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IETF RFC 107
Output of the Host-Host Protocol Glitch Cleaning Committee
Last modified on Tuesday, April 29th, 1997
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Network Working Group
Request for Comments # 107
NIC # 5806
Output of the Host-Host Protocol
Glitch Cleaning Committee
UCLA
23 March 1971
Robert Bressler
Steve Crocker
William Crowter
Gary Grossman
Ray Tomlinson
James Withe
PAGE 1
Introduction
The Host-Host Protocol Glitch Cleaning Committee met for the second
time at UCLA on 8, 9 March 1971, after canvassing the network com-
munity. [The result of the (slightly larger) committee's first
meeting are documented in RFC #102.] The committee agreed on
several modifications to the protocol in Document #1; these modi-
fications are listed below.
At each of the meeting, the committee quickly treated all but one
of the extant topics. At the first meeting, the bulk of time was
spent considering the interrupt mechanism, and that discussion is
summarized in RFC #102. At the second meeting, the committee spent
almost all of its time discussing the notion of bytes; this dis-
cussion is summarized after the list of modifications.
This RFC entirely supercedes RFC #102, and is an official modi-
fication of Document #1. A revision of Document #1 will be written
shortly which incorporates the changes listed here.
NCP implementers are to incorporate these changes as soon as
possible. NCP implementers also are to estimate on what date
theis NCP's will be ready and to communicate this estimate to
Steve Crocker or his secretary, Byrna Kristel.
PAGE 2
Modifications
I Bytes
Heretofore, a connection has been a bit stream. Henceforth, it is to
be a byte stream, with the byte size, S, indicated in the STR command
and in each message. The byte size meets the constraints: 1 <= S <=
255.
The choice of the byte size for a connection is a 3rd level protocol
issue, but the size is constant for the life of a connection. Each
message must contain an integral number of text bytes (see below).
II Message Format
The message format is changed to the format shown in figure 1.
The fields S and C are the byte size and byte count, respectively.
The S field is 8 bits wide and must match the byte size specified in
the STR which created the connection. The C field is 16 bit long and
specifies the number of bytes in the text portion of the message. A
zero value in the C field serves no purpose, but is explicitly
permitted.
The M1 and M2 field are each 8 bits long and must contain zero. The
M3 field is zero or more bits long and must be all zero. The M3 may
be used to fill out a message to a word boundary. It is followed by
padding.
The text field consists of C bytes, where each byte is S bit long.
The text field starts 72 bits after the start of the message.
The partition of a byte stream into messages is an artifact
required by the subnet. No semantic contents be attacched
to message boundaries. In particular,
PAGE 3
32 bits
|<--------------------------------->|
+-----------------------------------+
| |
| leader |
| |
+--------+--------+-----------------+
| | | |
| M1 | S | C |
| | | |
+--------+--------+-----------------+
| | ^ |
| M2 | | |
| | | |
+--------+ | |
| | |
| | |
| |
| Text |
// //
| | |
| | |
| | |
| | |
| | +--------+
| | | |
| | | M3 |
| v | |
+-----------------+--------+--------+
| |
| 10 --------- 0 | <-- Padding
| |
+-----------------+
Typical Message
Figure 1
PAGE 4
1. A message with a zero value for C has no meaning, although
it is legal and it does use up resource allocation. (See
Flow Control below.)
2. A receiver may not expect to see 3rd level control infor-
mation synchronized with message boundaries. Particuralrly,
if the notion of record is defined for a connection, the
receiver must expect multiple records and/or record frag-
ments within one message. (However, control message obey
special rules. See below.)
III Message Data Types
No notion of data type is defined as part of the 2nd level pro- tocol.
3rd level protocols may include the notion. Data types cannot be
synchronized on message boundaries.
IV Reset and Reset Reply
A new pair of one bit control commands RST (reset) and RRP (reset
reply) are added. The RST is interpreted as a signal to purge the NCP
tables of all existing entries which arose from the Host which sent to
RST. The Host receiving the RST acknowledges by returning a RRP. The
Host sending the RST may proceed to request connection after receiving
either a RST or RRP in return. An RST is returned if the second Host
comes up after the first Host.
V Flow Control
The flow control techniques are changed in two ways. First, the Cease
mechanism is discontinued. The 10HI and 11HI message will no longer
be recognized by the Imps, and the Imps will no loger generate the
10HI, 11HI or 12HI messages.
PAGE 5
Second, the allocation mechanism now deals with two quantities, bits
and messages. The receiver allocates each of these quantities
separately. The sender and receiver each must mantain a 16 bit
unsigned counter for message and a 32 bit unsigned counter for bits.
When sending a message, the sender subtract one from the message
counter, and the text length from the bit counter. The receiver
decrements his counter similarly when receiving the message. The
sender is prohibited from sending if either counter would be decre-
mented below zero. Similarly, the receiver is prohibited from raising
the current message allocation above 2**16 - 1, or the current bit
allocation above 2**32 - 1.
The TEXT LENGTH of a message is the product of S, the byte size, and
C, the number of bytes. These values always appear in the first part
of the message, as described under Message Format.
The ALL, GVB, and RET command are modified to treat two quantities.
Their formats are given under Control Command, below. The GVB command
is further modified to make it possible to ask for none of the
allocation to be returned. The new GVB command has four eight bit
fields. The first two fields are the op code and the link, as before.
The next two fields contain number fM and fB which control how much of
message and a bit allocation are to be returned. Each of these
numbers is interpreted as "the number of 128ths of the current
allocation" to be returned if it is in the range of 0 to 128, and is
to be interpreted as "all of the current allocation", if it is in the
range 128 to 255.
VI Control Message
The control link is chsnged to link 0; link 1 is not to be used. The
old and new protocols may thereforre coexist.
PAGE 6
Message sent over the control link have the same format as other
regular messages, as described above under Message Format. The byte
size field must contain the value 8.
Control messages may not contain more tha 120 byte of text; the
value in the byte count field is thus limited to 120. This limi-
tation is intended to help smaller hosts.
Control messages must contain an integral number of control commands.
Control commands, therefore, may not be split across control messages.
VII Link Assignment
The link are now assigned as follows:
0 control link
1 old protocol's control link - to be phased out
2 - 31 links for connections
32 - 190 reserved -- not for current use
191 to be used only for measurement work under direction
of the network measurement center (UCLA)
192 - 255 available for any private experimental use.
VIII Fixed Length Control Commands
The ECO, ERP and ERR commands are now fixed length. The ECO and ERP are
now 16 bit long -- 8 bits of op code and 8 bits of data. The ERR command
is now 96 bits long -- 8 bits of op code, 8 bits of error code, and 80
bits of text. 80 bits is long enough to hold the longest non-ERR control
command.
PAGE 7
IX Control Command Formats
As mentioned above, the formats of the STR, ALL, GVB, RET, ECO, ERP and
ERR commands have changed; and the commands RST and RRP have been added.
The formats of these commands are given here.
| 8 | 32 | 32 | 8 |
+-----+-----------------------+-----------------------+-----+
| | | | |
1. | STR | send socket | receive socket | |
| | | | ^ |
+-----+-----------------------+-----------------------+--|--+
|
| 8 | 8 | 16 | 32 | +-- byte size
+-----+-----+-----------+-----------------------+
| | | | |
2. | ALL | link| msg space | bit space |
| | | | |
+-----+-----+-----------+-----------------------+
| 8 | 8 | 16 | 32 |
+-----+-----+-----------+-----------------------+
| | | | |
3. | RET | link| msg space | bit space |
| | | | |
+-----+-----+-----------+-----------------------+
| 8 | 8 | 8 | 8 |
+-----+-----+-----+-----+
| | | | |
4. | GVB | link| fM | fB |
| | | ^ | ^ |
+-----+-----+--|--+--|--+
| |
| +-- bit fraction
+-------- message fraction
| 8 | 8 |
+-----+-----+
| | |
5. | ECO |data |
| | |
+-----+-----+
PAGE 8
| 8 | 8 |
+-----+-----+
| | |
6. | ERP |data |
| | |
+-----+-----+
| 8 | 8 | 80 |
+-----+-----+---------------------- // -----------------------+
| | | |
7. | ERR | | text |
| | ^ | |
+-----+--|--+---------------------- // -----------------------+
|
+-- error code
| 8 |
+-----+
| |
8. | RST |
| |
+-----+
| 8 |
+-----+
| |
9. | RRP |
| |
+-----+
The values of the op codes are
NOP = 0
RTS = 1
STR = 2
CLS = 3
ALL = 4
GVB = 5
RET = 6
INR = 7
INS = 8
ECO = 9
ERP = 10
ERR = 11
RST = 12
RRP = 13
PAGE 9
Discussion on Byte Streams
The previous specification that connections would be conduits of bit
streams provided maximum generality and minimum efficiency. Pressure
for greater efficiency developed and the problen was examined.
Two separate kinds of inefficiency arose from bit streams.
1. Receiving Hosts were equired to engage in expensive
shifting to concatenate the texts of successive
messages. Sending Hosts often also had to shift text
fields to align them on word boundaries.
2. Sending NCP's were prohibited from hanging onto ANY
text for an indefinite time if it were possible to send
even one bit. This requirement was necessary to prevent
possible deadlocks. For example, suppose processes A
and B have a conversation in progress over a pair of
connections, one in each directions. Also suppose that
these processes produce exactly one bit of output for
each bit of input. Then if A's NCP fails to send a
waiting bit because it wants to pack it together with
later output from A, then B will not be able to output
and neither will A. It is clear then, that unless there
is some quantitee that the data in the sending NCP's
buffers are not crucially needed on the receive side, the
sending NCP must assume otherwise and transmit any
waiting data as soon as it is able.
These considerations led to the notion of a "transmission unit," whose
existence would be known to the NCP's. The questions then became what
were typical and/or possible transmission unit sizes. For
PAGE 10
character-oriented interaction, 8-bit transmission units seemed
reasonable. For line-oriented interaction, the transmission unit might
best be the line itself, and therefore variable length; alternatively,
it might be best consider the transmission unit to be a character. For
file transfer, it might be desirable for the transmission unit to be a
multiple of the word lengths of both machines; however, the last part of
the file may not form a whole transmission unit, if the transmission
unit is too large. The consensus became that the transmission unit
should not be divisible under any circumstances, and should, therefore,
be fairly small. The notion of transmission unit thus seems to be
synonymous with the notation of byte, and the term transmission unit was
dropped.
Subsequent discussion of the deadlocks and wakeup aspect revealed that
there may be two byte sizes associated with a single connection:
1. Transmission from the sending process to the sending NCP
is in bytes of size S. The sending NCP must send a
message whenever the link is unblocked, the message
counter is at least 1, the bit counter is at least S,
and the least S bits of text are ready. The message
must contain an integral number of bytes.
2. At the receiving side, there may be a different byte
size R for transmission from the receiving NCP to the
receiving process. An example of where R <> S, is
suggested by UCSB which is providing a file system for
transparently storing binary files. It is reasonable that
a using HOST might send with 36 bit bytes, while the UCSB
file system might want to receive 32-bit increments.
It is clear that from a network protocol point of view, only the byte S
is relevant, and this is quantity which is communicated in the STR
command in every message. The choice of the byte size R is up
PAGE 11
to the receiving user, and its meaning is how often the receiving NCP
should wakeup the receiving process. It may also happen that a
receiving process has an agreement with the receiving NCP which is more
complex than "please wake me every R bits;" for example, the NCP might
scan for new-line characters before waking up the receiving process.
In the new protocol, it is the option of the receiver to refuse a
request for connection on the basis of the proffered byte size.
Conceptually, we imagine that NCP's are capable of handling all byte
sizes, and that such a choice would be up to the third level pro- grams
(user programs, loggers, telnets, etc.) Some Hosts, small ones in
particular, may know enough about their third level programs to restrict
the variety of byte sizes which can be sent or received. While it is a
matter of a local policy, the committee strongly suggests that NCP's be
capable of handling all byte sizes. One of our committee, moreover,
feels strongly that NCP's should be written to be able to receive all
byte sizes S and provide for different byte sizes R for transmission to
the user process.
[ This RFC was put into machine readable form for entry ]
[ into the online RFC archives by Enrico Bertone 4/97 ]
PAGE 12
Output of the Host-Host Protocol Glitch Cleaning Committee
RFC TOTAL SIZE: 18109 bytes
PUBLICATION DATE: Tuesday, April 29th, 1997
LEGAL RIGHTS: The IETF Trust (see BCP 78)
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