To read the COBOL-genned file, you'll need to know:
First, you'll need the record layout (copybook) for the file. A COBOL record layout will look something like this:
05 PATIENT-NAME PIC X(30).
05 PATIENT-SS-NUMBER PIC 9(9).
05 NUMBER-OF-TREATMENTS PIC 99 COMP-3.
05 TREATMENT-HISTORY OCCURS 0 TO 50 TIMES
DEPENDING ON NUMBER-OF-TREATMENTS
INDEXED BY TREATMENT-POINTER.
15 TREATMENT-DAY PIC 99.
15 TREATMENT-MONTH PIC 99.
15 TREATMENT-YEAR PIC 9(4).
10 TREATING-PHYSICIAN PIC X(30).
10 TREATMENT-CODE PIC 99.
You'll also need a copy of IBM's Principles of Operation (S/360, S370, z/OS, doesn't really matter for our purposes). Latest is available from IBM at
Chapters 8 (Decimal Instructions) and 9 (Floating Point Overview and Support Instructions) are the interesting bits for our purposes.
Without that, you're pretty much lost.
Then, you need to understand COBOL data types. For instance:
- PIC defines an alphameric formatted field (PIC 9(4), for example is 4 decimal digits, that might be filled with for space characters if missing). Pic 999V99 is 5 decimal digits, with an implied decimal point. So-on and so forthe.
- BINARY is [usually] a signed fixed point binary integer. Usual sizes are halfword (2 octets) and fullword (4 octets).
- COMP-1 is single precision floating point.
- COMP-2 is double precision floating point.
If the datasource is an IBM mainframe, COMP-1 and COMP-2 likely won't be IEE floating point: it will be IBM's base-16 excess 64 floating point format. You'll need something like the S/370 Principles of Operation to help you understand it.
- COMP-3 is 'packed decimal', of varying lengths. Packed decimal is a compact way of representing a decimal number. The declaration will look something like this:
PIC S9999V99 COMP-3. This says that is it signed, consists of 6 decimal digits with an implied decimal point. Packed decimal represents each decimal digit as a nibble of an octet (hex values 0-9). The high-order digit is the upper nibble of the leftmost octet. The low nibble of the rightmost octet is a hex value A-F representing the sign. So the above
PIC clause will require
ceil( (6+1)/2 ) or 4 octets. the value -345.67, as represented by the above
PIC clause will look like
0x0034567D. The actual sign value may vary (the default is C/positive, D/negative, but A, C, E and F are treated as positive, while only B and D are treated as negative). Again, see the S\370 Principles of Operation for details on the representation.
Related to COMP-3 is zoned decimal. This might be declared as `PIC S9999V99' (signed, 5 decimal digits, with an implied decimal point). Decimal digits, in EBCDIC, are the hex values 0xFO - 0xF9. 'Unpack' (mainframe machine instruction) takes a packed decimal field and turns in into a character field. The process is:
- start with the rightmost octet. Invert it, so the sign nibble is on top and place it into the rightmost octet of the destination field.
Working from right to left (source and the target both), strip off each remaining nibble of the packed decimal field, and place it into the low nibble of the next available octet in the destination. Fill the high nibble with a hex F.
The operation ends when either the source or destination field is exhausted.
If the destination field is not exhausted, if it left-padded with zeroes by filling the remaining octets with decimal '0' (oxF0).
So our example value, -345.67, if stored with the default sign value (hex D), would get unpacked as 0xF0F0F0F3F4F5F6D7 ('0003456P', in EBDIC).
[There you go. There's a quiz later]
- If the COBOL app lives on an IBM mainframe, has the file been converted from its native EBCDIC to ASCII? If not, you'll have to do the mapping your self (Hint: its not necessarily as straightforward as that might seem, since this might be a selective process -- only character fields get converted (COMP-1, COMP-2, COMP-3 and BINARY get excluded since they are a sequence of binary octets). Worse, there are multiple flavors of EBCDIC representations, due to the varying national implementations and varying print chains in use on different printers.
Oh...one last thing. The mainframe hardware tends to like different things aligned on halfword, word or doubleword boundaries, so the record layout may not map directly to the octets in the file as there may be padding octets inserted between fields to maintain the needed word alignment.