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TOPS-20
Release 7.0
Monitor Building Procedures and Information
Revision Date: January 16, 1990
COPYRIGHT (c) DIGITAL EQUIPMENT CORPORATION 1976, 1989.
ALL RIGHTS RESERVED.
THIS SOFTWARE IS FURNISHED UNDER A LICENSE AND MAY BE USED AND COPIED
ONLY IN ACCORDANCE WITH THE TERMS OF SUCH LICENSE AND WITH THE
INCLUSION OF THE ABOVE COPYRIGHT NOTICE. THIS SOFTWARE OR ANY OTHER
COPIES THEREOF MAY NOT BE PROVIDED OR OTHERWISE MADE AVAILABLE TO ANY
OTHER PERSON. NO TITLE TO AND OWNERSHIP OF THE SOFTWARE IS HEREBY
TRANSFERRED.
THE INFORMATION IN THIS SOFTWARE IS SUBJECT TO CHANGE WITHOUT NOTICE
AND SHOULD NOT BE CONSTRUED AS A COMMITMENT BY DIGITAL EQUIPMENT
CORPORATION.
DIGITAL ASSUMES NO RESPONSIBILITY FOR THE USE OR RELIABILITY OF ITS
SOFTWARE ON EQUIPMENT THAT IS NOT SUPPLIED BY DIGITAL.
TOPS-20 Monitor Building Procedures and Information Page 2
TABLE OF CONTENTS
1.0 Introduction . . . . . . . . . . . . . . . . . . . . 3
2.0 Monitor Selection and Building Procedures . . . . . 4
2.1 How to Select a Monitor Configuration . . . . . . 4
2.2 How to Build a Standard Monitor Configuration . . 5
2.3 Internals of LN2070.CTL and T20-AN70.CTL . . . . . 7
3.0 Monitor Configuration Parameters . . . . . . . . . 11
3.1 Parameters Controlling Software Resources . . . 11
3.2 Parameters Controlling System Defaults . . . . . 13
3.3 Parameters for Hardware Support . . . . . . . . 15
4.0 Installation-Specific Terminal Definitions . . . . 18
TOPS-20 Monitor Building Procedures and Information Page 3
1.0 Introduction
This document provides complete information on configuring and
building the TOPS-20 monitor. Multiple configurations are provided so
as to minimize the amount of resident storage used while supporting
all of the available peripheral devices. The "build" procedure
produces a core-image file of the monitor from the various relocatable
files and the one parameter-dependent source file.
Generally, an installation will be able to run one of the
standard monitor configurations supplied. Section 2 of this document
tells how to select the appropriate monitor configuration and how to
run the build procedure.
Some installations may wish to use a set of configuration
parameters different from those of the standard set. Section 3
describes the function of each parameter and its effect on the
resultant configuration.
Section 4 describes how to add installation-specific terminal
definitions.
TOPS-20 Monitor Building Procedures and Information Page 4
2.0 Monitor Selection and Building Procedures
NOTE: This section is intended for anyone who needs to build a
monitor, and it requires a minimum level of familiarity with the
structure or operation of the system. The knowledge which is required
is:
1. How to LOGIN and use basic EXEC commands.
2. How to use the magtape file restore program (DUMPER).
3. How to bring up the system with an existing monitor.
2.1 How to Select a Monitor Configuration
There are five standard monitor configurations. Each of them are
configured for general timesharing and batch usage. The first two are
intended for customers without a TCP/IP (Arpanet) licence. The second
two are intended for sites with a TCP/IP license but without a
DECnet-20 license. The last one is intended for sites with TCP/IP and
DECnet-20 licenses.
You should select the proper monitor based on your hardware
configuration. You will want the smallest monitor which supports all
of the hardware you have and which handles the number of users you
wish to allow.
1. 2060-MONBIG a medium sized monitor, includes DECnet-20, excludes
TCP/IP.
* 100 Jobs
* 30 PTYs
* 64 LAT terminal lines
* 96 RSX20F terminal lines
* 10000 pages swapping space
2. 2060-MONMAX: the maximum sized monitor, includes DECnet-20,
excludes TCP/IP.
* 128 Jobs
* 50 PTYs
* 128 LAT terminal lines
* 128 RSX20F terminal lines
* 15000 pages swapping space
TOPS-20 Monitor Building Procedures and Information Page 5
3. AN-MONBIG: a medium sized monitor, includes TCP/IP, excludes
DECnet-20.
* 100 Jobs
* 30 PTYs
* 50 LAT terminal lines
* 128 RSX20F terminal lines
* 40 TVT terminal lines
* 10000 pages swapping space
4. AN-MONMAX: a maximum sized monitor, includes TCP/IP, excludes
DECnet-20.
* 128 Jobs
* 50 PTYs
* 50 LAT terminal lines
* 128 RSX20F terminal lines
* 40 TVT terminal lines
* 20000 pages swapping space
5. AN-MONDCN: a maximum sized monitor, includes TCP/IP and
DECnet-20.
* 100 Jobs
* 50 PTYs
* 50 LAT terminal lines
* 128 RSX20F terminal lines
* 40 TVT terminal lines
* 40 CTERM terminal lines
* 20000 pages swapping space
2.2 How to Build a Standard Monitor Configuration
At this point, you will have selected one of the standard monitor
configurations described above (or have constructed you own parameter
file as described in Section 3). The following step-by-step procedure
produces a monitor configured according to the parameters in the
corresponding parameter file.
1. Login and connect to a directory containing a complete set of
monitor files. If the monitor files have not been loaded onto the
disk, load them from your distribution tape using DUMPER (document
TOPS20.DOC).
TOPS-20 Monitor Building Procedures and Information Page 6
2. The CTL files require the following logical names be set up.
* R: should point to the directory where REL files are to be
placed.
* MON: should point to the directory for the monitor sources
and support files.
* SYS: should point to the directory containing the latest
MONSYM.UNV, MONSYM.REL, MACSYM.UNV, and MACREL.REL.
These logical names are set up in the CTL by doing a explicit TAKE
of BATCH.CMD in the connected directory. Typically, SYS: should
be defined as DSK:,SYS: and the other the logical names may be
defined as DSK:.
3. If you are building a monitor without TCP/IP (Arpanet), copy the
appropriate parameter file to "PARAM0.MAC". If you are building a
monitor with TCP/IP, copy the appropriate parameter file to
"PARAN.MAC". The parameter files for the various monitors are:
* For 2060-MONBIG copy P70BIG.MAC to PARAM0.MAC
* For 2060-MONMAX copy P70MAX.MAC to PARAM0.MAC
* For AN-MONBIG copy ANPBIG.MAC to PARAN.MAC
* For AN-MONMAX copy ANPMAX.MAC to PARAN.MAC
* For AN-MONDCN copy ANPDCN.MAC to PARAN.MAC
4. If you are building a non-TCP/IP monitor, copy the appropriate
monitor name file to "NAMAM0.MAC". If you are building a TCP/IP
monitor, copy the appropriate name file to "NAMAN.MAC". The name
files for the various monitors are:
* For 2060-MONBIG copy N70BIG.MAC to NAMAM0.MAC
* For 2060-MONMAX copy N70MAX.MAC to NAMAM0.MAC
* For AN-MONBIG copy ANNBIG.MAC to NAMAN.MAC
* For AN-MONMAX copy ANNMAX.MAC to NAMAN.MAC
* For AN-MONDCN copy ANNDCN.MAC to NAMAN.MAC
5. Submit the appropriate batch file for the type of monitor you are
building: LN2070.CTL for a non-TCP/IP monitor or T20-AN70.CTL for
a monitor with TCP/IP. To build the single monitor, the switches
/TAG:SINGLE and /TIME:60 should be used.
* For 2060-MONBIG submit LN2070 /TAG:SINGLE /TIME:60
* For 2060-MONMAX submit LN2070 /TAG:SINGLE /TIME:60
* For AN-MONBIG submit T20-AN70 /TAG:SINGLE /TIME:60
* For AN-MONMAX submit T20-AN70 /TAG:SINGLE /TIME:60
* For AN-MONDCN submit T20-AN70 /TAG:SINGLE /TIME:60
The resultant monitor will be called MONITR.EXE (LN2070.CTL) or
AMONITR.EXE (T20-AN70.CTL).
TOPS-20 Monitor Building Procedures and Information Page 7
2.3 Internals of LN2070.CTL and T20-AN70.CTL
This section is intended to document the internals of the CTL
files that build the TOPS-20 monitor.
The internals of the CTL files do not need to be understood to
build monitors.
The monitor CTL files may be started beginning at several tags.
1. TRAP:: will execute a command to cause all file openings to be
displayed. It then goes to tag BEGIN.
2. FORCE:: will execute a command to force recompilation of all
sources.
3. CREF:: will execute a command to force CREF listings of all
sources. It then goes to tag BEGIN.
4. BEGIN:: builds all standard monitors from sources (2060-MONBIG
and 2060-MONMAX for LN2070.CTL, or AN-MONBIG, AN-MONMAX, AN-MONDCN
from T20-AN70.CTL).
5. ALL:: (LN2070 only) builds all standard monitors using existing
REL libraries LN2070.REL.
6. MONDEV:: builds 2060-MONMAX monitor (LN2070.CTL) or AN-MONDCN
monitor (T20-AN70.CTL) from sources.
7. SINGLE:: builds MONITR.EXE from PARAM0.MAC, NAMAM0.MAC, and
LN2070.REL (LN2070.CTL) or builds AMONITR.EXE from PARAN.MAC,
NAMAN.MAC, and T20AN.REL (T20-AN70.CTL).
If the sources are to be complied, the file MON:ASEMBL.CMD is
TAKEn. This file will compile all of the source modules needed to
create LN2070.REL or T20AN.REL.
After the source files are compiled, the REL files are combined
into the REL library by MON:APPEND.CMD (LN2070.REL) or MON:APPARP.CMD
(T20AN.REL).
Building each monitor consists of the following steps.
1. The source file for the name of the monitor, plus MON:VEDIT.MAC,
plus MON:VERSIO.MAC are compiled together to produce R:VERSIO.REL.
* For LN2070 SINGLE monitors, NAMAM0.MAC is used.
* For 2060-MONBIG monitor, N70BIG.MAC is used.
* For 2060-MONMAX monitor, N70MAX.MAC is used.
* For T20-AN70 SINGLE monitors, NAMAN.MAC is used.
* For AN-MONBIG monitor, ANNBIG.MAC is used.
* For AN-MONMAX monitor, ANNMAX.MAC is used.
* For AN-MONDCN monitor, ANNDCN.MAC is used.
TOPS-20 Monitor Building Procedures and Information Page 8
2. The source file for the PSECT origins for this monitor, plus the
parameters source file for this monitor, plus MON:PARAMS.MAC, plus
MON:STG.MAC is compiled together to create R:STG.REL (LN2070) or
R:STGAN.REL (T20-AN70).
* For LN2070 SINGLE monitors, PARLM0.MAC+PARAM0.MAC is used.
* For 2060-MONBIG monitor, PARLBG.MAC+P70BIG.MAC is used.
* For 2060-MONMAX monitor, PARLMX.MAC+P70MAX.MAC is used.
* For T20-AN70 SINGLE monitors, PARARP.MAC+PARAN.MAC is used.
* For AN-MONBIG monitor, PARBIG.MAC+ANPBIG.MAC is used.
* For AN-MONMAX monitor, PARMAX.MAC+ANPMAX.MAC is used.
* For AN-MONDCN monitor, PARDCN.MAC+ANPDCN.MAC is used.
The PSECT origin file (the first file mentioned above) contains
the origins for the PSVAR, JSVAR, NPVAR, ERVAR, ENVAR, and EPVAR
PSECTs.
At this point, all of the REL files needed to build the monitor have
been created.
3. LINK is run to begin the loading process. The CCL file used to
set PSECT origins for this monitor is given to LINK first. This
file just contains switches to LINK to set PSECT origins and is
unique to each standard monitor.
* For LN2070 SINGLE monitors, LNKLM0.CCL is used.
* For 2060-MONBIG monitor, LNKLBG.CCL is used.
* For 2060-MONMAX monitor, LNKLMX.CCL is used.
* For T20-AN70 SINGLE monitors, LNKARP.CCL is used.
* For AN-MONBIG monitor, LNKBIG.CCL is used.
* For AN-MONMAX monitor, LNKMAX.CCL is used.
* For AN-MONDCN monitor, LNKDCN.CCL is used.
The CCL file contains the PSECT origins for the RSCOD, INCOD,
RSDAT, PPVAR, RSVAR, NRVAR, NRCOD, BGSTR, BGPTR, SYPSX, ERCOD,
XRCOD, XNCOD, ENCOD, and POSTCD PSECTs.
4. LNKINI.CCL (LN2070) or LNKANI.CCL (T20-AN70) is given to LINK
next. This file also sets various LINK switches, then loads
SYS:MONSYM.REL, LDINIT.REL, VERSIO.REL, STG.REL or STGAN.REL,
KDDT.REL, and MDDT.REL.
5. The REL library is searched to extract all code that is needed to
build the monitor based on the selected software and hardware
configuration.
6. After LINK has created the monitor image (MON.EXE or AMON.EXE), it
is started at location 142 which starts up DDT. The built in DDT
breakpoints for BUGHLT and BUGCHK are set.
7. The monitor is then started in the POSTLD module. POSTLD first
rearranges certain monitor address spaces. It then prints out the
start, end, and length for each monitor PSECT. If there are PSECT
overlaps these are detected by POSTLD, which will result in a
error message. POSTLD will write a potential new set of PSECT
origins to LNKNEW.CCL and PARNEW.MAC. These will be used if PSECT
TOPS-20 Monitor Building Procedures and Information Page 9
overflows were detected by POSTLD. POSTLD then saves the ready to
run monitor as MONITR.EXE (LN2070) or AMONITR.EXE (T20-AN70).
If POSTLD did not detect PSECT overflows, the image that was just
saved is the monitor to use. If POSTLD did detect an overflow, a
second pass at the monitor build will be attempted, as described in
the following steps.
8. PARNEW.MAC (containing revised PSECT origins), plus the parameters
for this monitor, plus MON:PARAMS.MAC, plus MON:STG.MAC are
compiled together to create R:STG.REL (LN2070) or R:STGAN.REL
(T20-AN70).
9. LINK is run again and LNKNEW.CCL given to LINK to set the revised
PSECT origins. The rest of the monitor LINK switches and commands
are used to produce another base monitor image just as it was for
the previous build.
10. The image is started in DDT, and the breakpoints are set for
BUGHLT and BUGCHK are set, and POSTLD is started again. Because
PARNEW.MAC and LNKNEW.CCL were used, there should be no PSECT
overflows this time.
11. If the monitor just built did not have any PSECT overflows, the
LINK CCL file for PSECT origins for this monitor is replaced by
LNKNEW.CCL, and the source MAC file for PSECT origins for this
monitor is replaced by PARNEW.MAC. The old CCL and MAC files are
kept around as filename.OLD just in case the work done in pass 2
was in error.
Because POSTLD writes revised PSECT origins, and the CTL files
handle PSECT overflows automatically, the monitor building process
normally proceeds without intervention.
During the loading of the REL library a number of messages are
displayed. Messages from LINK of the form "%LNKFTH Fullword value
XXXXXX being truncated to halfword" are to be expected. Messages from
LINK of the form "%LNKPOP Psect XXXXXX overlapping psect YYYYYY at
address OOOOOO" can cause problems if there are a large number of
these errors or the PSECTs overlap severely, because LINK will loop
while loading the monitor.
If there are a number of PSECT overflows, or one or more PSECT
overflows are severe, LINK will loop while loading the monitor. This
will usually result in the batch job terminating after it exhausts its
runtime. In this case POSTLD does not have the opportunity to revise
the PSECTs, and manual intervention is required.
One of the switches given to LINK is a /COUNTERS switch. This
switch displays the PSECT relocation counters just before LINK
attempts to resolve global symbols (which is when LINK may loop).
By examining the LOG file the PSECT overflows can be seen by
looking at the output of the /COUNTERS switch. Normally the PSECT
overflows are caused by massive code additions OR by changing monitor
TOPS-20 Monitor Building Procedures and Information Page 10
parameters (such as drastic changes in number of jobs). To repair the
PSECT overflows, edit the CCL file used to load the monitor and change
the PSECT origins just enough so that they no longer overlap. Then
resubmit the monitor build. If changing one PSECT causes another to
overflow and this overflow is not severe, LINK will not loop and
POSTLD will be able to write the correct PSECT origins.
TOPS-20 Monitor Building Procedures and Information Page 11
3.0 Monitor Configuration Parameters
This section is intended for anyone needing to build a monitor
configuration different from the standard configurations. It requires
some familiarity with the operation of the system and utility
programs, and some knowledge of the structure of the monitor.
Specifically:
1. Everything required in Section 2.
2. How to use a text editor.
3. How to read assembly language.
4. The meaning of common TOPS-20 monitor terms (e.g. "jobs", "forks",
"PTY").
The monitor configuration is determined by a single parameter
file PARAM0.MAC (for non-TCP/IP monitors) or PARAN.MAC (for TCP/IP
monitors). This file is the only configuration-dependent file
required for a monitor build. To configure a monitor, you will use
the text editor to produce this parameter file.
PARAM0.MAC (or PARAN.MAC) should contain only those parameters
that are different from the standard values listed in PARAMS.MAC.
This section describes the meaning of each parameter and its effect on
the monitor configuration.
You should read each description, determine the proper value for
you configuration, and note this value on a listing of the parameter
file. You can then edit the parameter file to include these values.
When the new parameter file has been produced, you may follow the
normal monitor build procedure to build a single monitor. For
non-TCP/IP monitors submit LN2070 /TAG:SINGLE /TIME:60, and for TCP/IP
monitors submit T20-AN70 /TAG:SINGLE /TIME:60.
3.1 Parameters Controlling Software Resources
The parameters in this catagory cause the monitor to be built for
different numbers of software resources. Because the monitor's
section 0 address space is limited, increasing some parameters may
cause the section 0 space to overflow. For example, increasing the
number of jobs may require that the number of forks be reduced.
1. NJOBS
The number of jobs, defaults to 100. This parameter determines
the size of the jobs tables and hence the maximum number of jobs
which can exist at any one time. This includes interactive and
batch jobs and those jobs with run under PTYCON. There are 34
resident words of monitor space which are directly dependent on
this parameter; in addition, the number of forks (described
TOPS-20 Monitor Building Procedures and Information Page 12
below) is usually determined by the number of jobs, and the normal
ratio is 4 forks/job. Hence (unless you change the fork/job
ratio), the number of resident words required for each job is
(4*18)+10 words resident and 27 words swappable memory.
2. NFKS
The number of forks. This parameter determines the size of the
scheduler fork tables and hence the maximum number of forks which
can exist at any one time. This parameter is normally set to
3*NJOBS thus allowing an average of about 3 forks/job. If your
system is known to have an average distinctly above or below this,
this ratio may be changed. The resident memory requirements are
18*NFKS.
3. MAXFKS
Maximum fork size. This parameter specifies the maximum size to
which the working set of any fork (process) can grow. This
parameter defaults to 0. If this value is set to 0, the monitor
will limit working sets to a size 32 less than the number of
available pages. CAUTION: If this number is set too low, the
system will thrash.
4. SSPT
The size of the system pages table, defaults to 2560. This 2-word
table holds information about every open file and every fork. Its
minimum reasonable value is SSPT = 500 + NJOBS = 3*NFKS. It is
also used for holding information about shared file pages if there
is sufficient space. This allows a shared file page to be
referenced without its owing index block also being brought into
core. Hence it is probably most efficient to set SSPT to the
value shown above plus the average number of shared pages in use
in your system. The resident core requirements are: 2*SSPT.
5. NOFN
The number of OFN entries in the SPT. There is OFN (Open File
Number) assigned for each disk file open on the system. If the
system appears to run out of OFNs, NOFN may be increased. Each
OFN requires 9 resident words.
6. MAXCOR
The maximum number of physical pages. This parameter determines
the size of the five core status tables. It should be set to at
least the maximum amount of memory on your system (in pages).
Since all CSTs except CST5 have been moved out of section 0/1
space, the resident core requirements for this parameter are just
MAXCOR words.
7. NDST
The size of the drum status table. This table has one entry for
each page of swapping storage. The swapping area is used for all
TOPS-20 Monitor Building Procedures and Information Page 13
active pages whether shared or private. If the swapping area
becomes full, the monitor will move shared pages back to their
home address, but it cannot move private pages. Hence, this
parameter should be set to at least the maximum number of private
pages expected to be in use at one time. Note that at least this
much swapping space must have been allocated on the boot structure
(BS:). Also, since TOPS-20 V5.0, the DST is located in TABSEC and
therefore modifying its size has no effect on TOPS-20's section
0/1 address space.
3.2 Parameters Controlling System Defaults
Many of the parameters listed below can be overridden by users.
These parameters control defaults set by the monitor.
1. TMZONE
The time zone. This parameter specifies the local time zone in
which the system is being operated. The monitor standard time and
date format (see JSYS manual) is GMT. Hence, this parameter gives
the number of hours by which local time lags GMT. This value is
assembled into TIMZON and may be changed at system startup in
7-CONFIG.CMD. For the USA, EST = 5, CST = 6, MST = 7, PST = 8.
Daylight saving time is handled automatically; this parameter
should be set based on the standard local time.
2. IPTIMF
This parameter controls the inclusion of page trap overhead time
in process run times. A value of 1 causes page trap time to be
included; a value of 0 causes page trap time to be excluded.
"Page Trap Time" is the CPU time spent handling page traps for a
process. This time typically increases under headier system loads
because pages will be swapped out and must be faulted back into
memory more often. This is the major item which causes
variability in reported process and job runtimes under different
load conditions.
In monitors prior to release 3, this time was always included in
reported runtimes. For compatibility with previous releases, the
default is to include the page trap time. Installations wishing
to minimize the variability of reported runtimes may change this
value to 0. Such installations should be aware, however, that
this will generally result in some reduction of system total
chargable time, since the overhead which was being charged in
earlier monitors will be excluded.
3. SYSSCF
This parameter is the total free disk space limit below which no
OPENF's in write mode will be allowed, and defaults to 500 pages.
TOPS-20 Monitor Building Procedures and Information Page 14
4. IEDDTF
EDDT retention flag. This parameter is set to 1 if EDDT is to be
retained after monitor startup, 0 otherwise. This value is
assembled into EDDTF and may be changed at startup. EDDT takes
about 16K? of resident core.
5. NTRFE
This parameter specifies the number of disk cylinders that are set
aside for the front-end-file-system, which defaults to 10.
6. LOGTTY
Designator for logging information. This is the terminal on which
all login, logout, and account change commands are recorded. It
is not necessary to print this information on a terminal since it
is also recorded in the USAGE file. Hence, this parameter is
normally set to .NULIO.
7. DGOFKN
If a job tries to create a fork, and the number of forks in the
job (including the new one) is greater than the value of DGOFKN,
then the monitor calls the access-control facility to determine if
the job is permitted to create the fork. The default is 5.
8. FFFSZE
This is the size (in words) of the resident monitor patch area,
FFF. It defaults to 400 (octal) words.
9. COFMIN
When a job is detached because of carrier loss (or any other
communications interruption), the job remains detached for COFMIN
minutes before it is logged out. The default is 5 minutes. This
value may also be easily changed with the "ENABLE
DETACH-CARRIER-OFF n" command in 7-CONFIG.CMD.
10. SWDST
The default number of pages to reserve for swapping space on an
areas of a structure. If no value is declared for SWDST, it is
set to NDST.
11. .STDFP
The default file protection given to each new file in a directory
unless otherwise specified. It defaults to 777700.
12. .STDDP
The default directory protection of each new directory unless
specifically set to something else, defaults to 777700.
TOPS-20 Monitor Building Procedures and Information Page 15
13. .STDBS
The default number of versions of each new file to keep, defaults
to 1.
14. .STDMX
The default permanent and working disk storage, defaults to 250
pages.
15. .STDSD
Standard subdirectory quota, defaults to zero.
16. .STDNE
Standard on-line expiration for migration of files, defaults to 60
days.
17. .STDFE
Standard off-line expiration for migrated files on magnetic tape,
defautls to 180 days.
3.3 Parameters for Hardware Support
The next group of parameters refers to the configuration of
peripheral devices. These parameters take a number which is the
maximum number of units of a particular device. Each device has a
parameter related to the device name, i.e., for device "xxx", there is
a parameter "xxxN". Other symbols in the monitor are constructed by
concatenating the device name with a specific prefix or postfix.
1. NDHL, NDLL
The number of terminals on the RSX20F front end console. This
parameter determines the maximum number of physical terminal lines
including the CTY. NDHL is the number of DH11 lines on the
front-end, defaults to 128 (which is the maximum). This number is
normally 16 times the number of DH11s in the front-end. NDLL is
the number of DL lines on the front-end, including the CTY, and is
defaulted to 5 (one for the CTY, one for the KLINIK, one for each
of three possible DN20s). The resident storage required per
terminal line is a function of some ratios described below. For
this parameter, the number of resident words required is:
5*(NDHL+NDLL+1)
2. NTTPTY
The number of pseudo-terminals, defaulted to 30. This parameter
determines the number of PTYs available. You will need 1 for
PTYCON plus 1 for each PTYCON subjob being run, plus 1 for each
simultaneous batch job being run. Additional PTYs may be
TOPS-20 Monitor Building Procedures and Information Page 16
allocated for user use of PTYCON. The resident storage
requirement for a PTY is exactly the same as for a physical
terminal: 5*NTTPTY
3. NTTNVT
The number of Network Virtual Terminals (TELNET protocol
terminals), defaults to zero. These devices are present only on
installations using an TCP/IP monitor. The resident storage
requirement for a NVT is exactly the same as for a physical
terminal: 5*NTTNVT.
4. NTTMCB
The number of DECnet NVTs (Network Virtual Terminals), defaults to
20. If you do not have a DECnet-20 installation, this value may
be set to zero. The NVT protocol has been superceded by the CTERM
protocol for Phase IV DECnet systems. NVT terminals require
storage like any other terminal device, and their resident core
requirements are: 5*NTTMCB.
5. NTTCTH
The number of CTERM host terminals, defaults to 10. If you do not
use DECnet-20 or do not use DECnet-20 for terminal connections,
this value may be set to zero. CTERM terminals require storage
like any other terminal device, and their resident core
requirements are: 5*NTTCTH.
6. NTTLAH
The number of LAT host terminals, defaults to 50. If you do not
use LAT, or do not have an NIA20 Ethernet interface on your
system, this value may be set to zero. LAT terminals require
storage like any other terminal device, and their resident core
requirements are: 5*NTTLAH.
7. ACTLNS
This is the number of active terminal lines, including TTY and PTY
lines, and is defaulted to NJOBS. The number of resident words
is: 32*ACTLNS?
In addition, 22 words of resident storage is required for each
active line. This latter storage changes dynamically as any line
becomes active or inactive.
8. NETN
Arpanet (TCP/IP) service if set to 1. This symbol specifies that
the monitor has support for TCP/IP software and hardware. This
parameter is set to 0 in non TCP/IP monitors to remove TCP/IP code
from the monitor.
TOPS-20 Monitor Building Procedures and Information Page 17
9. ANXN
Support for the TCP/IP over AN20 Arpanet 1822 interface. If zero
there is no AN20; if one there is an AN20. (TCP/IP monitors
only.)
10. IPNIN
Support for TCP/IP over the NIA20. If zero no support for TCP/IP
over the NIA20; if one support TCP/IP over the NIA20. (TCP/IP
monitors only.)
11. DCN
DECnet-20 service if set to 1. This specifies that the monitor
has support for DECnet-20 software and hardware. Setting DCN to 0
removes DECnet code from the monitor.
12. FEN
Front End Device service. This parameter defines the number of FE
devices present, and defaults to 1. The FE devices are pseudo
devices used for general transfer of data to and from the front
end file system. The FE program is the only use of the FE:
device. A maximum of 4 is supported. Each FE device requires 7
resident words.
13. MTAN
Magtape device service. This parameter is the number of magtape
units present, defaulted to 16. A maximum of 16 is presently
supported. Each magtape device requires 98 resident words and 38
nonresident words.
14. DTEN
DTE20 service. This parameter denotes the number of DTE's
connected to the KL10 processor including the console 11/40.
NOTE: If this prarmeter is changed, the source module DTESRV.MAC
must be rebuilt; therefore only source sites can change DTEN.
15. LPTN
Lineprinter service (PLPTn:), which defaults to 2. A maximum of 2
is presently supported. Each physical printer takes 18 resident
words and 540 nonresident words.
16. CDRN
Card Reader service (PCDRn:), defaults to 1. This specifies the
number of card readers on the console front end. A maximum of 1
is supported. The spooled card reader device always exists. Each
card reader requires 7 resident words and 512 nonresident words.
TOPS-20 Monitor Building Procedures and Information Page 18
17. CDPN
Spooled card punch, defaults to 1. If nonzero, spooled card punch
is allowed.
18. PCDPN
Physical card punch service, defaults to 1. A maximum of 1 is
supported. Each physical card punch requres 72 resident words.
19. SPLTN
Spooled plotter, defaults to 0. If nonzero, spooled plotting is
allowed.
20. PLTN
Plotter service (PPLTn:), defaults to 0. A maximum of 1 is
supported. Each plotter requires 521 words of resident storage.
21. SPTPN
Spooled paper tape punch, defaults to 0. If nonzero, spooled
paper tape punch is allowed.
22. PTPN
Paper tape punch (PPTPn:), defaults to 0. A maximum of 1 is
supported. Each paper tape punch requires 73 words of resident
storage.
4.0 Installation-Specific Terminal Definitions
Installations wishing to define their own terminal types may use
terminal type codes 4 through 7. It is not possible to define
corresponding terminal type names. Note that DIGITAL only supports
those terminals detailed in the TOPS-20 Software Product Description.
Setting installation specific terminal types requires that the
source module STG.MAC be edited. For each terminal type the following
information must be known:
1. Terminal has mechanical form feed
2. Terminal has mechanical tabs
3. Terminal has lowercase keyboard input
4. Padding after a carriage return
5. Padding after a line feed
TOPS-20 Monitor Building Procedures and Information Page 19
6. Padding after a horizontal tab
7. Padding after a form feed
8. Terminal display length and width
9. Terminal automatically enables XON and XOFF processing
10. Character strings to be sent to the terminal to effect cursor
These characteristics are described by tables which can be found in
the source code module STG.MAC. Items 1 through 7 are declared in
table TTYPE0. Item 8 item is in table TTYPE1. Also, the cursor
positioning declarations are in tables for each terminal type, pointed
to by entries in table TTYPE1. See table VT100T for an example of the
table of cursor positioning commands for a specific terminal.
[End of MONITOR-BUILDING.MEM]