Network Working Group James E. White
Request for Comments: 105 Computer Research Lab.
Category: Informational University of California
Santa Barbara, California
March 1971
Network Specifications for
Remote Job Entry
and
Remote Job Output Retrieval
at UCSB
In the discussions that follow, 'byte' means 8 bits, with those
eight bits numbered 0-7 from left to right.
I - Remote Job Entry (RJE)
UCSB will accept input of pseudo card files for batch processing
at socket number x'200', site 3. Network users should obtain an
account number from the UCSB Computer Center; account #1025,
programmer names 'UCLA', 'SRI', 'UTAH', etc. may be used during
checkout. The 360/75 runs under OS MVT and HASP. Users submit jobs
to HASP for scheduling and subsequent execution by OS through an
intermediary process hereafter called RJE which is addressed as socket
number x'200' and can be invoked through the Logger. This section is
intended to provide programmers with the information necessary to
communicate with RJE; the is assumed familiar with the batch services
offered by the Computer Center, and with its job control language
(JCL) requirements.
RJE conducts all Network transactions through the NCP, which
operates under the Host-Host protocol of 3 August 1970. It expects
the first message it receives to be Type 0, discards the first eight
bits (the message type) assuming them to be zeros, and thereafter for
the life of the connection takes no notice of IMP-message boundaries.
To submit one or more jobs for batch processing, the Network user
must establish a simplex connection with RJE. RJE is core resident
only while such a simplex connection is established (i.e., while a
user is transmitting a file). At all other times, it resides on
direct-access storage and must be invoked through the Logger. A login
sequence can always be initiated by requesting connection to socket
x'200'. RJE does not serve multiple users simultaneously. This if a
connection request is made to that socket while RJE is in use, the NCP
will queue the request. When the current file transmission is
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RFC 105 RJE at UCSB March 1971
complete, RJE will listen for and accept the next request (if any) in
its queue; if no requests are queued for it, it will terminate
execution, releasing the main storage it occupied. At times when RJE
is not in core, the Logger listens on socket x'200', and will reject
the first call it receives, read RJE into core, and dispatch it. RJE
will then list on that socket. Thus to initiate a login sequence, the
user requests connection to socket x'200'. If accepted, he is in
contact with RJE. If rejected, he should reissue the connection
request; when accepted, he will be connected to RJE. A second
rejection would indicate that the NCP's resources were exhausted.
Once the connection has been established, RJE will consider the user
logged in.
To prevent RJE from being monopolized by a single user, provision
is made within the software for terminating a connection if RJE is
ever required to wait more than a certain amount of time for a
transmission from the connected user. For now, this time limit has
been set at one minute per record, but it may be shortened or
lengthened as required in the future. Barring such termination, RJE
will maintain its connection to the user indefinitely. Card images
will be accepted over the connection, and each one will be passed to
HASP as it is received. The user is expected to close the connection
once his file has been transmitted. RJE will interpret that action as
an end-of-file indication, and the user will be considered logged off.
RJE expects the first byte of data it receives over the
connection established with it to be zeros, indicating message Type 0;
it discards this byte unexamined, and thereafter, attaches no
significance to IMP-message boundaries. The second byte of data
received is interpreted as flags specifying the format of the data
(file) to follow. The byte is interpreted as follows:
Bits 0-1 = 00: file follows as Class A (stream-oriented)
input.
= 01: not defined, should not occur.
= 10: file follows as Class B (variable-length
record) input.
= 11: file follows as Class C (fixed-length record)
input.
Bits 2-7 : not examined, should be zeros.
Once made, this declaration prevails for the life of the connection.
Regardless of the input class specified, the user transmits his
file as card images, each of which will be padded on the right with
blanks or truncated on the right to 80 bytes if necessary. The file
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transmitted must be structured exactly as if it were being placed on
the card reader at the Computer Center. A job card and all the other,
usual JCL must be present for each job in the file (batching of jobs
is permissible and is transparent to RJE). For any job which requires
that special (non-resident) disk(s) and/or tape(s) to be mounted, a
special JCL card must be inserted immediately after the job card for
that job, and it must have the format:
/*SETUP vol-ser , vol-ser ,...
1 2
where 'vol-ser ' is the volume serial number of a volume requiring
i
mounting. '/*SETUP' begins in column 1; 'vol-ser ' must begin in
1
column 16. The job will then enter the System in a HASP hold status
until the required volume(s) can be mounted by the operator. If the
user neglects to declare all such required volumes, his job is subject
to immediate cancellation. All cards of the file which are not
contained in a SYSIN data set must consist of valid, EBCDIC
characters.
If input to RJE has been declared as Class A, the third byte of data
received over the connection by RJE is interpreted as a break character
declaration. Each byte received thereafter is compared to that
character. Any other character is taken to be the next byte of the
current card image. Whenever the break character is encountered, the
previous byte is taken to be the last byte of the current card image,
which is then padded or truncated as required and passed to HASP. Zero
or more non-break characters may occur between occurrences of the break
character. Thus when Class A input is specified, data transmitted to
RJE shall have the following form:
1 1 1 variable 1
+-------+-------+-------+ / +------//--------+-------+ \
| | | BREAK | / | | BREAK | \
| x'00' | x'00' | CHAR. | \ | CARD IMAGE | CHAR. | / ...
+-------+-------+-------+ \ +------//--------+-------+ /
where the length of each field has been specified in bytes. Zero or
more occurrences of the quantity in parentheses [angle brackets] may be
transmitted before the connection is closed by the user.
If input to RJE has been declared as Class B, then all input after
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the initial two bytes is expected to consist of a contiguous string of
variable length records, each consisting of a one-byte op code (the op
code should be x'01'), a two-byte length field which specifies the
unsigned length in bits of the variable-length text field which follows.
The text field may be zero or more bytes in length; the length field
must contain an integer which is a multiple of 8. The text field
represents one card image, which is padded or truncated by RJE as
required and passed to HASP. Thus when Class B input is specified, data
transmitted to RJE shall have the form:
1 1 1 2 L bits
+-------+-------+ / +-------+-------+-----//-----+ \
| | | / | | | TEXT | \
| x'00' | x'80' | \ | x'01' | L | card image | / ...
+-------+-------+ \ +-------+-------+-----//-----+ /
where the length of each field has been specified in bytes, except where
stated to the contrary. Zero or more occurrences of the quantity in
parentheses [angle brackets] may be transmitted before the connection is
closed.
If input to RJE has been declared as Class C, then all input after
the initial two bytes is expected to consist of a contiguous string of
fixed-length, 80-byte card images. Thus, when Class C input is
specified, data transmitted to RJE shall have the form:
1 1 80
+-------+-------+ / +--------------------+ \
| | | / | | \
| x'00' | x'C0' | \ | card image | / ...
+-------+-------+ \ +--------------------+ /
where the length of each field has been specified in bytes. Zero or
more occurrences of the quantity in parentheses [angle brackets] may be
transmitted before the connection is closed.
II - Remote Job Output Retrieval (RJOR)
Class A SYSOUT output from jobs submitted through RJE for batch
processing at UCSB may be obtained by contacting socket x'300', site 3,
provided that when the job was submitted, the character 'T' appeared as
the eighth positional accounting parameter on the job card. Output is
retrieved upon request and relayed to the Network user by a process
hereafter called RJOR which is addressed as socket x'300'. RJOR can be
invoked through the Logger. This section is intended to provide
programmers with the information necessary to communicate with RJOR.
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RJOR conducts all Network transactions through the NCP, which
operates under the Host-Host protocol of 3 August 1970. RJOR expects
the first message it receives to be Type 0, discards the first byte,
assuming it to be zeros, and thereafter for the life of the connection
takes no notice of IMP-message boundaries. Similarly, the first message
sent by RJOR is of Type 0: the first byte consists of zeros, and
thereafter for the life of the connection, IMP-message boundaries are
not significant.
To obtain output from a batch-mode job, the Network user must
establish a full duplex connection with RJOR. RJOR is core resident
only while in use (i.e., while control information or a file is being
transmitted to or from a user, or while RJOR is waiting for a previously
requested output file (or files)). At all other times, it resides on
direct-access storage and must be invoked through the Logger. A login
sequence can always be initiated by requesting connection to socket
x'300'. If a connection request is made to that socket while another
user is being logged in, the NCP will queue the request. After the
current connection is terminated, RJOR will listen for and accept the
next request (in any) in its queue; if no requests are queued for it and
if it has fulfilled all of its output file requests, it will terminate
execution, releasing the main storage it occupied. At times when RJOR
is not in core, the Logger listens on socket x'300', and will reject the
first call it receives, read RJOR into core, and dispatch it. RJOR will
then listen on that socket. Thus to initiate a login sequence, the user
requests connection to socket x'300'. If accepted, he is in contact
with RJOR. If rejected, he should reissue the connection request; when
accepted, he will be connected to RJOR. A second rejection would
indicate that the NCP's resources were exhausted. Once this first half
of the required duplex connection has been established, RJOR will
consider the user logged in.
Over this first connection (hereafter called the Input Connection),
the user transmits flags designating the function(s) to be performed by
RJOR, and the name of the job to which the function(s) is(are) to be
applied. RJOR then closes this connection. RJOR transmits control
information specifying the disposition of the user's request and the
output file (if requested) over a secondary connection involving RJOR's
socket number x'301', site 3, and the socket at the user's site whose
socket number is one less than that on which RJOR was contacted by the
user. The user's request may or may not be immediately executable. If
the former is the case, RJOR issues a connection request to the
designated user receive socket, and when the connection is established
transmits whatever control information is appropriate along with the
user's output (if required); RJOR then closes the connection and the
user is considered logged out. If the user's request cannot be
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RFC 105 RJE at UCSB March 1971
immediately satisfied (e.g., the job whose output is sought hasn't been
submitted yet or hasn't finished execution), the second connection is
opened by RJOR just long enough to inform the user of the delay, and
then closed. Then when the request can be serviced, the connection is
reopened, the required data transmitted, and the connection closed; the
user is then considered logged out.
To prevent RJOR from being monopolized by a single user, provision
is made within the software for terminating a connection if RJOR is ever
required to wait more than a certain amount of time for completion of a
transmission to or from the connected user. For now, this time limit
has been set at one minute per record, but it may be shortened or
lengthened as required in the future.
RJOR expects the first byte of data it receives over the Input
Connection to be zeros, indicating message Type 0; it discards this byte
unexamined, and thereafter, attaches no significance to IMP-message
boundaries. The second byte of data received is interpreted as flags
specifying the function(s) to be performed. Following the flag byte,
RJOR expects an eight-byte, EBCDIC job name, padded on the right with
blanks if necessary. The flag byte is interpreted as follows:
Bit 0 = 1: transmit the output generated by the specified job.
Bit 1 = 1: purge the output file created by the specified job.
Bit 2 = 1: wait as long as is required to execute the
function(s) specified by Bits 0-1.
= 0: if the function(s) specified by Bits 0-1 cannot be
executed immediately, simply return an indication of
that fact.
Bit 3 = 1: an earlier request pertaining to the specified job
which exercised the wait-for-output (Bit 2) option
is to be canceled.
Bits 4-7: not examined, should be zeros.
Any combination of Bits 0-2 is permissible. If Bit 3 = 1, no other bits
are examined. If Bit 0 = 1 and Bit 1 = 1, the output file is
transmitted before it is purged. If two jobs with the same name are
executed in succession, output from the second job will overlay that
produced by the first. In such cases, the user should purge the output
from the first job after it has been transmitted to him so that a
request for output from the second job will not simply return a second
copy of the first job's output.
RJOR may open the output connection either one or two times as the
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result of a single transmission on the Input Connection. In each case,
the first byte transmitted will consist of zeros indicating message Type
0, and thereafter for the life of the connection, IMP-message boundaries
are not significant. Following the first byte, RJOR will transmit the
name of the job to which the response applies. The job name will be
contained in an 8-byte field identical to that supplied by the user over
the Input Connection. Following the job name, RJOR will transmit zero
or more variable length logical records. Each will consist of a one-
byte op code, a two-byte length field which specifies the unsigned
length in bits of the variable length text field which follows. The
text field may be zero or more bytes in length; the length field will
contain an integer which is a multiple of eight.
The op codes presently defined are listed in Figure 1. An op code
of x'01' indicates that the text field contains one record of one of the
SYSOUT data sets created by the job whose output was requested. The
length fields of all logical records with an op code of x'01' will be
identical. For data sets with record lengths other than this value,
records are padded on the right side with blanks or truncated on the
right to this standard record length. Carriage control characters which
would ordinarily appear in column 1 for printer-destined output have
been discarded and do not appear.* The records are transmitted to the
user in the same sequence as they would be printed on the printer, and
collectively include everything that would appear in printed output with
the exception of HASP separator sheets.
In all logical records but those with an op code of x'01', the
length field contains the value zero, and the op code conveys the entire
meaning of the logical record.
________________________________________________________________________
*This restriction is temporary; a fix is in the works and will be
announced.
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RFC 105 RJE at UCSB March 1971
Figure 1. Output Connection Op Codes
--------- --------------------------
Op Code
(Hex) Name Explanation
------- ---- -----------
00 End-of-File. All output from the job has been
transmitted (follows last op-code-x'01'
logical record).
01 Output. The text field contains one record of
one SYSOUT data set generated by the
job.
02 Output file purged. Output from the job has been purged as
requested.
03 No core for buffer. Insufficient main storage is available
for transmitting output from the job.
The transmission request has been
aborted and the purge request (if any)
has been suppressed.
04 I/O Error reading An irrecoverable I/O error was
file. encountered reading the output file.
The transmission request has been
aborted and the purge request (if any)
suppressed.
05 I/O Error purging An irrecoverable I/O error was
file. encountered purging the output file.
The purge request was aborted.
06 No queue space for Output from the job was not available
request. and the wait-for-output option was
specified, but RJOR's resources were
insufficient to queue the request,
which was suppressed.
07 Waiting for output. Output from the job is not available
and the wait-for-output option was
specified. RJOR is waiting for the
job's output.
08 Canceled request not The user requested that a previously
found. made request specifying the
wait-for-output option be canceled. No
such request was found by RJOR.
09 Request canceled. At the user's request, a previously
made request specifying the
wait-for-output option has been
canceled.
0A I/O Error seeking An irrecoverable I/O error was
file. encountered attempting to locate output
from the job. The user's request was
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aborted.
0B Output not found. Output from the job was not found. The
wait-for-output option was not
specified by the user.
[ This RFC was put into machine readable form for entry ]
[ into the online RFC archives by Randy Dunlap 4/97 ]
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