that the message originated. If the bit is
not set by the transmitting host, no particular processing occurs on
the message. If the bit is set, then all intermediate adapters
involved in the delivery of the message have the privilege of turning
the bit off if the received message FROM address is not a TO address
that would be delivered to the originator if the message were going
the opposite direction.
If the message is received by a host computer with this bit still
set, then the FROM address is guaranteed correct in the sense that
returning a message with TO and FROM information reversed will result
in delivery of the message to the process that actually originated
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RFC 1044 IP on Network Systems HYPERchannel February 1988
it. By careful attention to the physical security of adapters and
intermediate links between networks, a high degree of security can be
built into systems that simply examine the FROM address of a message
to determine the legitimacy of its associated request.
GNA (GLOBAL NETWORK ADDRESSING). This bit ON indicates that 32-bit
addressing is present in the message. When this bit is on, bytes 2-3
(Domain and Network numbers) should also be nonzero.
TO ADDRESS
Four bytes contain the TO address, which is used to deliver the
network message as described in "Address Recognition and Message
Forwarding" on page 8. The "logical" part of the TO address is used
to designate a protocol server exactly as in the basic format network
message header.
The existing "address" field has its high order bit reserved as an
outnet bit for compatibility with existing A-series network adapter
equipment. Were it not for this bit, the A-series adapters would
attempt to accept messages that were "passing through" the local
network on their way elsewhere simply because the address field
matched while the the Domain and Network numbers (ignored by the A-
series adapters) were quite different.
This "outnet" bit is used in the following way:
o All network adapters (of any type) in an extended set of
networks containing A-Series adapters that will ever use 32-bit
addressing must have their addresses in the range 00-7F (hex.)
o If a message is to be sent to a destination on a nonlocal
network and domain on such an extended network, then the
high order bit of the address field is turned on.
o When the last bridge in the chain realizes that it is about to
forward the message to its final destination (the Domain and
Network numbers are local), then it turns the Outnet bit off.
This will result in local delivery to the destination adapter.
FROM ADDRESS
The FROM address follows the same logic as the TO address in that any
message can be returned to its source by reversing the FROM and TO
fields of the message. Since so many protocols examine byte 8 of the
message to determine its type, the FROM field has been split so that
the Domain and Network numbers extend into bytes 10-11.
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MESSAGE TYPE
This field (informally defined in the past) has been extended to 16-
bits so that a unique value can be assigned to any present or future
protocol which is layer on HYPERchannel messages for either private
or public use.
AGE COUNT
This field serves the same purpose as the IP "time to live" in that
it prevents datagrams from endlessly circulating about in an
improperly configured network. Each time a 32-bit message passes
through a bridge, the Age Count is decremented by one. When the
result is zero, the message is discarded by the bridge.
NEXT HEADER OFFSET AND HEADER END OFFSET
These are used as fields to optionally provide "loose source
routing", where a list of 32-bit TO addresses can be provided by the
transmitter to explicitly determine the path of a message through the
network. If this feature is not used, both these fields would
contain the value 16 (decimal) to both indicate extra TO addresses
are absent and that the beginning of protocol data following the
HYPERchannel header is in byte 16.
Although it is conceivable that a HYPERchannel IP process could use
this source routing capability to direct messages to hosts or
gateways, this capability is not felt to be of sufficient value to IP
to build it into a HYPERchannel IP protocol.
In the future, all higher level protocols should be able to examine
Header End Offset to determine the start of the higher level protocol
information.
BROADCASTING
NSC message forwarding protocols use low level link protocols to
negotiate transmission of a message to its next destination on the
network. Furthermore, NSC network boxes often "fan out" so that
several hosts share the same network transmission equipment as in the
A400 adapter. Both these characteristics mean that providing a
genuine broadcast capability is not a trivial task, and in fact no
current implementations of NSC technology support a broadcast
capability.
The last several years have seen broadcast applications mature to the
point where they have virtually unquestioned utility on a local and
sometimes campuswide basis. Accordingly, new NSC technologies will
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RFC 1044 IP on Network Systems HYPERchannel February 1988
support a broadcast capability. Information on the use of this
capability is included here as it is essential to the discussion of
the Address Resolution Protocol later in this document.
Broadcast capability will be supported only with the extended (32-bit
address) message format. A broadcast message will have the following
general appearance:
byte Message Proper
+------------------------------+-----------------------------+
0 | Trunks to Try | Message Flags |
| TO trunks | FROM trunks |GNA|CRC| |SRC|EXC|BST|A/D|
+--------------+---------------+---+---+--+--+---+---+---+---+
2 | TO Domain Number | TO Network Number |
| or 0xFF | or 0xFF |
+------------------------------+-----------------------------+
4 | 0xFF | Broadcast channel number |
| | |
+------------------------------+-----------------------------+
6 |O| Physical addr of source | |FROM port|
|N| adapter (FROM) | | number |
+------------------------------+-----------------------------+
8 | Message type |
| |
+------------------------------+-----------------------------+
10 | FROM Domain Number | FROM Network Number |
| | |
+------------------------------+-----------------------------+
12 | - reserved - | age count |
| | |
+------------------------------+-----------------------------+
14 | Next Header Offset | Header End Offset |
| (normally 16) | (normally 16) |
+------------------------------+-----------------------------+
16 | Start of user protocol |
| bytes 16 - 64 of message proper |
| |
+------------------------------+-----------------------------+
Associated Data
+-----------------------------------------------------------------+
| |
| As with basic format network messages |
| Maximum associated data size 1K bytes. |
| |
+-----------------------------------------------------------------+
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TRUNKS TO TRY AND MESSAGE FLAGS
These fields are defined just as with a normal 32-bit message. All
bits in the Message Flags field are valid with broadcast modes.
BROADCAST ADDRESS
For Domain, Network and Adapter Address fields, the value 0xFF is
reserved for use by the broadcast mechanism. A value of 0xFF in the
adapter address field indicates to the local network hardware that
this message is to be sent to all connected network equipment on the
individual network.
A value of 0xFF in the network or domain fields, respectively
indicates a request that the scope of the broadcast exceed the local
network. The bridging link adapters will receive the broadcast
message along with everyone else and will examine the "Broadcast
Channel" field and their internal switches to determine if the
message should be forwarded to other remote networks.
If the Network and Domain fields contain the local network and
domain, then the broadcast message will only be broadcast within the
local network. If a remote Network and Domain is specified, then the
message will be delivered as a single message to the remote network
and broadcast there.
BROADCAST CHANNEL
Since individual hosts and protocol servers generally are not
interested in all broadcast messages that float about the network, a
filtering mechanism is provided in the header and network adapter
equipment so that only proper classes of broadcast messages are
delivered to the end point.
Broadcast channel numbers in the range 00-0xFF will be assigned by
NSC much like the "message type" field. Host protocol servers
specify a specific TO address containing a channel number (such as
0xFF04) when they bind themselves to the HYPERchannel device driver.
The driver and the underlying equipment will deliver only broadcast
messages with the correct channel number to the protocol server. If
a protocol server wishes to receive several different broadcast
messages, it must bind itself to the driver several times with the
desired addresses.
Link adapters that are prepared to handle multinetwork broadcast
messages may be equipped with switches to determine which broadcast
channels will be propagated into the next network. Since
multinetwork broadcast is an arrangement that must be configured with
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care, these switches are off by default.
FROM ADDRESS
The FROM address is constructed just as with a normal 32-bit network
message. The Source Address Correct bit is processed just as with a
normal message.
MESSAGE TYPE
Message type is defined as with normal messages. Presumably
broadcast applications will have unique message types that are not
generally found in normal messages.
AGE COUNT
Age count is vitally important in a multinetwork broadcast as "loops"
in the network can cause a great deal of activity until all the
progeny of the original broadcast message die out.
PROTOCOL SPECIFICATION
This section contains information on the technique used to
encapsulate IP datagrams on the HYPERchannel network message. It
contains three sections to describe three protocol packagings:
o The technique used to encapsulate IP datagrams on the basic
16-bit network message. This is a de facto standard that has
been in use for several years and is documented here to make it
official.
o The encapsulation technique for IP datagrams on 32 bit network
messages.
o The definition of an Address Resolution Protocol on
HYPERchannel.
Hardwick & Lekashman [Page 17]
RFC 1044 IP on Network Systems HYPERchannel February 1988
BASIC (16-BIT) MESSAGE ENCAPSULATION
Message Proper
+------------------------------+-----------------------------+
0 | Trunks to Try | Message Flags |
| TO trunks | FROM trunks |GNA|CRC| |SRC|EXC|BST|A/D|
+------------------------------+-----------------------------+
2 | Access code 0000 |
| (no longer supported) |
+------------------------------+-----------------------------+
4 | Physical addr of | Protocol server |Dest Port|
| destination adapter | logical address | number |
+------------------------------+-----------------------------+
6 | Physical addr of | Originating | Src Port|
| source adapter | server address | number |
+------------------------------+-----------------------------+
8 | IP on HYPERchannel | Offset to start of IP |
| type code 0x05 | header from message start |
+------------------------------+-----------------------------+
10 | IP type designator | Offset to start of IP |
| 0x34 | header from byte 12 |
+------------------------------+-----------------------------+
12 | Padding (variable length incl. zero bytes) |
| |
+------------------------------+-----------------------------+
Off | First (64-Offset) bytes of IP datagram |
| |
| |
| |
+------------------------------+-----------------------------+
Associated Data
+------------------------------+-----------------------------+
| |
| Remainder of IP datagram |
| |
| No associated data is present if IP |
| datagram fits in the Message Proper |
| |
+------------------------------+-----------------------------+
TRUNK MASK
From the vantage of an IP driver, any trunk mask is valid so long as
it results in successful delivery of the HYPERchannel network message
to its destination. There is no reason to check this field for
validity on reception of the message. Specification of the Trunk
Mask on output is a local affair that could be specified by the
transmitting driver's address resolution tables.
Hardwick & Lekashman [Page 18]
RFC 1044 IP on Network Systems HYPERchannel February 1988
MESSAGE FLAGS
No use is made of the Flags field (byte 1) other than to
appropriately set the Associated Data bit. Burst Mode and the
Exception bit should not be used with IP.
ACCESS CODE
Although some current implementations of IP on HYPERchannel support
the access code, no one appears to be using it at the current time.
Since this field is currently reserved for the use of 32-bit
addresses, no value other than 0000 should be placed in this field.
TO ADDRESS
The TO field is generally obtained by a local IP driver through a
table lookup algorithm where a 16-bit TO address is found that
corresponds to the IP address of a local host or gateway. The high
order bits of the TO address of course refer to the adapter number
the adapter attached to the destination host.
The logical TO field should contain the protocol server address of
the HYPERchannel IP driver for that host as determined by the host's
system administrator. Many HYPERchannel TCP/IP drivers in the field
today are not "open" in that any network message delivered to that
host will be presumed to be an IP datagram regardless of the logical
TO field; however any transmitting IP process should be capable of
generating the entire 16-bit TO field in order to generate a message
capable of reaching a destination IP process.
The process of determining which HYPERchannel address will receive an
IP datagram based on its IP address is a major topic that is covered
in "Address Resolution".
FROM ADDRESS
The FROM address is filled in with the address that the local driver
expects to receive from the network, but no particular use is make of
the FROM address.
MESSAGE TYPE
Network Systems requests that a value of 5 (decimal) be placed in
this byte to uniquely indicate that the network message is being used
to carry IP traffic. No other well-behaved protocol using
HYPERchannel should duplicate this value of 5.
Hardwick & Lekashman [Page 19]
RFC 1044 IP on Network Systems HYPERchannel February 1988
Many current implementations of IP on HYPERchannel place a zero or
other values in this field simply because no value was reserved for
IP usage. Transmitting versions of IP should always place a 5 in
this field; receiving IP's should presume a delivered message to be
an IP datagram until proven otherwise regardless of the contents of
the Message Type field.
Developers should note that it is often convenient to permit
reception of the value 0xFF00 in bytes 8 and 9 of the IP datagram.
Transmitting a message with this value will cause it to be looped
back at the destination adapter and returned to the protocol server
designate in the FROM address. This permits the developer have host
applications talk to others on the same host for purposes of network
interface or other protocol debugging.
IP HEADER OFFSET
Byte 9 contains the offset to the start of the IP header within the
message proper, such that the Message Proper address plus the IP
header offset generates the address of the first byte of the IP
header (at least on byte addressable machines.)
This field is redundant with the offset field in byte 11, and is
present for cosmetic compatibility with 32-bit implementations. On
reception, the value in byte 11 should take precedence.
As part of the migration to larger HYPERchannel headers, this field
will become significant with the 32-bit addressing format, as the
length of the header is no longer 10 bytes and byte 11 is used for
other purposes.
IP TYPE DESIGNATOR
Early implementations of IP drivers on HYPERchannel wanted to leave
bytes 8 and 9 alone for NSC use and place a "message type" field in
later in the message. A value of 0x34 had been selected by earlier
developers for reasons that are now of only historical interest.
Once again, implementations should generate this value on
transmission, but not check it on input, assuming that an IP datagram
is present in the message.
IP HEADER OFFSET
This value is used by a number of commercial implementations of IP on
HYPERchannel to align the start of the IP header within the network
message. This offset is relative to byte 12 of the network message
so that a value of zero indicates that the IP header begins in byte
12. This value should be both correctly generated on transmission,
and always respected on input processing.
Hardwick & Lekashman [Page 20]
RFC 1044 IP on Network Systems HYPERchannel February 1988
The maximum permissible offset in this field is 52 indicating that
the IP header begins at the start of the associated data block.
IP DATAGRAM CONTENTS
Beginning at the offset designated in byte 11, the IP datagram is
treated as a contiguous block of data that flows from byte 63 of the
message proper into the first byte of associated data, so that the
entire message plus data is treated as a single contiguous block.
If the IP header is small enough to fit within the entire network
message, then only the message proper is transmitted. The length of
the message proper sent should always be 64 bytes, even if the IP
datagram and HYPERchannel header do not occupy all 64 bytes of the
message proper.
If the datagram flows over into the associated data, then both
message and data are sent. Since a number of machines cannot send a
length of data to the HYPERchannel that is an exact number of bytes
(due to 16-64 bits on the channel bus,) the length of the associated
data received should not be used as a guide to the length of the IP
datagram -- this should be extracted from the IP header. A driver
should verify, of course, that the associated data received is at
least as long as is needed to hold the entire IP datagram.
COMPATIBILITY WITH EXISTING IMPLEMENTATIONS
The basic format described here is clearly a compromise between
several implementations of IP on HYPERchannel. Not all existing
implementations are interoperable with the standard described above.
Currently there are two known "families" of IP HYPERchannel drivers
in existence:
THE "CRAY-NASA AMES" PROTOCOL
This protocol is in the widest production use and has the largest
number of supported drivers in existence. It is interoperable and
identical with the standard described above with the sole exception
that bytes 8 and 9 are set to zero by these drivers. As these bytes
are ignored by most implementations of this driver, they have been
assigned values to formalize the use of the message type field and to
make it consistent with the 32-bit protocol.
THE "TEKTRONIX-BERKELEY" PROTOCOL
This protocol was historically the first IP on HYPERchannel
implementation developed (at Tektronix) and subsequently made its way
to Berkeley and BSD UNIX. This protocol is not interoperable with
Hardwick & Lekashman [Page 21]
RFC 1044 IP on Network Systems HYPERchannel February 1988
the standard described above due to several distinct differences.
First, bytes 8 through 11 are always zero. The IP header always
starts on byte 12. Comments in some of these drivers designate byte
11 as an "IP header offset" field, but apparently this value is never
processed.
The major difference (and the incompatibility) concerns the packaging
of the IP datagram into the network message. Due to historical
difficulties in the early 80's with the sending and receiving of very
small blocks of associated data on VAXes, this protocol the takes a
curious approach to the placement of the IP header and the headers of
higher level protocols (such as TCP or UDP.)
o If the entire length of the IP datagram is 54 bytes or less,
it is possible to fit the entire datagram and the HYPERchannel
header in the 64 byte message proper. In this case, no
associated data is sent; only a message proper is used to carry
the data. The length of the message proper transmitted is the
exact length needed to enclose the IP datagram; no padding bytes
are sent at the end of the message.
o If the length of the IP header is greater than 54 bytes, then:
- All higher level protocol information (TCP/UDP header and
their associated data fields) are placed in the associated
data block, with the TCP/UDP header beginning at the start
of the associated data block.
- On transmission, the length of the message proper
transmitted is set to the length of the HYPERchannel header
plus the IP header -- it is not padded out to 64 bytes.
The length of the associated data sent should be sufficient
to accommodate the TCP/UDP header and its data fields.
Hardwick & Lekashman [Page 22]
RFC 1044 IP on Network Systems HYPERchannel February 1988
WHICH PROTOCOL IS BEST?
In choosing which to follow, the "Cray-Ames" approach was taken for
several reasons:
1. Cray Research has performed exemplary work in dealing with other
vendors to provide IP on HYPERchannel from the Cray computers to
other hosts. As a result, there are 4 or 5 vendor supported
implementations of IP on HYPERchannel that use this approach.
2. The two part structure of the message proper has its uses when a
machine wishes to make protocol decisions before staging the
transfer of an immense block of associated data into memory.
Many network coprocessors and intelligent I/O subsystems find it
simpler to read in the entire network message before deciding
what to do with it. Arbitrarily catenating the two components
does this best and permits streaming of messages from future
technology network adapters.
3. Some TCP users (mostly secure DoD sites) intend to load up IP
datagrams with optional fields in the future. The
Tektronix-Berkeley implementation has problems if the IP header
length exceeds 54 bytes.
Hardwick & Lekashman [Page 23]
RFC 1044 IP on Network Systems HYPERchannel February 1988
EXTENDED (32-BIT) MESSAGE ENCAPSULATION
Message Proper
+------------------------------+-----------------------------+
0 | Trunks to Try |1| Message Flags |
| TO trunks | FROM trunks |GNA|CRC| |SRC|EXC|BST|A/D|
+------------------------------+-----------------------------+
2 | Destination Domain | Destination Network |
| Number | Number |
+------------------------------+-----------------------------+
4 |O| Physical addr of | Protocol server |Dest Port|
|N| destination adapter | logical address | number |
+------------------------------+-----------------------------+
6 |O| Physical addr of | Originating | Src Port|
|N| source adapter | server address | number |
+------------------------------+-----------------------------+
8 | IP on HYPERchannel | Offset to start of IP |
| type code 0x06 | datagram header |
+------------------------------+-----------------------------+
10 | Source Domain Number | Source Network Number |
| | |
+------------------------------+-----------------------------+
12 | - reserved - | Age Count |
+------------------------------+-----------------------------+
14 | Next Header Offset | Header End Offset |
| | (usually 16) |
+------------------------------+-----------------------------+
16 | Padding to IP header start (usually 0 bytes) |
| |
+------------------------------+-----------------------------+
Off| Entire IP datagram if datagram length <= (64-Offset) |
| |
| else first (64-Offset) bytes of IP datagram |
+------------------------------+-----------------------------+
Associated Data
+------------------------------+-----------------------------+
| |
| Remainder of IP datagram |
| |
| No associated data is present if IP |
| datagram fits in the Message Proper |
| |
+------------------------------+-----------------------------+
TRUNK MASK
From the vantage of an IP driver, any trunk mask is valid so long as
Hardwick & Lekashman [Page 24]
RFC 1044 IP on Network Systems HYPERchannel February 1988
it results in successful delivery of the HYPERchannel network message
to its destination. There is no reason to check this field for
validity on reception of the message. Specification of the Trunk
Mask on output is a local affair that can be specified by the
transmitting driver's address resolution tables.
The use of 0xFF in this value is strongly encouraged for any message
other than those using exotic trunk configurations on a single local
network.
MESSAGE FLAGS
Several new bits have been defined here.
EXTENDED ADDRESSING. This bit should be set ON whenever a 32-bit
address (Network and/or Domain numbers nonzero) is present in the
message. It should always be OFF with the 16-bit message header. If
this bit is improperly set, delivery of the message to the (apparent)
destination is unlikely.
END-TO-END CRC. Some newer technology adapters are equipped to place
a 32-bit CRC of the associated data at the end of the associated data
block when this bit is on. Similarly equipped adapters will examine
the trailing 32-bits of associated data (when the bit is on) to
determine if the message contents have been corrupted at any stage of
the transmission.
Transmitting device drivers should include the ability to set this
bit on transmission as a configuration option similar to the specific
HYPERchannel device interface used. The bit should be generated to
be turned ON if the HYPERchannel IP driver is attached to an adapter
equipped to generated CRC information -- it should be left OFF in all
other circumstances.
If a message arrives at the host with the CRC bit still on, this
indicates that the CRC information was placed at the end of
associated data by the transmitting adapter and not removed by the
receiving adapter; thus the associated data will be four bytes longer
than otherwise expected. Since the IP datagram length is self
contained in the network message, this should not impact IP drivers.
It is possible for host computers to both generate and check this CRC
information to match the hardware assisted generation and checking
logic in newer network adapters. Contact NSC if there are particular
applications requiring exceptional data integrity that could benefit
from host generation and checking.
Hardwick & Lekashman [Page 25]
RFC 1044 IP on Network Systems HYPERchannel February 1988
FROM ADDRESS CORRECT. This bit should be set by all transmitting IP
drivers who have endeavored to provide a completely correct FROM
address that properly reflects the adapter interface used. No action
should be taken on this bit by the receiving IP driver at this time.
Additional work needs to be done to determine the action an IP driver
should take if it detects a real or imagined "security violation"
should a message arrive with this bit absent.
TO ADDRESS
The TO address logically constitutes bytes 2-5 of the network
message.
NETWORK AND DOMAIN NUMBERS. The Network and Domain numbers should
both be nonzero when 32-bit addressing is used. If the message is
local in nature, then the local Network and Domain numbers should be
placed in this field.
ADAPTER ADDRESS. Contains the adapter address as in the basic
message. The high order bit of this eight bit field (the "outnet"
bit) should be set to zero if the destination network and domain are
the same as the transmitting host's. The high order bit should be
set to one if the destination host is not in the local network or
domain.
LOGICAL TO AND SUBADDRESS. The logical TO field should contain the
protocol server address of the HYPERchannel IP driver for that host
as determined by the host's system administrator.
FROM ADDRESS
The FROM address is filled in with the address that the local driver
expects to receive from the network, but no particular use is made of
the FROM address.
MESSAGE TYPE
The value 6 must be placed in this byte to uniquely indicate that the
network message is being used to carry IP traffic. No other well-
behaved protocol using HYPERchannel should duplicate this value of 6.
Note that all IP drivers should be prepared to send and receive the
basic format network messages using the 16-bit HYPERchannel
addresses. The driver can distinguish an incoming network message by
the value of byte 8 -- 32-bit messages will always have a 6 in byte
8, while 16-bit messages should have a 5 here. For interoperability
with older drivers, a value of 0 here should be treated as 16 address
bit messages.
Hardwick & Lekashman [Page 26]
RFC 1044 IP on Network Systems HYPERchannel February 1988
IP HEADER OFFSET
Byte 9 contains the offset to the start of the IP header within the
message proper, such that the Message Proper address plus the IP
header offset generates the address of the first byte of the IP
header (at least on byte addressable machines.)
Unlike the 16-bit header, receiving IP drivers should assume that
this field contains a correct offset to the IP header and examine the
information at that offset for conformance to an IP datagram header.
Valid offsets are in the range of 16 through 44 bytes, inclusive.
The limitation of 44 bytes is imposed so that routing decisions on
the vast majority of IP datagrams can be made by examining only the
message proper, as the basic IP datagram will fit into the message
proper if it begins at an offset of 44.
IP DATAGRAM CONTENTS
The message and data are treated as logically contiguous entities
where the first byte of associated data immediately follows the 64th
byte of the message proper.
If the entire IP datagram is less than or equal to (64-offset) bytes
in length it will fit into the Message Proper. If so, only a message
proper containing the HYPERchannel header and IP datagram is sent on
the network.
If the IP datagram is greater than this length, the IP datagram
spills over into the associated data. On transmission, a 64 byte
message proper is sent followed by as many bytes of associated data
as are needed to send the entire datagram.
On reception, the message proper can be read into the start of an IP
input buffer and the associated data read into memory 64 bytes from
the start of the message. If the received message is in fact a 32-
bit address message, no "shuffling" of the message will be required
to build a contiguous IP datagram -- it's right there at buffer+16.
ADDRESS RESOLUTION PROTOCOL
Address Resolution Protocol has achieved a great deal of success on
the Ethernet as it permits a local IP network to configure itself
simply by having each node know its own IP address. Those unfamiliar
with the intent, protocol, and logic of the Address Resolution
Protocol should refer to RFC-826, "An Ethernet Address Resolution
Protocol" [2].
Hardwick & Lekashman [Page 27]
RFC 1044 IP on Network Systems HYPERchannel February 1988
A later section of this document describes four techniques where a
target HYPERchannel address is to obtained given the destination's IP
address. The protocol is defined in this section for completeness.
Message Proper
+------------------------------+-----------------------------+
0 | Trunks to Try |1| Message Flags |
| TO trunks | FROM trunks |GNA|CRC| |SRC|EXC|BST|A/D|
+------------------------------+-----------------------------+
2 | Server Domain or | Server Network or |
| 0xFF | 0xFF |
+------------------------------+-----------------------------+
4 | Server Adapter Address or | Server logical addr/port or |
| 0xFF | 07 |
+------------------------------+-----------------------------+
6 |O| Physical addr of | Originating | Src Port|
|N| source adapter | server address | number |
+------------------------------+-----------------------------+
8 | NSC ARP type code |
| 07 | 00 |
+------------------------------+-----------------------------+
10 | Source Domain | Source Network |
+------------------------------+-----------------------------+
12 | - reserved - | Age Count |
+------------------------------+-----------------------------+
14 | Next Header Offset | Header End Offset |
| (usually 16) | (usually 16) |
+------------------------------+-----------------------------+
16 | Padding to start of IP info (usually 0 bytes) |
+------------------------------+-----------------------------+
Hardwick & Lekashman [Page 28]
RFC 1044 IP on Network Systems HYPERchannel February 1988
+------------------------------+-----------------------------+
Off | ARP hardware address type for HYPERchannel |
| 8 |
+------------------------------+-----------------------------+
+2 | HYPERchannel protocol type |
| 06 00 |
+------------------------------+-----------------------------+
+4 | HYPERchannel address length | IP address length |
| 6 | 4 |
+------------------------------+-----------------------------+
+6 | ARP opcode (request or reply) |
+------------------------------+-----------------------------+
+8 | Domain | Network |
+- Sender's 32-bit HYPERchannel address -+
+10 | Adapter address | Logical addr/port |
+------------------------------+-----------------------------+
+12 | Source's MTU size |
+------------------------------+-----------------------------+
+14 | | |
+- Sender's 32-bit IP address -+
+16 | |
+------------------------------+-----------------------------+
+18 | Domain | Network |
+- Destination's 32-bit HYPERchannel address -+
+20 | (to be determined on request) |
| Adapter address | Logical addr/port |
+------------------------------+-----------------------------+
+22 | Destination's MTU size |
| (to be determined on request) |
+------------------------------+-----------------------------+
+24 | | |
+- Destination's 32-bit IP address -+
+26 | |
+------------------------------+-----------------------------+
Layout of the fields of this ARP message is a fairly straightforward
exercise given the standards of ARP and the 32-bit message header. A
few fields are worth remarking upon:
TO ADDRESS
The TO address of an ARP message will be one of two classes of
address. A "normal" address indicates that the message is an ARP
response, or that it is an ARP request directed at an ARP server at a
well known address on the local network. For those HYPERchannel
networks which are equipped to broadcast, a value of 0xFFFFFF07 in
the TO address will (by convention) be picked up only by those
protocol servers prepared to interpret and respond to ARP messages.
Hardwick & Lekashman [Page 29]
RFC 1044 IP on Network Systems HYPERchannel February 1988
The issue of which address to use in an ARP request is discussed in
the Address Resolution section.
FROM ADDRESS
Must be the correct FROM address of the user protocol server issuing
an ARP request. The Source Correct bit in the Message Flags byte
should be set by this requesting server, as some ARP servers may
someday choose to issue ARP information on an "need to know" basis in
secure environments. With an ARP response, the FROM address will
contain the "normal" HYPERchannel address of the protocol server
responding to the ARP address, even if that server was reached via
broadcast mechanisms.
ARP responses are returned to the party specified in the FROM address
specified in the message header, rather than the address in the
"Source HYPERchannel Address" field within the body of the ARP
message.
MESSAGE TYPE
The 16-bit value 0x0700 is reserved for the exclusive use of ARP.
Unlike IP messages, no provision is made for the ARP message to begin
at an arbitrary offset within the message proper, so the value in
byte 9 is an extension of the message type.
HEADER END OFFSET
ARP uses the 32-bit addressing convention that byte 15 contains the
offset to the start of user protocol (and hence the end of user
protocol information). Note that this is not a substitute for the IP
offset fields, as this field also serves as the end of HYPERchannel
header information -- future NSC message processing code may well
take exception to "garbage" between the actual header end and the
start of user data.
HYPERCHANNEL HARDWARE TYPE CODE
This 16-bit number is assigned a formal ARP hardware type of 8.
HYPERCHANNEL PROTOCOL TYPE
On the Ethernet, this field is used to distinguish IP from all other
protocols that may require address resolution. To be logically
consistent, this field is identical to bytes 8 and 9 0x0600 in a 32-
bit address HYPERchannel message carrying an IP datagram.
Hardwick & Lekashman [Page 30]
RFC 1044 IP on Network Systems HYPERchannel February 1988
HYPERCHANNEL ADDRESS LENGTH
This contains the value 6, a sufficient number of bytes to
accommodate the four byte HYPERchannel address and 2 bytes to
indicate the largest IP datagram size that source and destination can
handle.
SOURCE AND DESTINATION HYPERCHANNEL ADDRESS
This field contains the Domain, Network, and Adapter/port address of
source and destination, respectively. A value of 0000 in the Domain
and Network fields has special significance as this is interpreted as
a request to send and receive 16-bit HYPERchannel headers rather than
32-bit headers. If 32-bit headers are to be used within a single
HYPERchannel network, then the local domain and network numbers may
be specified.
MAXIMUM TRANSMISSION UNIT
HYPERchannel LAN technology is such that messages of unlimited length
may be sent between hosts. Since host throughput on a network is
generally limited by the rate the network equipment can be
functioned, larger transmission sizes result in higher bulk transfer
performance. Since not every host will be able to handle the maximum
size IP datagram, a more flexible means of MTU (maximum transmission
unit) size negotiation than simply wiring the same value into every
network host is needed. With this field, each host declares the
maximum IP datagram size (not the associated data block size) it is
prepared to receive. Transmitting IP drivers should be prepared to
send the minimum of the source and destination IP sizes negotiated at
ARP time.
The MTU size sent refers to the maximum size of IP header + data. It
does not include the length of the HYPERchannel Hardware header or
any offset between the header and the start of the IP datagram.
Since it is the option of the transmitting hosts to use an offset of
up to 44 bytes a receiving host must in any event be prepared to
receive a 64 byte Message Proper and an Associated Data block of
MTU-20 (that is 64 - 44, or the length of the basic IP header).
An example of a typical 16-bit packet is:
12 bytes hardware header.
12 bytes offset.
40 bytes IP/TCP header.
4096 bytes of data.
This gives an MTU of 4136.
Hardwick & Lekashman [Page 31]
RFC 1044 IP on Network Systems HYPERchannel February 1988
An example of a typical 32-bit packet is:
16 bytes hardware header.
8 bytes offset.
40 bytes IP/TCP header.
4096 bytes of associated data,
This also gives an MTU of 4136.
The offset values are chosen so that the typical packet causes user
data to be page aligned at the start of the associated data area.
This is an implementation decision, which can certainly be modified
as required.
The maximum maximum transmission unit is 65536, the current largest
size IP datagram. In order to allow this value to fit into a 16-bit
field, the offset length is not included in the MTU. This MTU size
is not a requirement that a local host be equipped to send or receive
datagrams of that size; it simply indicates the maximum capacity of
the receiving host.
A note on trunk masks:
There is no field for specifying trunk masks. This is intentional,
as new NSC hardware will contain trunk reachability information,
eliminating the need for the host to maintain hardware configuration
layouts. All HYPERchannel messages generated as a result of an ARP
response should use 0xFF in the trunk mask.
ADDRESS RESOLUTION
This section describes techniques used by an IP driver to determine
the HYPERchannel address and header that a message should contain
given an IP datagram containing an IP address. It describes
techniques that are local to specific hosts (and hence can be
modified without regard to the activities or techniques of other
hosts) as well as techniques to use the Address Resolution Protocol
on existing HYPERchannel equipment to better manage IP addresses.
It also discusses the migration of name resolution on one of four
steps.
1. Truncation of the IP address to form a HYPERchannel address.
2. Local resolution of HYPERchannel addresses through configuration
files.
3. Centralized resolution of HYPERchannel addresses through an "ARP
server" driven by a configuration file.
Hardwick & Lekashman [Page 32]
RFC 1044 IP on Network Systems HYPERchannel February 1988
4. Distributed resolution of HYPERchannel addresses using a "real"
address Resolution Protocol on future HYPERchannel media
supporting a broadcast mode.
IP ADDRESS TRUNCATION
A number of IP on HYPERchannel implementations support modes where
the HYPERchannel address is generated by placing the low order 16-
bits of the IP address in the TO address of the message proper. This
more or less treats a set of HYPERchannel boxes addressable through
16-bit HYPERchannel addresses as a Class B IP network.
This approach certainly offers simplicity: IP addresses are simply
chosen to match HYPERchannel addresses and no IP address
"configuration files" need be kept. Although this approach works in
an environment where the HYPERchannel completely constitutes a Class
B network, or where connection to a larger IP network is not a
concern, its long term use is discouraged for several reasons:
o It simply will not work with any Class C address (the physical
TO address is not controllable) or a Class A address (where host
addresses are generally carefully administered.) In addition,
it will not support subnetworks. It is quite incompatible with
32-bit HYPERchannel addresses.
o By decoupling the IP and HYPERchannel addresses through more
complex address resolution, the characters of the two addresses
allow greater site flexibility: the IP address becomes
"logical" in character so that an address can move about a site
with the user or host; the HYPERchannel address maintains its
physical character so that a HYPERchannel address carefully
identifies the physical location of the source and destination
within the extended HYPERchannel network.
LOCAL ADDRESS RESOLUTION
The current state of address resolution art with IP on HYPERchannel
works as follows: given an arbitrary IP address, the IP HYPERchannel
driver looks up an entry with that address in a (generally hashed)
table. If found, the table entry contains the first 6 bytes of the
HYPERchannel header that is used to send the IP datagram to the next
IP node on the internet. Since implementations such as the 4.3BSD
UNIX IP are clever enough to provide its lower level drivers with the
IP address of the next gateway as well as the destination address on
the internet (assuming the message is not delivered locally on the
HYPERchannel,) the number of entries in this table is more or less
manageable, as it must only contain the IP hosts and gateway
addresses that are directly accessible on the HYPERchannel.
Hardwick & Lekashman [Page 33]
RFC 1044 IP on Network Systems HYPERchannel February 1988
CONFIGURATION FILE FORMAT
So long as this technique of address resolution is used, the
techniques used are exclusively local to the host in the sense that
the techniques used to generate and store the information in the
table are irrelevant to other hosts.
Shown here is a typical file format. This file should probably be
program generated from a database, as asymmetric trunk configurations
and multiply homed hosts can cause differences in physical routing
and trunk usage. This format is documented here to illustrate what
sort of information must be kept at the link layer.
The file consists of source lines each with the form:
<type> <hostname> <trunks/flags> <domain/net> <addr> <MTU>
an example:
<type> <hostname> <t/f> <dom/net> <addr> <MTU>
# Random front end
host hyper.nsco.com FF88 0103 3702 4148
# because we want to show the 4 byte format
host 192.12.102.1 FF00 0000 2203 1024
# Small packets, interactive traffic.
host cray-b.nas.nasa.gov FF88 0103 4401 4148
# The other interface, for big packets.
ahost cray-b.nas.nasa.gov FF88 0103 4501 32768
# A loopback interface, (What else)
loop loop37.nsco.com FF00 0000 3700 4148
# And of course an example of arp service.
arpserver hcgate.nsco.com FF88 0103 7F07
Comments may begin with either # or ;.
Case is not significant in any field.
<type> indicates the type of entity to be defined.
Currently defined types are "host," "ahost", "loop," "address,"
and "arpserver".
host This token indicates an IP host. The following field is
expected to be a name that can be resolved to an IP
address.
ahost This field indicates an additional network interface to
the same host. This may be used for performance
enhancements.
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RFC 1044 IP on Network Systems HYPERchannel February 1988
loop Sets a flag in the entry for that host so that 0xFF00 is
placed in bytes 8 and 9 of the message. This will cause
the IP datagram to be directed towards the specified host
(which must still be a valid host name) and looped back
within the remote adapter. This facility serves both as a
debugging aid and as a crude probe of the availability of
the remote network adapter.
arpserver This indicates an address to use for directing ARP
requests to the network. If several arpserver addresses
are specified, they will be tried in turn until a response
is received (or we run out of servers.) An arpserver with
the appropriate broadcast address of FFFF FF07 would
cause an ARP broadcast to take place when broadcasting
becomes available. Broadcast and specific addresses may
be used in combination.
<hostname> This field is the logical name of the destination. For a
host it is the logical name to be given to the local naming service
to determine the associated IP address. This field may contain four
decimal numbers separated by dots, in which case it is assumed to be
the explicit IP address.
<trunks/flags> This field is the value to be placed in bytes 0 and 1
of the message header when sending to this host. The associated data
bit need not be supplied as the driver must control it. All other
bits are sent as provided. This field is a hexidecimal number.
<domain/net> This field is the value to be placed in the Domain and
Network number field of the message. A value of 0000 in this field
indicates that the destination should be reached by constructing a
16-bit HYPERchannel header, rather than a 32-bit header.
<address> This field is the value to be placed in the 16-bit TO field
to reach <hostname>. This field is a hexidecimal number.
<MTU> This field contains the largest size IP datagram that the
destination host is prepared to receive. This field is a decimal
number. This field is optional. If not present, a value of 4148 is
assumed. See the earlier discussion on Maximum Transmission Unit for
more detail.
ARP SERVERS
The primary problem with local host address resolution is that
changes or additions to hosts on the local net must be replicated to
every HYPERchannel host in that network. While this is manageable
for up to half a dozen hosts, it becomes quite unmanageable for
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RFC 1044 IP on Network Systems HYPERchannel February 1988
larger networks. An approach that can be implemented using existing
HYPERchannel technology is to have a server on the HYPERchannel
network provide the HYPERchannel destination address that is
associated with an IP address.
Although this is strictly a point-to-point request/response dialogue
between two network nodes, the Address Resolution Protocol which was
originally designed for Ethernet (but thoughtfully constructed to
work with any pair of link and network addresses) performs an
excellent job.
ARP servers can be reached simply by placing the address of the
server in the 32-bit TO address of the network message. ARP servers
only "listen" to messages that arrive on their well known normal
address; they do not respond to ARP broadcast messages. Properly
equipped IP drivers should respond to the broadcast messages when
they appear.
If an ARP server receives a message containing an IP address it does
not know how to resolve, it ignores the message so that another ARP
server might be addressed at the source's next attempt.
If the address is resolvable, it places the known HYPERchannel
address and MTU size in the response and returns it to the location
in the HYPERchannel header FROM address.
Unlike a broadcast ARP, the ARP server will be required to service
two requests when two hosts that are initially unknown to one another
attempt to get in touch. Since the destination did not receive the
ARP request, it must contact the ARP server when its higher level
protocols first generate a datagram to respond to the the source's
first IP datagram to go through to the destination.
The source configuration file described in the previous section was
explicitly designed so that it could be sufficient as a data base for
an ARP server as well as an individual host.
BROADCAST ARP
When a local HYPERchannel network contains a broadcast capability,
any IP driver wishing to perform HYPERchannel address resolution may
be configured to emit the ARP message on a broadcast instead of a
well known address. IP drivers on other hosts are presumed to know
if their local HYPERchannel interface can send broadcast messages; if
so, they arrange to "listen" on the FF07 broadcast TO address for
ARP.
Processing of a received ARP broadcast message is otherwise identical
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RFC 1044 IP on Network Systems HYPERchannel February 1988
to RFC-826:
o Messages are responded to if and only if the destination IP
driver is authoritative for the designated IP address.
o Whenever an ARP message is processed, the IP driver takes the
source HYPERchannel address and MTU size and adds it to its
address resolution tables. Thus the driver is equipped to
turn around the IP datagram that arrives from the destination
host when contact is made.
Each IP driver may have address resolutions that are set through a
static routing table (the configuration file specified above). If
ARP information arrives that contradicts a static entry (as opposed
to previously set dynamic ARP information) then the ARP information
should be ignored. This decision is made on the premise that the
only useful purpose of static routing in a broadcast ARP environment
is to add authentication, as it's easy to lie with ARP.
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RFC 1044 IP on Network Systems HYPERchannel February 1988
APPENDIX A. NSC PRODUCT ARCHITECTURE AND ADDRESSING
This section is intended to be a concise review of the state of the
art in NSC networks and the techniques they provide for the delivery
of messages. Those who are thoroughly familiar with HYPERchannel may
wish to only skim this section; however, there is material on new
technologies and addressing formats that are not yet generally known
to most of NSC's customers.
NETWORK SYSTEMS HYPERCHANNEL TECHNOLOGIES
Network Systems manufactures several different network technologies
that use very different media and link controls, but still provide a
common host interface in both the protocol and hardware sense of the
term. These four technologies are:
o HYPERchannel A -- A 50-megabit, baseband, CSMA with collision
avoidance network using a coaxial cable bus. Individual
HYPERchannel "network adapters" can control up to 4 of these
coaxial cable "trunks," providing up to 200 megabits of
capacity on a fully interconnected network. HYPERchannel A
is NSC's earliest product and has been in production since
1977. It is principally used to interconnect larger
mainframe computers and high speed mainframe peripherals such
as tape drives and laser printers.
o HYPERchannel B -- a 10-megabit, baseband, CSMA with collision
avoidance network using a single coaxial cable bus. This
technology is used for direct host to host communications under
the name HYPERchannel B, and for terminal connections under the
name HYPERbus. It is currently used for three major
applications -- local networks of ASCII terminals, networks
of IBM 3270 terminals, and host to host communications of
smaller computers.
o DATAPIPE[3] -- a 275-megabit fiber optic "backbone" network
that interconnects lower speed local area networks within a 20
mile range, and to provide an ultra-high-performance network for
the next generation of supercomputers and optical storage
systems. A prototype version of DATApipe is currently under
development at a customer site.
o Bridges and Network Distance Extensions -- NSC quickly
discovered that its customers wanted very high speeds over
geographic areas, not just within the range of several miles
that is conceivable with a coaxial cable network. Starting
in 1978, NSC began to build a series of "link adapters" that
are integral bridges between local area networks. These link
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RFC 1044 IP on Network Systems HYPERchannel February 1988
adapters support common high speed communications media such
as Telco T1 circuits, private microwave, high speed
satellite links, and fiber optic point to point connections.
ATTACHMENT TO HOST COMPUTERS
Network Systems' high speed interfaces use the attachment techniques
of the manufacturer's highest speed peripheral controllers in order
to achieve burst transfer rates of tens of megabits per second.
These attachment techniques fall into three categories:
"MAINFRAME" DATA CHANNEL ATTACHMENT
+-----------+-------+ +------------+ | | | |
| | | |HYPERchannel+--+ | | |
| | +-------------------+ Network +--|-+ | |
| Host | I/O +-------------------+ Adapter +--|-|-+ |
| | | Standard host | +--|-|-|-+
| Computer |Control| data channel +------------+ | | | |
| | |
| | |
| | |
| | |
+-----------+-------+
The network adapter contains interface boards and firmware to be
cabled to the manufacturer's data channel, such as would be done with
a disk or tape controller. Mainframe network adapters do not emulate
an existing manufacturer's device (such as a tape drive) but are
supported by software which functions the channel and adapter to send
and receive network messages.
Models of HYPERchannel adapters are available for essentially all
large scale computers worldwide.
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RFC 1044 IP on Network Systems HYPERchannel February 1988
MINICOMPUTER AND WORKSTATION ATTACHMENT
Since the network adapter contains lots of expensive, high speed
logic, a different technique is used to provide attachment to
minicomputers and workstations.
+-------------+ +---------------+ +--------------+
| | | | | |
| Minicomputer| | Supermini | | Workstation |
| | | | | |
+-----+-------+ +-------+-------+ +-------+------+
| | DMA | | | DMA | | DMA | |
| |control| | |control| |control| |
+-----+---++--+ +-------+--++---+ +--++---+------+
|| || ||
|| || ||
|+----------+ || +---------+|
+----------+| || |+---------+
|| || ||
+-++--+-----+--++-+--++-+
| | | | |
+-----+-----+-----+-----+
| x400 |
| Network Adapter |
| |
+-------+-+-+-+---------+
| | | |
------------------|-|-|-+----------------
------------------|-|-+------------------
------------------|-+--------------------
------------------+----------------------
In this case, NSC provides a DMA controller designed for direct
connection to that minicomputer's backplane bus. These DMA
controllers accept functions and burst blocks of data from host
memory to a channel cable that is connected to one of four ports on a
"general purpose computer adapter." This adapter multiplexes
transmissions to and from the HYPERchannel trunks from up to four
attached processors.
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RFC 1044 IP on Network Systems HYPERchannel February 1988
NETWORK COPROCESSORS
For about 10 different bus systems, Network systems provides a
"smart" DMA controller containing onboard memory and a Motorola 68010
protocol processor.
+------------+-----+---------------+-------+
| | | Coprocessor | | +--------+
| |Host | MC 68010 |Adapter+--------+ x400 |
| HOST |DMA | 256K memory | DMA +--------+ Adapter|
| | | | | +--------+
| Memory +-----+---------------+-------+
| |
+------------+
This class of interface works through the network coprocessor's
direct access to host memory. Network transmit and receive request
packets are placed in a common "mailbox" area and extracted by the
coprocessor. The coprocessor reads and writes system memory as
required to service network requests in the proper order. The
coprocessors currently provide a service to read or write network
messages (called Driver service as it is more or less identical to
HYPERchannel dumb DMA drivers) and a service for NETEX, which is
NSC's OSI-like communications protocol.
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RFC 1044 IP on Network Systems HYPERchannel February 1988
APPENDIX B. NETWORK SYSTEMS HYPERCHANNEL PROTOCOLS
The protocols implemented by NSC within its own boxes are designed
for the needs of the different technologies. A compact summation of
these protocols is:
HYPERchannel B HYPERchannel A DATApipe
10 Mbits/second 50-200 Mbits/second 275 Mbits/second
+----------------------+----------------------+---------------------+
| |
| HYPERchannel network message |
| connectionless datagram protocol |
| |
+----------------------+----------------------+---------------------+
| "HYPERchannel | | |
| compatibility mode" | HYPERchannel A | DATApipe |
| Virtual circuit | reservation and | acknowledgment |
| estab. & control | flow control | & flow control |
+----------------------+ protocol | protocol |
| | | |
| Virtual Circuits | | |
| Flow Control | | |
+----------------------+----------------------+---------------------+
| CSMA / VT | CSMA / CA | |
| frame (datagram) | frame (datagram) | TDMA packet delivery|
| delivery and | delivery and | |
| acknowledgment | acknowledgment | |
+----------------------+----------------------+---------------------+
| | | Fiber optics |
| 75 ohm coax | 1-4 75 ohm coax | (various cable sizes|
| cable | cables | and xmission modes)|
+----------------------+----------------------+---------------------+
Without getting into great detail on these internal protocols, a few
points are particularly interesting to system designers:
o All three technologies supply the same interface to the host
computer or network coprocessor, a service to send and receive
network messages that are datagrams from the host's vantage in
that each contains sufficient information to deliver the message
in and of itself. Since this datagram and its header fields are
of paramount interest to the host implementor, it is discussed
in detail below.
o All technologies use acknowledgments at a very low level to
determine if packets have been successfully delivered. In
addition to permitting a highly tuned contention mechanism for
the coax medium, it also permits HYPERchannel A to balance the
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RFC 1044 IP on Network Systems HYPERchannel February 1988
load over several coax cables -- a feat that has proven very
difficult on, for example, Ethernet.
o All boxes go to some lengths to assure that resources exist
in the receiving box before actual transmission takes place.
HYPERchannel B uses a virtual circuit that endures for several
seconds of inactivity after one host first attempts to send a
message to the other. Traffic over this "working virtual
circuit" is flow controlled from source to destination and
buffer resources are reserved for the path.
HYPERchannel A exchanges frames at very high rates to determine that
the receiver is ready to receive data and to control its flow as data
moves through the network.
DATApipe propagation time is relatively long compared to the time
needed to send an internal packet of 2K-4K bytes. As a result,
DATApipe controllers use a streamlined TP4-like transport protocol to
assure delivery of frames between DATApipe boxes.
REFERENCES
[1] HYPERchannel is a trademark of Network Systems Corporation.
[2] Plummer, D., "An Ethernet Address Resolution Protocol",
RFC-826, Symbolics, September 1982.
[3] DATApipe is a registered trademark of Network Systems
Corporation.
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