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Trailing-Edge - PDP-10 Archives - tops10and20_integ_tools_v9_3-aug-86 - tools/casestdy/case3ici.rno
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  Trevor Moore                                           Chris Bond
  John Morris                                           Jacky Quinn

  ICI Petrochemicals Division           Large Systems Skills Centre
  Wilton                                                  DEC Leeds
  Cleveland                                               Yorkshire
  ENGLAND                                                   ENGLAND











.EL
.PG
.LIT















                               
                               ABSTRACT

       +--------------------------------------------------------+
       !                                                        !
       !   This paper  describes  the  conversion of a  large   !
       !   production data base  and program from a  DEC 2060   !
       !   to a VAX 780.  The data base is a DBMS20 data base   !
       !   and the program is written in  COBOL using TRAFFIC   !
       !   for its screen handling.     The converted product   !
       !   uses DBMS32, COBOL and TDMS.                         !
       !                                                        !
       !   The paper concludes that in this instance the con-   !
       !   version was achieved with relative ease.  The pen-   !
       !   ultimate section makes some suggestions about  how   !
       !   future integration requirements might be met while   !
       !   the final section draws some general conclusions.    !
       !                                                        !
       +--------------------------------------------------------+



.EL
.PG
.NUMBER 1
.BL 12
.HL 1 INTRODUCTION

This PAPER describes the process of taking a large program suite
written to run under TOPS20 on a DEC2060 and converting it to run
under VMS on a VAX780.  Because
the program uses DBMS20 this conversion also involved the transfer of the whole
database structure and most of the data for the DEC20 to the VAX.  Because it
describes the conversion of one specific program to do a specific job this note
should not necessarily
be taken as describing the process by which other conversion
exercises are tackled; rather it is a case study and as such will provide the
reader with guidelines should he wish to tackle a similar exercise.  The main
body of the note describes the conversion in general terms; specific and more
technical examples refered to in the main body of the text
are included as appendices.

The reader is assumed to have a working knowledge of TOPS20,
COBOL-20, DBMS20 and TRAFFIC20 but is not assumed to have more
than a passing acquaintance with the VAX equivalents.

.HL 1 OBJECTIVES OF EXERCISE


The objective of the exercise was to do a straight conversion from the one
system to the other.  This means that no redesign was to be done (in fact some
was done for reasons which will be explained) and that existing bugs on the 20
version would not be deliberately fixed (indeed in porting the software we
did actually port the bugs as well!).  One corollary of this is that no attempt
has been made to tune the converted product; the database design for example
more or less reflects 
the strucure on the DEC20.  

.HL 1 BACKGROUND


ICI is one of the largest chemical companies in the world.  Petrochemicals and
Plastics Division is one of its divisions; the Division employs 15000 people.
The Division's major manufacturing base is at
Wilton in Cleveland, England and comprises a number of very capital intensive
continuous process chemical plants.  Chemical plants cost a lot to run and in
order to improve efficiency, productivity, energy consumption etc
operating parameters are
continually monitored.  Critical parameters are measured
in real time by a wide variety of machines (mainly DEC) including 2 VAX780s.
The Production Management System (PMS) is designed to store and allow the rapid
retrieval of data associated with the operation of the chemical plants.  The
system runs on a 2060 and collects its data from the real time machines, from
manual input and from regular calculations.  Data can be retrieved either
directly from the data base or can be transferred - using Robins (VT180s) and a
COBOL-callable KERMIT - to floppy disks and examined using CP/M software.

The program suite 
which was converted is called PLNTIN and is the major input 
facility
in PMS.  It is also the one which has absorbed the most effort both
in design and performance terms.  Appendix A describes in outline the function
of the program and the design of the data base.  Appendix B describes the
structure of the program suite and its component modules
and describes the
functions of the major modules.


.HL 1 ORIGINS OF EXERCISE


In mid-1983 ICI 
began to evaluate its options for a continuing computing strategy.  
ICI recognised that there 
were three distinct types of production
system:

.LM +5
.RM -5
.LIST
.LE;Established systems
.BREAK
.BL
ICI has many systems which are in
maintenance mode running on 2060's.  
These systems can satisfactorily remain where they are
since hardware and software support for the KL is to continue.
.LE;New systems
.BREAK
.BL
ICI felt that new systems with a long life expectancy
could not reasonably be put on a machine whose
future was obviously finite.  They would be designed and implemented on
other hardware - possibly the VAX.
.LE;Developing systems
.BREAK
.BL
These systems were the problem.  Clearly there was little
point in continuing to develop long term a system which was 40 man years
into a 100 man year development cycle.
.END LIST
.RM +5
.LM -5

It was in addressing the developing systems that the conversion feasibility
study emerged.  One of the problems that ICI was worried about was the amount
of retraining which might be necessary both for programmers and analysts
and also - most importantly - for users.  ICI wanted ideally to have a system
on the VAX which was identical to the system on the 20 in every respect.
In fact the conversion
came very close to achieving that ideal and without too much difficulty.


.HL 1 EARLY CONSIDERATIONS


Early on in the process - before Digital was involved - ICI identified 6 areas
of concern

.LM +5
.RM -5
.LIST
.LE;Languages
.BREAK
.BL
PLNTIN is written in COBOL Version 12b. Since ANSI standards for COBOL are
fairly rigidly enforced few if any compatibility problems were envisaged in
this area. (COBOL Version 13 will provide the programming constructs - such
as in-line PERFORMS, END-IF etc - that are missing from Version 12b but
present in VAX COBOL.)
.LE;Databases and Files
.BREAK
.BL
ICI quickly discovered that although DBMS32 was a
CODASYL database it was different from DBMS20.  At the programmer level
some retraining would be necessary.  
It was not felt that sequential and relative files would
present a problem.  PMS does not use ISAM files.
.LE;Screens
.BREAK
.BL
This was rapidly identified as being the potential trouble spot.
Screen handling uses TRAFFIC Version 4.0. This is different and more
powerful in some important respects (notably data input validation) than
TDMS (and, in fact, than TRAFFIC version 2.0).
The decision was made to use TDMS as this follows Digital's 
mainstream screen product development direction.
It might have been easier to
use FMS but in fact TDMS can be made to emulate TRAFFIC and FMS.
.LE;IPCF - Interprocess Communication Facility (IP20)
.BREAK
.BL
Much communication between processes is done by sharing memory and due
to virtual address space restrictions on the 2060 (we only use section 0
of course) considerable use is made of IPRUNI (ie CFORK%, SFRKV% 
and WFORK%).
It was quickly demonstrated that VMS mailboxes handle this aspect nicely and
that subprocesses can be spawned on the VAX.
.LE
Assembler
.BREAK
.BL
ICI has many assembler routines written in MACRO36 but
fortunately these are all small. In general these routines just
implement a couple of JSYSes or
activate the interrupt system.  As it happened all these could be handled
by VMS system services called directly from COBOL.  In fact since the
conversion ICI has worked on converting its only large MACRO36 program to
MACRO32 and 'C' in parallel.  While the conversion to 'C' is relatively
straightforward (although actually a rewrite) the conversion to MACRO32 is
not difficult; for instance JSYS calls 
can be replaced by subroutines, SETZM by CLRL and so on.
.LE;Operating System
.BREAK
.BL
ICI felt there are some mainly operational and 
administrative
shortcomings within VMS compared with TOPS20.
For example queuing of mount requests, archiving and
retrieval are things which one might expect to find in a large 
time-sharing operating system. However, consideration is being
given to the inclusion of these and other facilities in future versions
of VMS.
.END LIST
.LM -5
.RM +5

These considerations - together with the formation of Digital's UK Large
Systems Skills Centre at Leeds (70 miles away from ICI Wilton) - led rapidly to
a team being set up to do the conversion.

.HL 1 METHOD OF APPROACH

The method of approach was to tackle the conversion in two separate but
overlapping stages.

.BL
.LIT
Stage I  - To convert and implement the data-base structure on the VAX
           and to transfer data out of the 20 data base and into the 
           VAX data base.

Stage II - To convert, compile and test the programs on the VAX.
.EL

.HL 1CONVERSION OF THE DATA BASE

As it turned out conversion of the data base was
accomplished with relative ease. There are several
conceptual differences between DBMS32 and DBMS20. Specific examples include the
different implementation of CALC records. On the VAX every CALC record must be
the member of a set whose owner is the SYSTEM record. The VAX maintains a
system record on every page of the physical data base. In this sense the SYSTEM
record behaves like a CALC CHAIN HEADER in DBMS20.
Another example is that there is no
concept of a REALM in DBMS20. In designing the data base for the 2060 ICI had
taken full advantage of the physical record placement clauses allowable in the
DDL description. These cannot be completely mirrored in DBMS32 although
shadow clustering allows some physical design flexibility. These
differences (and this is not an exhaustive list) had to be learnt by the ICI
people.

The next stage was to redesign the data base in DBMS32 terms. This was done
with DEC Valbonne confirming the ICI suggestions. The result was a converted data
base schema description which at this stage was in source form on the 2060. (It
is worth saying that in the early stages of the exercise all source was written
on the 2060 and compiled on the VAX!!) The schema was moved to the VAX by tape
transfer. Initially CHANGE was used but this resulted in difficulties. We
actually ended up using the method recommended in the TOPS20 manuals (see
Tape Processing Manual ref AA-H180A-TM, Chapter 6).
Appendices
C and D describe this method in more detail than the manual.

The standard PMS unload program was modified to allow data to be unloaded in
ASCII form eg COMP fields were unloaded as DISPLAY and a VAX reload program was
written to load the data into the VAX. Again data was transfered by tape. As it
happened the loading of the data base on the VAX worked first time! The only
difficulty we did have was that the VAX is more stringent in its data
conversion, typing and checking than the 2060. For example it would get upset by embedded
nulls in packed decimal fields.

Writing the unload programs brought out the differences in DML between DBMS20
and DBMS32. These are few; the main ones are the different 
way in which a transaction
is delimited and the
way in which currency is handled. Record currency was the main
area of difficulty in converting PLNTIN itself. The action of KEEPLISTs in
DBMS32 does not mirror exactly the action and effect of the
MOVE STATUS DML command in DBMS20.
The VAX COBOL 
COMMIT statement releases currency under version 2. (Under version 3 COMMIT
RETAINING [currency]
is implemented but this may affect lock status.) Appendix E lists
one or two of these examples in a comparitive way.

At this stage the importance of DBQ became apparent. Although we had no
programs we could still
look at - and modify - the data in the data base. There is no
supported utility equivalent to DBQ
on the 2060. There is a utility called XDML which
does what DBQ does which ought to be released as DBQ20. This, of course,
supports recognition - including recognition on data names!! This would
have been
useful in this exercise as one record name - OPERATIONAL-BDY-RECORD - is unique
in the first two characters!! We now understand that XDML is to be bundled with
version 6.1 of DBMS20.

The exercise to this stage was
very much a learning exercise. It was also one off; once the data base
conversion is done and the lessons learned there is no need to go
through it again.

.HL 1CONVERSION OF THE PROGRAMS

We split the various modules which comprise PLNTIN up into 3 categories as
follows:
.LIST
.LE;modules which do not use DBMS and do no screen i/o
.LE;modules which do use DBMS but do no screen i/o
.LE;modules which do use DBMS and do screen i/o
.END LIST

The first step we took to convert COBOL code was to run a raw COBOL20 program
of category 1 above (ie no DML or screen calls)
through the VAX COBOL compiler. This pointed up basic syntactic differences
such as VAX COBOL's dislike of ID for IDENTIFICATION. In addition to the
information we got from this we had gathered much information from the data
base conversion. At about this time a Digital integration
document was issued which listed differences between the two COBOLs.
A selection of the differences we found is contained in Appendix F.

For the next stage we set as a target the achievement of a
clean compilation of everything. This we achieved by the rote replacement of
syntactic differences the one for the other. This is probably not the way one
would do a conversion in practice - more thought is advisable. Calls to
assembler routines - like TRAFFIC calls - were commented out. We very quickly
ended up with a set of cleanly compilable programs most of which were
non-functional because we had done nothing about screen i-o.

One point worth making here is that we had been a little worried about the
effect of the different word size on the two machines. In this particular
exercise we had two reasons for concern (neither of which were justified as it
happened). First much use had been made of the fact that PIC 9(10) COMP fits
into 36 bits. So on the 2060 many numeric codes were based on, say, the
concatenation of two 5 digit numbers. We had to convert to DISPLAY to get
round this (you can only get PIC 9(9) COMP into a 32-bit word!) which uses more
space on disk (and insignificantly in memory) but which doesn't cause any
technical difficulty. Since data type conversion is all microcoded on the VAX
there may not be any significant performance penalty.
The second area of concern was that PLNTIN actually set
the bits in a word and used the bits as flags. To set bit 0 the program would
add 1 to a variable to set bit 4 it would add 16 and so on. In fact this rather
primitive idea converted as it stood to the VAX.

On reflection,a number of lessons were learned from this process.
The quality of the 
code being converted was variable and we found that well structured code was
easier to convert than poorly structured code.
Poorly written and poorly structured code is more difficult 
to convert than good code. This is particularly true
in the screen conversion area where some restructuring may be 
necessary.

The act of conversion does, however,
present an opportunity to look at program structure and content.
When converting it is important to examine the code.
This is partly to gain some insight into the way 
the original programmer worked and thought but also to assess any 
potential difficulty. Code with neither screen or data base calls 
presents little or no difficulty. Code with only DML - and no 
screen calls - becomes straightforward once a standard error 
handling procedure is decided.

It is possible to break the screen conversion procedure down. When 
examining the nature of the screens it is important to consider:
.LM +5
.LIST
.LE;how much input and output of fields is required
.LE;whether the forms access more than one record
.LE;what use is made of special function keys
.LE;how much and what sort of help is presently given at run-time
.END LIST
.LM -5

.HL 1 SCREEN CONVERSION

As remarked above we had anticpated that the screens would cause us the most
trouble. They did; but not as much as we had feared.

PLNTIN uses TRAFFIC20 (the new version 4.0).
Unfortunately it does no TRAFFIC
section reads but gets all its data by reading a field at a time. On the face
of it replacing a section read in TRAFFIC by a request in TDMS would have
worked. But the way PLNTIN is written it gets information
a field at a time. So for
example consider this screen:

.BL
.TEST PAGE 15
.LIT

                +---------------------------------------+
                !                                       !
                !             SAMPLE SCREEN             !
                !                                       !
                !            Enter name: ______         !
                !             Enter age: ___            !
                !  Enter marital status: _              !
                !                                       !
                !                    OK? _              !
                !                                       !
                +---------------------------------------+

.EL
.BL

TRAFFIC would enable you to set this up as a section and read it in one fell
swoop (go). TDMS works like that and such a use of TRAFFIC might have made the
conversion easier. Unfortunately PLNTIN would read the screen like this:

.BL
.TEST PAGE 20
.LIT

                          Paint screen

        +->  not  +-----> Read name
        !    OK   +-----  Validate name   ---------+
        !                                          !
        !    not  +-----> Read age                 !
   try  !    OK   +-----  Validate age    ---------+
        !                                          !     allow panic
  again !    not  +-----> Read status              !---->exit on
        !    OK   +-----  Validate status ---------+     <UPARROW>
        !                                          !
        !    not  +-----> Read OK                  !
        !    OK   +-----  Validate OK     ---------+
        !
        +---------------  Act on OK
                              !
                              !
                              V
                          continue

.EL
.BL

where the read statements were not contiguous in the soure file. TDMS would
want to say:

.TEST PAGE 6
.LIT

              not  +----->  Do request
              OK   +-----   Validate data

.EL

There are a number of problems here. TRAFFIC version 4 allows the inclusion of
field validation (vet) routines. 
These are like the User Action Routines available in FMS
and allow validation of the input to a field at the time it is input.
So, for example, as soon as the name is read the data base can be checked for
existence and the field reread as necessary. 
ICI feel that TDMS would be a much stronger product
if it had the ability to perform user-defined field-level validation
checks.
Since TRAFFIC validates field by field, the user gets feedback (when
necessary) immediately he has completed a field.
With a TDMS request he must type in the whole screen
(request). This can mean that he types a lot of data in that he would not have
typed in had he had a response earlier.

This would not have
met our criterion of having the converted product look and feel
like the original. The obvious way round this is to generate a request for each
field read. Since requests are stored in a run-time library we thought that
there would be a significant performance penalty in doing this. As it happens
TDMS has the facility of acting on data items that it calls 'control fields'.
These enable a single request to do different things according to how the
control field is set at the outset. We mapped the TRAFFIC section numbers onto
a control field which caused the TDMS request to mimic the action of TRAFFIC.
Appendix H describes in detail how this is done and gives coding examples.

This method, although an elegant solution to the problem of a rapid
conversion, is still
not as runtime efficient as using TDMS as it was designed to be used.
This solution was applied to
the INPUTR module which is where the data is actually input. The PLNTIN module
was tackled by using TDMS as it was designed to be used. This actually resulted
in some fairly difficult restructuring but the result was screens which
painted more smoothly. Appendix G describes the different approaches in more
detail.

.HL 1TESTING THE PROGRAMS

Testing the programs fell into two stages: testing the screen flow and testing
the data updates.

Screen flow testing (ie testing the superficial program flow logic)
was done as the screens and requests were developed. This
proved to be relatively time consuming if not particularly difficult. The major
difficulty was in understanding the original code rather than in implementing
it. An example of the sort of problem at this stage was 
where a field was not rewritten in
reverse video when it had failed validation. 

We had to give some thought to the use of function keys. TRAFFIC allows the
programmer to pick up, for example, the arrow keys. TDMS does not recognise
arrow keys but uses the GOLD (PF1) key followed by another key.
This is the only significant difference
between the converted program and the original product .
As an example, GOLD-X on the VAX replaces UP-ARROW on the 2060 as the
program abort key. Appendix I describes the use of special 
function keys in more detail.

Testing that data base updates have been properly processed
is most important. By and large because this involved no restructuring
of code the conversion worked first time. It turned out that the one or two
bugs we found here were present on the 2060 version. But here again DBQ proved
an invaluable aid.

.HL 1 ASSEMBLER ROUTINES

All assembler routines were replaced by VMS System Services which means that
the VAX version uses no assembly level code. In particular a MACRO20 routine to
submit a job to the batch queue is replaced by a call to LIB$SPAWN to
execute a DCL command which submits the job. Appendix J
gives one or two examples.

.HL 1REFLECTIONS

At the end of the conversion exercise ICI were relieved to discover that it
had been less painful than they had anticipated. But there are a
number of comments one might make both in terms of establishing forward 
compatibility standards and in terms of tools
and utilities which might help the movement of data and programs
between the 20 and the VAX.

.LIST
.LE;VMS help is very good but it involves more keystrokes than
the 20. The in-line help facility ('?')was sorely missed.
.LE;TDMS would be stronger if user-defined, field-level could be set up. 
Form definition and modification
within TDMS is easier than within TRAFFIC.
.LE;VMS needs some convenient - and supported - way of handling standard
administrative and operating tasks such as tape and disk mounts, archiving,
retrieval etc.
.LE;XDML should be finished and released as DBQ20 as soon as
practicable.
.LE;In the light of the recent release of the DBMS32 load/unload facility, 
a useful tool would be an unload program on the 20 which 
would unload a DBMS20 data base into a format suitable for the 
VAX load program.
.LE;The ability to set breakpoints in the VAX COBOL source
debugger at lines is a significant aid to debugging. The same
feature in the 20 COBOL (and other) debuggers should be
incorporated.
.END LIST

.HL 1 CONCLUSIONS 

.LIST
.LE;The conversion used no assembler. This was important to ICI who
have no systems programmers as such.
.LE;It is possible to mimic TRAFFIC with TDMS.
.LE;The COBOL and DBMS software is sufficiently similar to make conversion
fairly straightforward.
.LE;An exercise like this gives an opportunity to 
ask anew questions about program
structure, design and content.
.LE;At the outset ICI thought they would not miss recognition - they did!
.LE;Quality of code is important. 
.LE;The second method of screen conversion was quicker
and more simple to implement. (See Appendix G.)
.LE;VMS is a good operating system to work with; it is just
different from TOPS20.
.LE;But the bottom line is that the conversion worked and it worked well.
.END LIST
.PG

.APP FUNCTION OF PMS DATA BASE AND PLNTIN PROGRAM

PMS is the Production Management System. It is used to monitor the performance
and operation of large chemical plants.
PLNTIN is possibly the most important of all the PMS programs. It is by using
this (or one of a number of flavours of the same thing) that PMS collects most
of its data. The other method of data collection is via a link to two PDP-11's
which get information from the data loggers and real-time VAX780's
on the plants.

At its heart the data structures of PMS are straightforward. It is only the
detail which clouds the issue. A chemical manufacturing complex (called a
WORKS) can be considered as a hierarchy of smaller components. These components
are known as OPERATIONAL BOUNDARIES (more usually OB's). The hierarchy of OB's
is refered to as the BOOB (Bill Of Operational Boundaries). An OB may be a
whole plant or it may be a single pump. But in general an OB is composed of a
number of smaller OB's. For example the NYLON OB has component OB's called
SOLVENTS and ACIDS (among others). At the bottom of the heap are some 'element'
OB's which have no components. These have no special significance.

The most important attribute an OB may possess is that it may have associated
with it a number (possibly zero) of MEASUREMENTS. A measurement is something
that can have associated with it a time series of VALUES or READINGS. The terms
'VALUE' and 'READING' are used interchangeably.

So for example the SOLVENTS OB has some measurements called, say, YIELD and
MAKE. Each of these measurements has a value for a series of times - there is a
January YIELD a February YIELD and so on.

Values can be of one of two types - CALCULATED or RAW. Raw data is read by
PLNTIN (or one of its flavours) or read 
from a data logger. Calculated values are
calculated by CALCNS.

The reading of certain raw data is the objective of PLNTIN. PLNTIN needs to
know for which measurements it needs to get values. There are LISTS of
measurements. Everyone who uses PMS is registered within the data base and some
users may have INPUT LISTS. An INPUT LIST is a set of measurements which is to
be read. An input list may be SCHEDULED - in which case there is a specific
time at which it must be read - or UNSCHEDULED - in which case there isn't.

In CODASYL network data base terms because one LIST can have many MEASUREMENTS
and one MEASUREMENT could be on many LISTS we need a link record. This record
is called a MEASUREMENT LIST ENTRY (MLE or more affectionately Emily) and
is central to the PMS data base. There are also OUTPUT LISTs but these are used
by other reporting programs. Figure 1 below describes a much simplified view of
the data base structure.

.TEST PAGE 30
.LIT



       +---------+        +---------+                   +---------+
       | OB      |------->| BOOB    |                   | USER    |
       |         |------->| LINK    |                   |         |
       +----+----+        +---------+                   +----+----+
            !                                                !
            !                                                !
       +----V----+                                      +----V----+
       | MEAS    |                                      | LIST    |
       |         |                                      |         |
       +--+---+--+                                      +----+----+
          !   !                                              !
          !   !                                              !
          !   !                                              !
          !   !                   +---------+                !
          !   +------------------>|  MLE    |<---------------+
          !                       |         |
          !                       +---------+
     +---------+
     | READING |
     |         |
     +---------+


                          Figure 1


.EL


Every reading (raw or calculated) must be validated before it is stored on the
data base. The results of the validation tests are stored in a coded fashion in
the READING-RECORD for the reading concerned. The tests which are to be carried
out on a reading are attributes of the measurement. So for each
measurement there is 
a collection of validation tests. These are stored as a set of records
owned by the measurement record. They are duplicated for reasons of
performance in the MLE record. Validation can be straightforward - such as 
maximum
and minimum
checks - or more complex - such as trend checking. The validation
program - VALTWO - is a fairly large and complex program which reflects the
nature of the validation that is carried out at data input time.

There is also a set of COMMENT-RECORDs (possibly empty) owned by a reading
record.

Finally there are a couple of records designed to keep track of amendments to
values. PLNTIN can be used to change values which have been entered (subject to
certain restrictions). If this is done the old value and any comments are
moved to two other records. 

.APP COMPONENTS OF PLNTIN



.HL 1 Outline of structure of PLNTIN

PLNTIN is composed of a number of modules as follows:
.BL
.LIT

          +---------+                                Response to TTY of
          |PLNTIN   |                                requestor (TERTLK)
          |         |                                        ^
          +----+----+   (call to SUBMIT)                     !
               !---------------------------------+           !
               !                                 !           !
          +----+----+                    +-------+--------+  !
          |INPUTR   |                    |Batch .CTL file |  !
          |         |                    |----------------|  !
          +----+----+                    | MMDATR         |  !
      _________!_________                |  (*.RCD,*.DAT) |  !
     !                   !               | EXPTER         |  !
     !                   !               |  (IPRUNI'd from|  !
+----+----+         +----+----+          |     MMDATR)    |  !
|ICOMNT   |         |PLTSHF   |          |                |  !
|         |         |         |          |                |  !
+---------+         +---------+          |        !       |--+
                                         |        !       |
                                         +--------!-------+
                                                  !
                                                  !
                                                  V
                                       SUBMIT to PRINT/DELETE
                                       *.HLD of errors to LPT







.EL
Each of the modules on the left side of this figure are composed of further
submodules. The conversion exercise did not tackle the ICOMNT and PLTSHF
modules. PLTSHF is essentially a callable version of another PMS program.
ICOMNT is used to put comments into the data base.
.HL 1 Outline of functions of major modules
.LM +5
.HL 2 PLNTIN
.LM +5
.LIST
.LE;determines which is the next list to be input. It may be passed
this by a top level menu program through the TOPS20 process
argument block. If the user has not specified the list at the
higher level then PLNTIN checks to see if the user has scheduled lists. If he
does then PLNTIN works out which is the next list that should be
input. The user may select a list whose values have already been
entered in which case PLNTIN goes into amend mode.
.LE;gets the information about the measurements associated with this
list and puts them in a big array. If the values are already
entered they are put in the array as well.
.LE;PLNTIN calls INPUTR passing the big array
.LE;when INPUTR is finished PLNTIN sets off the batch job to run
MMDATR and immediately returns control to the higher level
.END LIST
.LM -5
.HL 2 INPUTR
.LM +5
.LIST
.LE;displays the data received in the big array on the screen
.LE;reads data from each field validating input using VALTWO as
it is input. Also allows the user to get more validation
information and to run PLTSHF (qv)
.LE;allows the user to input comments associated with any number
of readings (call to ICOMNT (qv))
.LE;reading values are written to a *.DAT file which is read by
MMDATR (qv) to update the data base
.LE;returns control to PLNTIN when user wishes to process data
.END LIST
.LM -5
.HL 2 ICOMNT
.LM +5
.LIST
.LE;accepts the user comment via EDITPM and allows this comment to
be copied to apply to other entries
.LE;comments are written to a *.RCD file. This is used by MMDATR
(qv) to update the data base
.LE;returns control to INPUTR
.END LIST
.LM -5
.HL 2 PLTSHF
.LM +5
.LIST
.LE;lets the user view up to the previous 50 values of a given
measurement
.LE;returns control to INPUTR
.LIT

   Note: MMDATR is run as a batch job so that the user may
         continue  using PMS while the data  base is being
         updated. MMDATR may take several minutes to run.

.EL
.END LIST
.LM -5
.HL 2 MMDATR
.LM +5
.BREAK
.LIST
.LE;actually updates the data base using
.BREAK
#####(a) *.DAT which holds the data for the while transaction
.BREAK
#####(b) *.RCD which holds comments for the readings
.BREAK
The value of * is determined by the time at which the files are
created so these files are unique. They are deleted at the end
of the run.
.LE;IPRUNI's EXPTER which updates the history data base. EXPTER
only runs if there is exception information from the user's
input. If there is then EXPTER runs RUNPRT to print out any
processing error information. Otherwise RUNPRT is run by
MMDATR.
.LE;sends a message to the TTY which requested the job (via TERTLK)
saying that the run has completed ok or not
.LE;sends a message to WAYTER reporting its completion. (WAYTER
collects information from different runs of PLNTIN during a
shift and then runs the calculation program CALCNS when all
the information is in.)
.LE;tidies up and exits
.END LIST
.LM -10

.APP TRANSFER OF FILES FROM DEC20 TO VAX 

.HL 1 TRANSFER OF FILES FROM DEC20 TO TAPE

.LIT

@ENABLE (CAPABILITIES)
$
$;  Run OPR and initialise a tape with ANSI labels.....
$
$OPR
OPR>SET TAPE-DRIVE MTA1: INITIALISE /LABEL-TYPE:ANSI-
/VOLUME-ID:TREVOR
OPR>
14:11:12 	  -- MTA1: Volume TREVOR Initialised --
		Label type: ANSI        Density: 1600

14:11:13 	  -- INITIALISE Completed --
		MTA1: available for user tape requests
OPR>EX
$
$;   Now mount the tape.....
$
$MOUNT TAPE (NAME) TREVOR: /WRITE-ENABLED
[Mount request TREVOR queued, request #1452]

[Tape set TREVOR, volume TREVOR mounted]
[TREVOR: defined as MT1:]
$
$;   Now we can copy all the files onto the tape....
$
$COP *.* TREVOR:,
$$ASCII NOPARITY
$$; Noparity is the default
$$
 PMSPLN.TXT.1 => MT1:PMSPLN.TXT.131071 [OK]
 VAX.MEM.1 => MT1:VAX.MEM.131071 [OK]
 VAXPLN.MEM.1 => MT1:VAXPLN.MEM.131071 [OK]
 VAXPMS.TXT.1 => MT1:VAXPMS.TXT.131071 [OK]
 VAXPOS.TXT.1 => MT1:VAXPOS.TXT.131071 [OK]
$
$;    and dismount the tape....
$
$DISMOUNT TAPE (NAME) TREVOR:
[Tape dismounted, logical name TREVOR: deleted]
$

.EL
.PG

.HL 1 TRANSFER FROM TAPE TO VAX

.LIT

$
$ !    get where we want to be....(like TOPS20 CONNECT)
$
$ SET DEFAULT  [MOORE.US]
$
$ !    now mount the tape.....
$
$ MOUNT MSA0: TREVOR
volume is write locked
TREVOR mounted on _MSA0:
$
$ !    receive cheery VMS message.
$ !    we check that it is all there with the DIRECTORY command
$
$ DIR MSA0:

Directory MSA0:[]

PMSPLN.TXT;32767  VAX.MEM;32767   VAXPLN.MEM;32767  VAXPMS.TXT;1
VAXPOS.TXT;32767

Total of 5 files.
$
$ !    VMS rewinds for you so we can
$ !    now copy the files
$
$ COPY MSA0:*.*;* [MOORE.US]*.*;*
$
$ !    VMS' default is not to tell you unless it fails
$ !    so we check....
$
$ DIR

Directory US1:[MOORE.US]

MYNOTE.MEM;1      MYNOTE.RNO;3      PMSPLN.TXT;32767  VAX.MEM;1
VAXPLN.MEM;32767  VAXPMS.TXT;32767  VAXPOS.TXT;32767

Total of 7 files.
$
$ !    now change these silly generation numbers....
$
$ REN *.*;32767 *.*;1
$
$ !    RENAME is like TOPS20 but agin default is no confirmation.
$
.EL

.APP STAGES OF PROGRAM CONVERSION

.HL 1 SUMMARY

This appendix deals with the stages in converting the program 
code
as distinct from the data base conversion which
is discussed in Section 8 and Appendix E.
There were three distinct stages to the conversion which are 
discussed below.  These were firstly the straight conversion 
of COBOL code, secondly the conversion
of the screen handling and finally testing and bug fixing.

.HL 1 STRAIGHT COBOL CONVERSION

This involved the removal of all Macro calls and the conversion of all 
DML statements to achieve a clean compile.
All the database error handling that
used declaratives was amended and tests for success status
after each database access were inserted.

Transactions (OPEN/CLOSE) which exist in DBMS20 were replaced 
by READY and COMMIT/ROLLBACK on the VAX. (See Appendix E.)

.HL 1 SCREEN CONVERSION. 

There were three general problem areas that required 
consideration. These were
.LM +5
.LIST
.LE;retaining special functions keys,
.LE;providing user help and
.LE;limiting the size of the TDMS libraries.
.END LIST
.LM -5

.HL 2 Special Function Keys

The functionality of these keys had to remain, although 
the actual keys were replaced with meaningful Gold keys.

.LIT

The following function keys were used:

     KEY	    FUNCTION		   REPLACING 	    RETURN 
                                                           INDICATOR 
                                                             VALUE
     ---------------------------------------------------------------
     GOLD U-p       step up a field 	   Line Feed	       3
     GOLD D-own     step down a field      CR/normal input     5 
     GOLD X-exit    abort/exit	           Down Arrow	       6
     GOLD B-ack     step back a page/form  Up Arrow	       7 
     GOLD F-orward  step forward 	   Not applicable      8

NB: A return indicator of 5 is always returned from a request
    unless one of the functions keys is used

.EL

.HL 2 Providing user help

As one of the modules required full screen help on a per
field basis which was implemented directly within the program 
code,
we retained this
help text including VT100 cursor control sequences,
since this  caused no 
problem to TDMS. TRAFFIC users will recall that this is a 
problem when using version 2.0 of TRAFFIC. 
It is, however, unfortunate that there is no way of forcing a CONTROL-W 
(re-paint screen) from within the code, so it was necessary
to redisplay after each help request, which of course takes time.


.HL 2 TDMS library size

The two main screen i/o modules (PLNTIN and INPUTR)
were converted using a different 
method for each. Initially it was thought that it would be necessary 
to replace each individual TRAFFIC call 
by one TDMS request. The problem with this would have been a 
request library which contained a large number of requests. Since 
the request library is searched sequentially at run-time there 
were some unattractive performance implications with this.
As competence with TDMS increased it was possible to 
avoid the large libraries which it was feared would result from
taking this approach. (See Appendix G.)


.HL 1 TESTING AND BUG FIXING

Testing and bug fixing constituted a fairly
large part of the program conversion effort.
This was mainly because of the lack of functional and in-program
documentation, and the relatively poor
quality of the code itself. The conversion brought to light some 
existing bugs in the original program suite (which were of course also 
converted because the exercise was to achieve an identical, 
or nearly identical, copy!!).

The small Cobol only or Cobol with DML modules required simple 
testing and the very few bugs that came to light were to do 
with either the difference in data structure or the difference 
between initialising variables on the 20 and Vax.

The major screen modules required the most time and effort 
to test and debug.

.HL 2 PLNTIN

This module probably took the longest to obtain a satisfactory 
working copy for the following reasons:
.LM +5
.LIST "o"
.LE;it was the first screen module to be converted 
so inevitable mistakes using TDMS were made.
.LE;the degree of re-structuring made it necessary 
to understand in detail the function of the module.
.LE;testing of the function/logic of the module 
as well as conversion changes was 
required.
.END LIST
.LM -5
.HL 2 INPUTR

The second method of screen conversion
was applied to this module. As this method requires no change to the 
fundamental program logic and structure, testing and debugging
was simpler than with PLNTIN (see above).
Some time was wasted due to
errors with the database conversion - when unloading and reloading the 
data base some data was lost. Time was also lost chasing 
after bugs which also existed in the original 20 version.


.APP EXAMPLES OF DBMS DIFFERENCES

.HL 1 Definition of schema and storage schema

.HL 1 Selected DML examples

.LIT

SCHEMA SECTION.
	INVOKE SUB-SCHEMA plntss OF SCHEMA pms.		        20

SUB-SCHEMA SECTION.
	DB nysub WITHIN pms.				        VAX

OPEN TRANSACTION modify-list.					20
READY list-area CONCURRENT UPDATE.				VAX


FIND NEXT RECORD OF list-mle-set SET.				20
FETCH NEXT WITHIN list-mle-set.					VAX


FIND list-record VIA CURRENT OF list-set USING list-key.	20
FETCH FIRST list-record WITHIN list-set USING list-key.		VAX


FIND NEXT input-list-record RECORD OF list-set SET.		20
FETCH NEXT list-record WITHIN list-set.				VAX


CLOSE TRANSACTION modify-list.					20
COMMIT.								VAX

.EL

.HL 2 DBMS Error Handling

.LIT

*************
DECLARATIVES.
*************

FIND-END SECTION.
*****************
	USE FOR DB-EXCEPTION ON dbm$_end.

FE-01.
	SET no-record TO true.

FE-END.
	EXIT.


OWNER-ERROR SECTION.
********************
	USE FOR DB-EXCEPTION ON dbm$_cstyp_null.

OE-01.
	SET no-owner TO true.

OE-END.
	EXIT.

.EL

.APP EXAMPLES OF COBOL DIFFERENCES

.HL 1 Selected COBOL examples

.LIT

Example 1.

WORKING-STORAGE SECTION.
************************
01	ACTION-FLAG		PIC S9(10)	COMP.
	88	GET-OUT-NOW		VALUE 1.
	88	WILL-EXIT		VALUE 2.
	88	PREVIOUS-MENU		VALUE 3.
	88	CONTINUE-PROCESS	VALUE 4.

PROCESSING-SECTION.
*******************
	SET action-flag TO 1.			20

	MOVE 1 TO action-flag.			VAX
	SET get-out-now TO true.		VAX

Example 2.

ID DIVISION.                                    20

IDENTIFICATION DIVISION.                        VAX

Example 3.

FILE-CONTROL.

	SELECT updater-file ASSIGN TO dsk1
		RECORDING MODE ASCII
		file-status IS fs-1,fs-2,fs-3.		20



	SELECT updater-file ASSIGN TO dsk1
		file status IS fs-1.			VAX



.EL


.APP SCREEN CONVERSION OPTIONS

Two methods of screen conversion were used.
.HL 1 METHOD 1

This method made use of TDMS in 
more like the way the designers had 
probably intended it to be used.
This required a limited 
amount of restructuring and used multi-function TDMS requests. 
A multi-function request is one which can itself clear the 
screen, display a form, read fields and make decisions from within a 
single request. This 
method, although providing a cosmetically pleasing finished module, 
proved to be more difficult to achieve than anticipated.

.HL 1 METHOD 2

This method 
replaces TRAFFIC call for call
by TDMS requests. It defines a TDMS control field in a single 
program-wide request which is then mapped one to one with TRAFFIC 
section or field numbers.


.APP SCREEN HANDLING COMPARISONS

.HL 1 REPLACING TFRERR

.LIT

*	ENTER MACRO tfrerr USING "Incorrect use of function key." 
				  error-status error-code.

	CALL "tss$write_msg_line" USING BY REFERENCE channel,
					BY DESCRIPTOR "Incorrect use of function key." 

.EL

.HL 1 EXAMPLE OF MULTI-FUNCTION REQUEST

.HL 2 COBOL CODE

.LIT

*	********************************************************
*	* move formatted lines to the screen display variables *
*	********************************************************
	PERFORM VARYING wk_count FROM 1 BY 1 UNTIL wk_count > 20
		MOVE list_line(wk_count) TO plntin_list_line(wk_count)
	END-PERFORM.

	SET unfinished TO true.
	MOVE spaces TO plntin_list_choice.
	MOVE "1" TO plntin_list_page_no.
	MOVE total_lists TO list_val.
	
FULL-04.
	SET unfinished TO true.

	PERFORM UNTIL finished

		IF plntin_list_page_no = "1"
		THEN	MOVE "F forward page" TO list_page
		ELSE	MOVE "B back page" TO list_page
		END-IF

		MOVE list_message TO plntin_list_message

*		**********************************
*		* display page and accept choice *
*		**********************************
		CALL "TSS$REQUEST" USING BY REFERENCE channel,
					 BY REFERENCE library-id,
					 BY DESCRIPTOR request-list(2),
					 BY REFERENCE plntin_work
				   GIVING status-result

		PERFORM CHECK

		PERFORM read-list-choice

	END-PERFORM.

	IF get-out-now OR will-exit OR previous-menu
		GO TO full-exit.

.EL

.HL 2 TDMS REQUEST

.LIT

FORM IS PLNTIN_LIST_SCREEN;
RECORD IS PLNTIN_WORK;

RETURN "5" TO PLNTIN_END_IND;

PROGRAM KEY IS GOLD "X"
	NO CHECK;
	RETURN "6" TO PLNTIN_END_IND;
END PROGRAM KEY;

PROGRAM KEY IS GOLD "B"
	NO CHECK;
	RETURN "7" TO PLNTIN_END_IND;
END PROGRAM KEY;

	USE FORM PLNTIN_LIST_SCREEN;

	CONTROL FIELD IS PLNTIN_LIST_PAGE_NO
		"1":
		OUTPUT PLNTIN_LIST_LINE[1 TO 10] TO PLNTIN_LIST_DETAIL[1 TO 10];

		"2":
		OUTPUT PLNTIN_LIST_LINE[11 TO 20] TO PLNTIN_LIST_DETAIL[1 TO 10];
	END CONTROL FIELD;

	OUTPUT "  " TO PLNTIN_LIST_CHOICE;
	OUTPUT PLNTIN_LIST_MESSAGE TO PLNTIN_LIST_MESSAGE;
	INPUT PLNTIN_LIST_CHOICE TO PLNTIN_LIST_CHOICE;

	RETURN "L" TO PLNTIN_SCREEN;

END DEFINITION;

.EL

.HL 1 REPLACING TFRRD

.HL 2 COBOL CODE

.LIT

STANDARD-READER SECTION.
************************
SR-1.

*	ENTER MACRO tfrrd USING fieldz end-ind error-code.

	MOVE spaces TO inputr_reading.
	MOVE fieldz TO inputr_field_no.

	CALL "tss$request"
		USING BY REFERENCE channel,
		BY REFERENCE library-id,
		BY DESCRIPTOR request-list(1),
		BY REFERENCE inputr_work,
		GIVING status-result.
	PERFORM check.

*	*************************************************
*	* move data read to the 'old' traffic variables *
*	*************************************************
	EVALUATE fieldz

	WHEN 25 thru 38
		MOVE inputr_reading TO value-array(fieldz - 24)

	WHEN 81
		MOVE inputr_choice TO inp-choice

	WHEN 122
		MOVE inputr_page_choice TO pag_choice

	WHEN 90
		MOVE inputr_reading TO inp-inf-value

	WHEN 132
		MOVE inputr_choice TO inp-inf-choice

	END-EVALUATE.

	MOVE inputr_end_ind to end-ind.

	IF end-ind = 1 
		GO TO sr-2.

.EL

.HL 2 TDMS REQUEST

.LIT

FORM IS INPUTR;
FORM IS INPUTR_VALIDN_SCREEN;
RECORD IS INPUTR_WORK;

RETURN "5" TO INPUTR_END_IND;

PROGRAM KEY IS GOLD "X"
	NO CHECK;
	RETURN "6" TO INPUTR_END_IND;
END PROGRAM KEY;

PROGRAM KEY IS GOLD "B"
	NO CHECK;
	RETURN "7" TO INPUTR_END_IND;
END PROGRAM KEY;

PROGRAM KEY IS GOLD "F"
	NO CHECK;
	RETURN "8" TO INPUTR_END_IND;
END PROGRAM KEY;

PROGRAM KEY IS GOLD "U"
	NO CHECK;
	RETURN "3" TO INPUTR_END_IND;
END PROGRAM KEY;

	CONTROL FIELD IS INPUTR_FIELD_NO

	"025":	USE FORM INPUTR;
		INPUT READING[1] TO INPUTR_READING;
	"026":	USE FORM INPUTR;
		INPUT READING[2] TO INPUTR_READING;
	"027":	USE FORM INPUTR;
		INPUT READING[3] TO INPUTR_READING;
	"028":	USE FORM INPUTR;
		INPUT READING[4] TO INPUTR_READING;
	"029":	USE FORM INPUTR;
		INPUT READING[5] TO INPUTR_READING;
	"030":	USE FORM INPUTR;
		INPUT READING[6] TO INPUTR_READING;
	"031":	USE FORM INPUTR;
		INPUT READING[7] TO INPUTR_READING;
	"032":	USE FORM INPUTR;
		INPUT READING[8] TO INPUTR_READING;
	"033":	USE FORM INPUTR;
		INPUT READING[9] TO INPUTR_READING;
	"034":	USE FORM INPUTR;
		INPUT READING[10] TO INPUTR_READING;
	"035":	USE FORM INPUTR;
		INPUT READING[11] TO INPUTR_READING;
	"036":	USE FORM INPUTR;
		INPUT READING[12] TO INPUTR_READING;
	"037":	USE FORM INPUTR;
		INPUT READING[13] TO INPUTR_READING;
	"038":	USE FORM INPUTR;
		INPUT READING[14] TO INPUTR_READING;
	"081":	USE FORM INPUTR;
		OUTPUT " " TO CHOICE;
		INPUT CHOICE TO INPUTR_CHOICE;
	"122":	USE FORM INPUTR;
		INPUT PAGE_CHOICE TO INPUTR_PAGE_CHOICE;
	"132":	USE FORM INPUTR_VALIDN_SCREEN;
		OUTPUT " " TO VALIDN_CHOICE;
		INPUT VALIDN_CHOICE TO INPUTR_CHOICE;
	"090":	USE FORM INPUTR_VALIDN_SCREEN;
		INPUT VALIDN_READING TO INPUTR_READING;

	END CONTROL FIELD;

END DEFINITION;

.EL

.HL 1 REPLACING TFRWRT

.HL 2 COBOL CODE

.LIT

*		MOVE inp-last-value TO data-val(page-no,line-no),
*				value-array(line-no)
*		enter macro tfrwrt using field-no error-code

		MOVE inp-last-value TO data-val(page-no,line-no),
				value-array(line-no),inputr_reading
		MOVE field-no TO inputr_field_no
		CALL "tss$request" USING BY REFERENCE channel,
					 BY REFERENCE library-id,
					 BY DESCRIPTOR request-list(3),
					 BY REFERENCE inputr_work,
				   GIVING status-result
		PERFORM check

.EL

.HL 2 TDMS REQUEST

.LIT

FORM IS INPUTR;
RECORD IS INPUTR_WORK;

USE FORM INPUTR;

	CONTROL FIELD IS INPUTR_FIELD_NO

	"025":	OUTPUT "          " TO READING[1];
		OUTPUT INPUTR_READING TO READING[1];
	"026":	OUTPUT "          " TO READING[2];
		OUTPUT INPUTR_READING TO READING[2];
	"027":	OUTPUT "          " TO READING[3];
		OUTPUT INPUTR_READING TO READING[3];
	"028":	OUTPUT "          " TO READING[4];
		OUTPUT INPUTR_READING TO READING[4];
	"029":	OUTPUT "          " TO READING[5];
		OUTPUT INPUTR_READING TO READING[5];
	"030":	OUTPUT "          " TO READING[6];
		OUTPUT INPUTR_READING TO READING[6];
	"031":	OUTPUT "          " TO READING[7];
		OUTPUT INPUTR_READING TO READING[7];
	"032":	OUTPUT "          " TO READING[8];
		OUTPUT INPUTR_READING TO READING[8];
	"033":	OUTPUT "          " TO READING[9];
		OUTPUT INPUTR_READING TO READING[9];
	"034":	OUTPUT "          " TO READING[10];
		OUTPUT INPUTR_READING TO READING[10];
	"035":	OUTPUT "          " TO READING[11];
		OUTPUT INPUTR_READING TO READING[11];
	"036":	OUTPUT "          " TO READING[12];
		OUTPUT INPUTR_READING TO READING[12];
	"037":	OUTPUT "          " TO READING[13];
		OUTPUT INPUTR_READING TO READING[13];
	"038":	OUTPUT "          " TO READING[14];
		OUTPUT INPUTR_READING TO READING[14];

	END CONTROL FIELD;

END DEFINITION;

.EL

.HL 1 REPLACING TFRCHG

.HL 2 CDD Work Area

.LIT

	INPUTR_VIDEO_ATTRIBUTES STRUCTURE.
		INPUTR_VIDEO	DATATYPE TEXT 1 OCCURS 14 TIMES.
	END INPUTR_VIDEO_ATTRIBUTES STRUCTURE.

.EL

.HL 2 COBOL CODE

.LIT

*	enter macro tfrchg using field-no 'NORMAL' error-code.
	MOVE spaces TO inputr_video_attributes.
	MOVE "7" TO inputr_video(field-no - 24).
	CALL "tss$request" USING BY REFERENCE channel,
				 BY REFERENCE library-id,
				 BY DESCRIPTOR request-list(5),
				 BY REFERENCE inputr_work,
			   GIVING status-result.
	PERFORM check.


*		ENTER MACRO TFRCHG USING COL-5 'REVERSE-VIDEO' ERROR-CODE
*		ENTER MACRO TFRCHG USING COL-5 'BOLD' ERROR-CODE.
		MOVE spaces TO inputr_video_attributes
		MOVE "5" TO inputr_video(col-5 - 24)
		CALL "tss$request" USING BY REFERENCE channel,
					 BY REFERENCE library-id,
					 BY DESCRIPTOR request-list(5),
					 BY REFERENCE inputr_work,
				   GIVING status-result
		PERFORM check.

.EL

.HL 2 TDMS REQUEST

.LIT

FORM IS INPUTR;
RECORD IS INPUTR_WORK;

USE FORM INPUTR;

	CONTROL FIELD IS INPUTR_VIDEO[1 TO 14]
		"1":	BLINK FIELD READING[%LINE];
		
		"2":	REVERSE FIELD READING[%LINE];
			BLINK FIELD READING[%LINE];

		"3":	BLINK FIELD READING[%LINE];
			REVERSE FIELD READING[%LINE];
			BOLD FIELD READING[%LINE];

		"4":	BLINK FIELD READING[%LINE];
			BOLD FIELD READING[%LINE];

		"5":	REVERSE FIELD READING[%LINE];
			BOLD FIELD READING[%LINE];

		"6":	REVERSE FIELD READING[%LINE];
	
		"7":	RESET FIELD READING[%LINE];
	
	END CONTROL FIELD;

END DEFINITION;

.EL