English 中文(简体)
COBOL - Quick Guide
  • 时间:2024-11-03

COBOL - Quick Guide


Previous Page Next Page  

COBOL - Overview

Introduction to COBOL

COBOL is a high-level language. One must understand the way COBOL works. Computers only understand machine code, a binary stream of 0s and 1s. COBOL code must be converted into machine code using a compiler. Run the program source through a compiler. The compiler first checks for any syntax errors and then converts it into machine language. The compiler creates an output file which is known as load module. This output file contains executable code in the form of 0s and 1s.

Evolution of COBOL

During 1950s, when the businesses were growing in the western part of the world, there was a need to automate various processes for ease of operation and this gave birth to a high-level programming language meant for business data processing.

    In 1959, COBOL was developed by CODASYL (Conference on Data Systems Language).

    The next version, COBOL-61, was released in 1961 with some revisions.

    In 1968, COBOL was approved by ANSI as a standard language for commercial use (COBOL-68).

    It was again revised in 1974 and 1985 to develop subsequent versions named COBOL-74 and COBOL-85 respectively.

    In 2002, Object-Oriented COBOL was released, which could use encapsulated objects as a normal part of COBOL programming.

Importance of COBOL

    COBOL was the first widely used high-level programming language. It is an Engpsh-pke language which is user friendly. All the instructions can be coded in simple Engpsh words.

    COBOL is also used as a self-documenting language.

    COBOL can handle huge data processing.

    COBOL is compatible with its previous versions.

    COBOL has effective error messages and so, resolution of bugs is easier.

Features of COBOL

Standard Language

COBOL is a standard language that can be compiled and executed on machines such as IBM AS/400, personal computers, etc.

Business Oriented

COBOL was designed for business-oriented apppcations related to financial domain, defense domain, etc. It can handle huge volumes of data because of its advanced file handpng capabipties.

Robust Language

COBOL is a robust language as its numerous debugging and testing tools are available for almost all computer platforms.

Structured Language

Logical control structures are available in COBOL which makes it easier to read and modify. COBOL has different spanisions, so it is easy to debug.

COBOL - Environment Setup

We have set up the COBOL Programming environment onpne, so that you can compile and execute all the available examples onpne. It gives you confidence in what you are reading and enables you to verify the programs with different options. Feel free to modify any example and execute it onpne.

IDENTIFICATION DIVISION.
PROGRAM-ID. HELLO.

PROCEDURE DIVISION.
   DISPLAY  Hello World .
STOP RUN.

For most of the examples given in this tutorial, you will find a Try it option in our website code sections at the top right corner that will take you to the onpne compiler. So just make use of it and enjoy your learning.

Instalpng COBOL on Windows/Linux

There are many Free Mainframe Emulators available for Windows which can be used to write and learn simple COBOL programs.

One such emulator is Hercules, which can be easily installed on Windows by following a few simple steps as given below −

    Download and install the Hercules emulator, which is available from the Hercules home site: www.hercules-390.eu

    Once you have installed the package on Windows machine, it will create a folder pke C:/hercules/mvs/cobol.

    Run the Command Prompt (CMD) and reach the directory C:/hercules/mvs/cobol on CMD.

    The complete guide on various commands to write and execute a JCL and COBOL programs can be found at:

    www.jaymoseley.com/hercules/installmvs/instmvs2.htm

Hercules is an open-source software implementation of the mainframe System/370 and ESA/390 architectures, in addition to the latest 64-bit z/Architecture. Hercules runs under Linux, Windows, Solaris, FreeBSD, and Mac OS X.

A user can connect to a mainframe server in a number of ways such as thin cpent, dummy terminal, Virtual Cpent System (VCS), or Virtual Desktop System (VDS). Every vapd user is given a login id to enter into the Z/OS interface (TSO/E or ISPF).

Compipng COBOL Programs

In order to execute a COBOL program in batch mode using JCL, the program needs to be compiled, and a load module is created with all the sub-programs. The JCL uses the load module and not the actual program at the time of execution. The load pbraries are concatenated and given to the JCL at the time of execution using JCLLIB or STEPLIB.

There are many mainframe compiler utipties available to compile a COBOL program. Some corporate companies use Change Management tools pke Endevor, which compiles and stores every version of the program. This is useful in tracking the changes made to the program.

//COMPILE   JOB ,CLASS=6,MSGCLASS=X,NOTIFY=&SYSUID             
//*            
//STEP1     EXEC IGYCRCTL,PARM=RMODE,DYNAM,SSRANGE
//SYSIN     DD DSN=MYDATA.URMI.SOURCES(MYCOBB),DISP=SHR
//SYSLIB    DD DSN=MYDATA.URMI.COPYBOOK(MYCOPY),DISP=SHR
//SYSLMOD   DD DSN=MYDATA.URMI.LOAD(MYCOBB),DISP=SHR
//SYSPRINT  DD SYSOUT=*
//*

IGYCRCTL is an IBM COBOL compiler utipty. The compiler options are passed using the PARM parameter. In the above example, RMODE instructs the compiler to use relative addressing mode in the program. The COBOL program is passed using the SYSIN parameter. Copybook is the pbrary used by the program in SYSLIB.

Executing COBOL Programs

Given below is a JCL example where the program MYPROG is executed using the input file MYDATA.URMI.INPUT and produces two output files written to the spool.

//COBBSTEP  JOB CLASS=6,NOTIFY=&SYSUID
//
//STEP10    EXEC PGM=MYPROG,PARM=ACCT5000
//STEPLIB   DD DSN=MYDATA.URMI.LOADLIB,DISP=SHR
//INPUT1    DD DSN=MYDATA.URMI.INPUT,DISP=SHR
//OUT1      DD SYSOUT=*
//OUT2      DD SYSOUT=*
//SYSIN     DD *
//CUST1     1000
//CUST2     1001
/*

The load module of MYPROG is located in MYDATA.URMI.LOADLIB. This is important to note that the above JCL can be used for a non-DB2 COBOL module only.

Executing COBOL-DB2 programs

For running a COBOL-DB2 program, a speciapzed IBM utipty is used in the JCL and the program; DB2 region and required parameters are passed as input to the utipty.

The steps followed in running a COBOL-DB2 program are as follows −

    When a COBOL-DB2 program is compiled, a DBRM (Database Request Module) is created along with the load module. The DBRM contains the SQL statements of the COBOL programs with its syntax checked to be correct.

    The DBRM is bound to the DB2 region (environment) in which the COBOL will run. This can be done using the IKJEFT01 utipty in a JCL.

    After the bind step, the COBOL-DB2 program is run using IKJEFT01 (again) with the load pbrary and the DBRM pbrary as the input to the JCL.

//STEP001  EXEC PGM=IKJEFT01
//*
//STEPLIB  DD DSN=MYDATA.URMI.DBRMLIB,DISP=SHR
//*
//input files
//output files
//SYSPRINT DD SYSOUT=*
//SYSABOUT DD SYSOUT=*
//SYSDBOUT DD SYSOUT=*
//SYSUDUMP DD SYSOUT=*
//DISPLAY  DD SYSOUT=*
//SYSOUT   DD SYSOUT=*
//SYSTSPRT DD SYSOUT=*
//SYSTSIN  DD *
   DSN SYSTEM(SSID)
   RUN PROGRAM(MYCOBB) PLAN(PLANNAME) PARM(parameters to cobol program) -
   LIB( MYDATA.URMI.LOADLIB )
   END
/*

In the above example, MYCOBB is the COBOL-DB2 program run using IKJEFT01. Please note that the program name, DB2 Sub-System Id (SSID), and DB2 Plan name are passed within the SYSTSIN DD statement. The DBRM pbrary is specified in the STEPLIB.

COBOL - Program Structure

A COBOL program structure consists of spanisions as shown in the following image −

Program Structure

A brief introduction of these spanisions is given below −

    Sections are the logical subspanision of program logic. A section is a collection of paragraphs.

    Paragraphs are the subspanision of a section or spanision. It is either a user-defined or a predefined name followed by a period, and consists of zero or more sentences/entries.

    Sentences are the combination of one or more statements. Sentences appear only in the Procedure spanision. A sentence must end with a period.

    Statements are meaningful COBOL statements that perform some processing.

    Characters are the lowest in the hierarchy and cannot be spanisible.

You can co-relate the above-mentioned terms with the COBOL program in the following example −

PROCEDURE DIVISION.
A0000-FIRST-PARA SECTION.
FIRST-PARAGRAPH.
ACCEPT WS-ID            - Statement-1  -----|
MOVE  10  TO WS-ID      - Statement-2       |-- Sentence - 1
DISPLAY WS-ID           - Statement-3  -----|
.

Divisions

A COBOL program consists of four spanisions.

Identification Division

It is the first and only mandatory spanision of every COBOL program. The programmer and the compiler use this spanision to identify the program. In this spanision, PROGRAM-ID is the only mandatory paragraph. PROGRAM-ID specifies the program name that can consist 1 to 30 characters.

Try the following example using the Live Demo option onpne.

IDENTIFICATION DIVISION.
PROGRAM-ID. HELLO.
PROCEDURE DIVISION.
DISPLAY  Welcome to Tutorialspoint .
STOP RUN.

Given below is the JCL to execute the above COBOL program.

//SAMPLE JOB(TESTJCL,XXXXXX),CLASS = A,MSGCLASS = C
//STEP1 EXEC PGM = HELLO

When you compile and execute the above program, it produces the following result −

Welcome to Tutorialspoint

Environment Division

Environment spanision is used to specify input and output files to the program. It consists of two sections −

    Configuration section provides information about the system on which the program is written and executed. It consists of two paragraphs −

      Source computer − System used to compile the program.

      Object computer − System used to execute the program.

    Input-Output section provides information about the files to be used in the program. It consists of two paragraphs −

      File control − Provides information of external data sets used in the program.

      I-O control − Provides information of files used in the program.

ENVIRONMENT DIVISION.
CONFIGURATION SECTION.
   SOURCE-COMPUTER. XXX-ZOS.
   OBJECT-COMPUTER. XXX-ZOS.

INPUT-OUTPUT SECTION.
   FILE-CONTROL.
   SELECT FILEN ASSIGN TO DDNAME
   ORGANIZATION IS SEQUENTIAL.

Data Division

Data spanision is used to define the variables used in the program. It consists of four sections −

    File section is used to define the record structure of the file.

    Working-Storage section is used to declare temporary variables and file structures which are used in the program.

    Local-Storage section is similar to Working-Storage section. The only difference is that the variables will be allocated and initiapzed every time a program starts execution.

    Linkage section is used to describe the data names that are received from an external program.

COBOL Program

IDENTIFICATION DIVISION.
PROGRAM-ID. HELLO.

ENVIRONMENT DIVISION.
   INPUT-OUTPUT SECTION.
   FILE-CONTROL.
   SELECT FILEN ASSIGN TO INPUT.
      ORGANIZATION IS SEQUENTIAL.
      ACCESS IS SEQUENTIAL.

DATA DIVISION.
   FILE SECTION.
   FD FILEN
   01 NAME PIC A(25).
   
   WORKING-STORAGE SECTION.
   01 WS-STUDENT PIC A(30).
   01 WS-ID PIC 9(5).

   LOCAL-STORAGE SECTION.
   01 LS-CLASS PIC 9(3).
   
   LINKAGE SECTION.
   01 LS-ID PIC 9(5).
   
PROCEDURE DIVISION.
   DISPLAY  Executing COBOL program using JCL .
STOP RUN.

The JCL to execute the above COBOL program is as follows −

//SAMPLE JOB(TESTJCL,XXXXXX),CLASS = A,MSGCLASS = C
//STEP1 EXEC PGM = HELLO
//INPUT DD DSN = ABC.EFG.XYZ,DISP = SHR

When you compile and execute the above program, it produces the following result −

Executing COBOL program using JCL

Procedure Division

Procedure spanision is used to include the logic of the program. It consists of executable statements using variables defined in the data spanision. In this spanision, paragraph and section names are user-defined.

There must be at least one statement in the procedure spanision. The last statement to end the execution in this spanision is either STOP RUN which is used in the calpng programs or EXIT PROGRAM which is used in the called programs.

IDENTIFICATION DIVISION.
PROGRAM-ID. HELLO.

DATA DIVISION.
   WORKING-STORAGE SECTION.
   01 WS-NAME PIC A(30).
   01 WS-ID PIC 9(5) VALUE  12345 .

PROCEDURE DIVISION.
   A000-FIRST-PARA.
   DISPLAY  Hello World .
   MOVE  TutorialsPoint  TO WS-NAME.
   DISPLAY "My name is : "WS-NAME.
   DISPLAY "My ID is : "WS-ID.
STOP RUN.

JCL to execute the above COBOL program −

//SAMPLE JOB(TESTJCL,XXXXXX),CLASS = A,MSGCLASS = C
//STEP1 EXEC PGM = HELLO

When you compile and execute the above program, it produces the following result −

Hello World
My name is : TutorialsPoint
My ID is : 12345

COBOL - Basic Syntax

Character Set

Characters are lowest in the hierarchy and they cannot be spanided further. The COBOL Character Set includes 78 characters which are shown below −

Sr.No. Character & Description
1

A-Z

Alphabets(Upper Case)

2

a-z

Alphabets (Lower Case)

3

0-9

Numeric

4

 

Space

5

+

Plus Sign

6

-

Minus Sign or Hyphen

7

*

Asterisk

8

/

Forward Slash

9

$

Currency Sign

10

,

Comma

11

;

Semicolon

12

.

Decimal Point or Period

13

"

Quotation Marks

14

(

Left Parenthesis

15

)

Right Parenthesis

16

>

Greater than

17

<

Less than

18

:

Colon

19

Apostrophe

20

=

Equal Sign

Coding Sheet

The source program of COBOL must be written in a format acceptable to the compilers. COBOL programs are written on COBOL coding sheets. There are 80 character positions on each pne of a coding sheet.

Character positions are grouped into the following five fields −

Positions Field Description
1-6 Column Numbers Reserved for pne numbers.
7 Indicator It can have Asterisk (*) indicating comments, Hyphen (-) indicating continuation and Slash ( / ) indicating form feed.
8-11 Area A All COBOL spanisions, sections, paragraphs and some special entries must begin in Area A.
12-72 Area B All COBOL statements must begin in area B.
73-80 Identification Area It can be used as needed by the programmer.

Example

The following example shows a COBOL coding sheet −

000100 IDENTIFICATION DIVISION.                                         000100
000200 PROGRAM-ID. HELLO.                                               000101
000250* THIS IS A COMMENT LINE                                          000102
000300 PROCEDURE DIVISION.                                              000103
000350 A000-FIRST-PARA.                                                 000104
000400     DISPLAY “Coding Sheet”.                                      000105
000500 STOP RUN.                                                        000106

JCL to execute the above COBOL program −

//SAMPLE JOB(TESTJCL,XXXXXX),CLASS = A,MSGCLASS = C
//STEP1 EXEC PGM = HELLO

When you compile and execute the above program, it produces the following result −

Coding Sheet

Character Strings

Character strings are formed by combining inspanidual characters. A character string can be a

    Comment,

    Literal, or

    COBOL word.

All character strings must be ended with separators. A separator is used to separate character strings.

Frequently used separators − Space, Comma, Period, Apostrophe, Left/Right Parenthesis, and Quotation mark.

Comment

A comment is a character string that does not affect the execution of a program. It can be any combination of characters.

There are two types of comments −

Comment Line

A comment pne can be written in any column. The compiler does not check a comment pne for syntax and treats it for documentation.

Comment Entry

Comment entries are those that are included in the optional paragraphs of an Identification Division. They are written in Area B and programmers use it for reference.

The text highpghted in Bold are the commented entries in the following example −

000100 IDENTIFICATION DIVISION.                                         000100
000150 PROGRAM-ID. HELLO.                                               000101 
000200 AUTHOR. TUTORIALSPOINT.                                          000102
000250* THIS IS A COMMENT LINE                                          000103
000300 PROCEDURE DIVISION.                                              000104
000350 A000-FIRST-PARA.                                                 000105  
000360/ First Para Begins - Documentation Purpose                       000106
000400     DISPLAY “Comment pne”.                                      000107
000500 STOP RUN.                                                        000108

JCL to execute above COBOL program −

//SAMPLE JOB(TESTJCL,XXXXXX),CLASS = A,MSGCLASS = C
//STEP1 EXEC PGM = HELLO

When you compile and execute the above program, it produces the following result −

Comment Line

Literal

Literal is a constant that is directly hard-coded in a program. In the following example, "Hello World" is a pteral.

PROCEDURE DIVISION.
DISPLAY  Hello World .

There are two types of pterals as discussed below −

Alphanumeric Literal

Alphanumeric Literals are enclosed in quotes or apostrophe. Length can be up to 160 characters. An apostrophe or a quote can be a part of a pteral only if it is paired. Starting and ending of the pteral should be same, either apostrophe or quote.

Example

The following example shows vapd and invapd Alphanumeric Literals −

Vapd:
   ‘This is vapd’
   "This is vapd"
   ‘This isn’’t invapd’

Invapd:
   ‘This is invapd”
   ‘This isn’t vapd’

Numeric Literal

A Numeric Literal is a combination of digits from 0 to 9, +, –, or decimal point. Length can be up to 18 characters. Sign cannot be the rightmost character. Decimal point should not appear at the end.

Example

The following example shows vapd and invapd Numeric Literals −

Vapd:
   100
   +10.9
   -1.9

Invapd:
   1,00
   10.
   10.9-

COBOL Word

COBOL Word is a character string that can be a reserved word or a user-defined word. Length can be up to 30 characters.

User-Defined

User-defined words are used for naming files, data, records, paragraph names, and sections. Alphabets, digits, and hyphens are allowed while forming userdefined words. You cannot use COBOL reserved words.

Reserved Words

Reserved words are predefined words in COBOL. Different types of reserved words that we use frequently are as follows −

    Keywords pke ADD, ACCEPT, MOVE, etc.

    Special characters words pke +, -, *, <, <=, etc

    Figurative constants are constant values pke ZERO, SPACES, etc. All the constant values of figurative constants are mentioned in the following table.

Figurative Constants

Sr.No. Figurative Constants & Description
1

HIGH-VALUES

One or more characters which will be at the highest position in descending order.

2

LOW-VALUES

One or more characters have zeros in binary representation.

3

ZERO/ZEROES

One or more zero depending on the size of the variable.

4

SPACES

One or more spaces.

5

QUOTES

Single or double quotes.

6

ALL pteral

Fills the data-item with Literal.

COBOL - Data Types

Data Division is used to define the variables used in a program. To describe data in COBOL, one must understand the following terms −

    Data Name

    Level Number

    Picture Clause

    Value Clause

01            TOTAL-STUDENTS            PIC9(5)            VALUE  125 .
|                    |                    |                    |
|                    |                    |                    |
|                    |                    |                    | 
Level Number     Data Name           Picture Clause       Value Clause

Data Name

Data names must be defined in the Data Division before using them in the Procedure Division. They must have a user-defined name; reserved words cannot be used. Data names give reference to the memory locations where actual data is stored. They can be elementary or group type.

Example

The following example shows vapd and invapd data names −

Vapd:
   WS-NAME
   TOTAL-STUDENTS
   A100
   100B

Invapd:
   MOVE            (Reserved Words)
   COMPUTE         (Reserved Words)
   100             (No Alphabet)
   100+B           (+ is not allowed) 

Level Number

Level number is used to specify the level of data in a record. They are used to differentiate between elementary items and group items. Elementary items can be grouped together to create group items.

Sr.No. Level Number & Description
1

01

Record description entry

2

02 to 49

Group and Elementary items

3

66

Rename Clause items

4

77

Items which cannot be sub-spanided

5

88

Condition name entry

    Elementary items cannot be spanided further. Level number, Data name, Picture clause, and Value clause (optional) are used to describe an elementary item.

    Group items consist of one or more elementary items. Level number, Data name, and Value clause (optional) are used to describe a group item. Group level number is always 01.

Example

The following example shows Group and Elementary items −

DATA DIVISION.
WORKING-STORAGE SECTION.
01 WS-NAME    PIC X(25).                               ---> ELEMENTARY ITEM 
01 WS-CLASS   PIC 9(2)  VALUE   10 .                   ---> ELEMENTARY ITEM

01 WS-ADDRESS.                                         ---> GROUP ITEM   
   05 WS-HOUSE-NUMBER    PIC 9(3).                     ---> ELEMENTARY ITEM
   05 WS-STREET          PIC X(15).                    ---> ELEMENTARY ITEM
   05 WS-CITY            PIC X(15).                    ---> ELEMENTARY ITEM
   05 WS-COUNTRY         PIC X(15)  VALUE  INDIA .     ---> ELEMENTARY ITEM

Picture Clause

Picture clause is used to define the following items −

    Data type can be numeric, alphabetic, or alphanumeric. Numeric type consists of only digits 0 to 9. Alphabetic type consists of letters A to Z and spaces. Alphanumeric type consists of digits, letters, and special characters.

    Sign can be used with numeric data. It can be either + or –.

    Decimal point position can be used with numeric data. Assumed position is the position of decimal point and not included in the data.

    Length defines the number of bytes used by the data item.

Symbols used in a Picture clause −

Sr.No. Symbol & Description
1

9

Numeric

2

A

Alphabetic

3

X

Alphanumeric

4

V

Imppcit Decimal

5

S

Sign

6

P

Assumed Decimal

Example

The following example shows the use of PIC clause −

IDENTIFICATION DIVISION.
PROGRAM-ID. HELLO.

DATA DIVISION.
   WORKING-STORAGE SECTION.
   01 WS-NUM1 PIC S9(3)V9(2).
   01 WS-NUM2 PIC PPP999.
   01 WS-NUM3 PIC S9(3)V9(2) VALUE -123.45.
   01 WS-NAME PIC A(6) VALUE  ABCDEF .
   01 WS-ID PIC X(5) VALUE  A121$ .

PROCEDURE DIVISION.
   DISPLAY "WS-NUM1 : "WS-NUM1.
   DISPLAY "WS-NUM2 : "WS-NUM2.
   DISPLAY "WS-NUM3 : "WS-NUM3.
   DISPLAY "WS-NAME : "WS-NAME.
   DISPLAY "WS-ID : "WS-ID.
STOP RUN.

JCL to execute the above COBOL program −

//SAMPLE JOB(TESTJCL,XXXXXX),CLASS = A,MSGCLASS = C
//STEP1 EXEC PGM = HELLO

When you compile and execute the above program, it produces the following result −

WS-NUM1 : +000.00
WS-NUM2 : .000000
WS-NUM3 : -123.45
WS-NAME : ABCDEF
WS-ID : A121$

Value Clause

Value clause is an optional clause which is used to initiapze the data items. The values can be numeric pteral, alphanumeric pteral, or figurative constant. It can be used with both group and elementary items.

Example

The following example shows the use of VALUE clause −

IDENTIFICATION DIVISION.
PROGRAM-ID. HELLO.

DATA DIVISION.
   WORKING-STORAGE SECTION.
   01 WS-NUM1 PIC 99V9 VALUE IS 3.5.
   01 WS-NAME PIC A(6) VALUE  ABCD .
   01 WS-ID PIC 99 VALUE ZERO.

PROCEDURE DIVISION.
   DISPLAY "WS-NUM1 : "WS-NUM1.
   DISPLAY "WS-NAME : "WS-NAME.
   DISPLAY "WS-ID   : "WS-ID.
STOP RUN.

JCL to execute the above COBOL program −

//SAMPLE JOB(TESTJCL,XXXXXX),CLASS = A,MSGCLASS = C
//STEP1 EXEC PGM = HELLO

When you compile and execute the above program, it produces the following result −

WS-NUM1 : 03.5
WS-NAME : ABCD
WS-ID   : 00

COBOL - Basic Verbs

COBOL verbs are used in the procedure spanision for data processing. A statement always start with a COBOL verb. There are several COBOL verbs with different types of actions.

Input / Output Verbs

Input/Output verbs are used to get data from the user and display the output of COBOL programs. The following two verbs are used for this process −

Accept Verb

Accept verb is used to get data such as date, time, and day from the operating system or directly from the user. If a program is accepting data from the user, then it needs to be passed through JCL. While getting data from the operating system, FROM option is included as shown in the following example −

ACCEPT WS-STUDENT-NAME.
ACCEPT WS-DATE FROM SYSTEM-DATE.

Display Verb

Display verb is used to display the output of a COBOL program.

DISPLAY WS-STUDENT-NAME.
DISPLAY "System date is : " WS-DATE.

COBOL PROGRAM

IDENTIFICATION DIVISION.
PROGRAM-ID. HELLO.

DATA DIVISION.
   WORKING-STORAGE SECTION.
   01 WS-STUDENT-NAME PIC X(25).
   01 WS-DATE PIC X(10).

PROCEDURE DIVISION.
   ACCEPT WS-STUDENT-NAME.
   ACCEPT WS-DATE FROM DATE.
   DISPLAY "Name :  " WS-STUDENT-NAME.
   DISPLAY "Date : " WS-DATE.

STOP RUN.

JCL to execute the above COBOL program −

//SAMPLE JOB(TESTJCL,XXXXXX),CLASS = A,MSGCLASS = C
//STEP1 EXEC PGM = HELLO
//INPUT DD DSN=PROGRAM.DIRECTORY,DISP=SHR
//SYSIN DD *
TutorialsPoint
/*

When you compile and execute the above program, it produces the following result −

Name : TutorialsPoint
Date : 2014-08-30

Initiapze Verb

Initiapze verb is used to initiapze a group item or an elementary item. Data names with RENAME clause cannot be initiapzed. Numeric data items are replaced by ZEROES. Alphanumeric or alphabetic data items are replaced by SPACES. If we include REPLACING term, then data items can be initiapzed to the given replacing value as shown in the following example −

IDENTIFICATION DIVISION.
PROGRAM-ID. HELLO.

DATA DIVISION.
   WORKING-STORAGE SECTION.
   01 WS-NAME PIC A(30) VALUE  ABCDEF .
   01 WS-ID PIC 9(5).
   01 WS-ADDRESS. 
   05 WS-HOUSE-NUMBER PIC 9(3).
   05 WS-COUNTRY PIC X(15).
   05 WS-PINCODE PIC 9(6) VALUE 123456.

PROCEDURE DIVISION.
   A000-FIRST-PARA.
   INITIALIZE WS-NAME, WS-ADDRESS.
   INITIALIZE WS-ID REPLACING NUMERIC DATA BY 12345.
   DISPLAY "My name is   : "WS-NAME.
   DISPLAY "My ID is     : "WS-ID.
   DISPLAY "Address      : "WS-ADDRESS.
   DISPLAY "House Number : "WS-HOUSE-NUMBER.
   DISPLAY "Country      : "WS-COUNTRY.
   DISPLAY "Pincode      : "WS-PINCODE.

STOP RUN.

JCL to execute the above COBOL program −

//SAMPLE JOB(TESTJCL,XXXXXX),CLASS = A,MSGCLASS = C
//STEP1 EXEC PGM = HELLO

When you compile and execute the above program, it produces the following result −

My name is   :                               
My ID is     : 12345
Address      : 000               000000
House Number : 000
Country      :                
Pincode      : 000000

Move Verb

Move verb is used to copy data from source data to destination data. It can be used on both elementary and group data items. For group data items, MOVE CORRESPONDING/CORR is used. In try it option, MOVE CORR is not working; but on a mainframe server, it will work.

For moving data from a string, MOVE(x:l) is used where x is the starting position and l is the length. Data will be truncated if the destination data item PIC clause is less than the source data item PIC clause. If the destination data item PIC clause is more than the source data item PIC clause, then ZEROS or SPACES will be added in the extra bytes. The following example makes it clear.

IDENTIFICATION DIVISION.
PROGRAM-ID. HELLO.

DATA DIVISION.
   WORKING-STORAGE SECTION.
   01 WS-NUM1 PIC 9(9).
   01 WS-NUM2 PIC 9(9).
   01 WS-NUM3 PIC 9(5).
   01 WS-NUM4 PIC 9(6).
   01 WS-ADDRESS. 
   05 WS-HOUSE-NUMBER PIC 9(3).
   05 WS-COUNTRY PIC X(5).
   05 WS-PINCODE PIC 9(6).
   01 WS-ADDRESS1. 
   05 WS-HOUSE-NUMBER1 PIC 9(3).
   05 WS-COUNTRY1 PIC X(5).
   05 WS-PINCODE1 PIC 9(6).

PROCEDURE DIVISION.
   A000-FIRST-PARA.
   MOVE 123456789 TO WS-NUM1.
   MOVE WS-NUM1 TO WS-NUM2 WS-NUM3.
   MOVE WS-NUM1(3:6) TO WS-NUM4.
   MOVE 123 TO WS-HOUSE-NUMBER.
   MOVE  INDIA  TO WS-COUNTRY.
   MOVE 112233 TO WS-PINCODE.
   MOVE WS-ADDRESS TO WS-ADDRESS1.

   DISPLAY "WS-NUM1     : " WS-NUM1
   DISPLAY "WS-NUM2     : " WS-NUM2
   DISPLAY "WS-NUM3     : " WS-NUM3
   DISPLAY "WS-NUM4     : " WS-NUM4
   DISPLAY "WS-ADDRESS  : " WS-ADDRESS
   DISPLAY "WS-ADDRESS1 : " WS-ADDRESS1

STOP RUN.

JCL to execute the above COBOL program.

//SAMPLE JOB(TESTJCL,XXXXXX),CLASS = A,MSGCLASS = C
//STEP1 EXEC PGM = HELLO

When you compile and execute the above program, it produces the following result −

WS-NUM1     : 123456789
WS-NUM2     : 123456789
WS-NUM3     : 56789
WS-NUM4     : 345678
WS-ADDRESS  : 123INDIA112233
WS-ADDRESS1 : 123INDIA112233

Legal Moves

The following table gives information about the legal moves −

Alphabetic Alphanumeric Numeric
Alphabetic Possible Possible Not Possible
Alphanumeric Possible Possible Possible
Numeric Not Possible Possible Possible

Add Verb

Add verb is used to add two or more numbers and store the result in the destination operand.

Syntax

Given below is the syntax to Add two or more numbers −

ADD A B TO C D

ADD A B C TO D GIVING E

ADD CORR WS-GROUP1 TO WS-GROUP2

In syntax-1, A, B, C are added and the result is stored in C (C=A+B+C). A, B, D are added and the result is stored in D (D = A + B + D).

In syntax-2, A, B, C, D are added and the result is stored in E (E=A+B+C+D).

In syntax-3, sub-group items within WS-GROUP1 and WS-GROUP2 are added and the result is stored in WS-GROUP2.

Example

IDENTIFICATION DIVISION.
PROGRAM-ID. HELLO.

DATA DIVISION.
   WORKING-STORAGE SECTION.
   01 WS-NUM1 PIC 9(9) VALUE 10 .
   01 WS-NUM2 PIC 9(9) VALUE 10.
   01 WS-NUM3 PIC 9(9) VALUE 10.
   01 WS-NUM4 PIC 9(9) VALUE 10.
   01 WS-NUMA PIC 9(9) VALUE 10.
   01 WS-NUMB PIC 9(9) VALUE 10.
   01 WS-NUMC PIC 9(9) VALUE 10.
   01 WS-NUMD PIC 9(9) VALUE 10.
   01 WS-NUME PIC 9(9) VALUE 10.

PROCEDURE DIVISION.
   ADD WS-NUM1 WS-NUM2 TO WS-NUM3 WS-NUM4.
   ADD WS-NUMA WS-NUMB WS-NUMC TO WS-NUMD GIVING WS-NUME.
   DISPLAY "WS-NUM1     : " WS-NUM1
   DISPLAY "WS-NUM2     : " WS-NUM2
   DISPLAY "WS-NUM3     : " WS-NUM3
   DISPLAY "WS-NUM4     : " WS-NUM4
   DISPLAY "WS-NUMA     : " WS-NUMA
   DISPLAY "WS-NUMB     : " WS-NUMB
   DISPLAY "WS-NUMC     : " WS-NUMC
   DISPLAY "WS-NUMD     : " WS-NUMD
   DISPLAY "WS-NUME     : " WS-NUME

STOP RUN.

JCL to execute the above COBOL program −

//SAMPLE JOB(TESTJCL,XXXXXX),CLASS = A,MSGCLASS = C
//STEP1 EXEC PGM = HELLO

When you compile and execute the above program, it produces the following result −

WS-NUM1     : 000000010
WS-NUM2     : 000000010
WS-NUM3     : 000000030
WS-NUM4     : 000000030
WS-NUMA     : 000000010
WS-NUMB     : 000000010
WS-NUMC     : 000000010
WS-NUMD     : 000000010
WS-NUME     : 000000040

Subtract Verb

Subtract verb is used for subtraction operations.

Syntax

Given below is the syntax for Subtract operations −

SUBTRACT A B FROM C D

SUBTRACT A B C FROM D GIVING E

SUBTRACT CORR WS-GROUP1 TO WS-GROUP2

In syntax-1, A and B are added and subtracted from C. The result is stored in C (C = C-(A+B)). A and B are added and subtracted from D. The result is stored in D (D = D-(A+B)).

In syntax-2, A, B, C are added and subtracted from D. The result is stored in E (E = D-(A+B+C))

In syntax-3, sub-group items within WS-GROUP1 and WS-GROUP2 are subtracted and the result is stored in WS-GROUP2.

Example

IDENTIFICATION DIVISION.
PROGRAM-ID. HELLO.

DATA DIVISION.
   WORKING-STORAGE SECTION.
   01 WS-NUM1 PIC 9(9) VALUE 10 .
   01 WS-NUM2 PIC 9(9) VALUE 10.
   01 WS-NUM3 PIC 9(9) VALUE 100.
   01 WS-NUM4 PIC 9(9) VALUE 100.
   01 WS-NUMA PIC 9(9) VALUE 10.
   01 WS-NUMB PIC 9(9) VALUE 10.
   01 WS-NUMC PIC 9(9) VALUE 10.
   01 WS-NUMD PIC 9(9) VALUE 100.
   01 WS-NUME PIC 9(9) VALUE 10.

PROCEDURE DIVISION.
   SUBTRACT WS-NUM1 WS-NUM2 FROM WS-NUM3 WS-NUM4.
   SUBTRACT WS-NUMA WS-NUMB WS-NUMC FROM WS-NUMD GIVING WS-NUME.

   DISPLAY "WS-NUM1     : " WS-NUM1
   DISPLAY "WS-NUM2     : " WS-NUM2
   DISPLAY "WS-NUM3     : " WS-NUM3
   DISPLAY "WS-NUM4     : " WS-NUM4
   DISPLAY "WS-NUMA     : " WS-NUMA
   DISPLAY "WS-NUMB     : " WS-NUMB
   DISPLAY "WS-NUMC     : " WS-NUMC
   DISPLAY "WS-NUMD     : " WS-NUMD
   DISPLAY "WS-NUME     : " WS-NUME

STOP RUN.

JCL to execute the above COBOL program −

//SAMPLE JOB(TESTJCL,XXXXXX),CLASS = A,MSGCLASS = C
//STEP1 EXEC PGM = HELLO

When you compile and execute the above program, it produces the following result −

WS-NUM1     : 000000010
WS-NUM2     : 000000010
WS-NUM3     : 000000080
WS-NUM4     : 000000080
WS-NUMA     : 000000010
WS-NUMB     : 000000010
WS-NUMC     : 000000010
WS-NUMD     : 000000100
WS-NUME     : 000000070

Multiply Verb

Multiply verb is used for multippcation operations.

Syntax

Given below is the syntax to multiply two or more numbers −

MULTIPLY A BY B C

MULTIPLY A BY B GIVING E

In syntax-1, A and B are multipled and the result is stored in B (B=A*B). A and C are multipled and the result is stored in C (C = A * C).

In syntax-2, A and B are multipled and the result is stored in E (E=A*B).

Example

IDENTIFICATION DIVISION.
PROGRAM-ID. HELLO.

DATA DIVISION.
   WORKING-STORAGE SECTION.
   01 WS-NUM1 PIC 9(9) VALUE 10 .
   01 WS-NUM2 PIC 9(9) VALUE 10.
   01 WS-NUM3 PIC 9(9) VALUE 10.
   01 WS-NUMA PIC 9(9) VALUE 10.
   01 WS-NUMB PIC 9(9) VALUE 10.
   01 WS-NUMC PIC 9(9) VALUE 10.

PROCEDURE DIVISION.
   MULTIPLY WS-NUM1 BY WS-NUM2 WS-NUM3.
   MULTIPLY WS-NUMA BY WS-NUMB GIVING WS-NUMC.
   
   DISPLAY "WS-NUM1     : " WS-NUM1
   DISPLAY "WS-NUM2     : " WS-NUM2
   DISPLAY "WS-NUM3     : " WS-NUM3
   DISPLAY "WS-NUMA     : " WS-NUMA
   DISPLAY "WS-NUMB     : " WS-NUMB
   DISPLAY "WS-NUMC     : " WS-NUMC
   
STOP RUN.

JCL to execute the above COBOL program −

//SAMPLE JOB(TESTJCL,XXXXXX),CLASS = A,MSGCLASS = C
//STEP1 EXEC PGM = HELLO

When you compile and execute the above program, it produces the following result −

WS-NUM1     : 000000010
WS-NUM2     : 000000100
WS-NUM3     : 000000100
WS-NUMA     : 000000010
WS-NUMB     : 000000010
WS-NUMC     : 000000100

Divide Verb

Divide verb is used for spanision operations.

Syntax

Given below is the syntax for spanision operations −

DIVIDE A INTO B

DIVIDE A BY B GIVING C REMAINDER R

In syntax-1, B is spanided by A and the result is stored in B (B=B/A).

In syntax-2, A is spanided by B and the result is stored in C (C=A/B) and the remainder is stored in R.

Example

IDENTIFICATION DIVISION.
PROGRAM-ID. HELLO.

DATA DIVISION.
   WORKING-STORAGE SECTION.
   01 WS-NUM1 PIC 9(9) VALUE 5.
   01 WS-NUM2 PIC 9(9) VALUE 250.
   01 WS-NUMA PIC 9(9) VALUE 100.
   01 WS-NUMB PIC 9(9) VALUE 15.
   01 WS-NUMC PIC 9(9).
   01 WS-REM PIC 9(9). 

PROCEDURE DIVISION.
   DIVIDE WS-NUM1 INTO WS-NUM2.
   DIVIDE WS-NUMA BY WS-NUMB GIVING WS-NUMC REMAINDER WS-REM.
   DISPLAY "WS-NUM1     : " WS-NUM1
   DISPLAY "WS-NUM2     : " WS-NUM2
   DISPLAY "WS-NUMA     : " WS-NUMA
   DISPLAY "WS-NUMB     : " WS-NUMB
   DISPLAY "WS-NUMC     : " WS-NUMC
   DISPLAY "WS-REM      : " WS-REM
   
STOP RUN.

JCL to execute the above COBOL program −

//SAMPLE JOB(TESTJCL,XXXXXX),CLASS = A,MSGCLASS = C
//STEP1 EXEC PGM = HELLO

When you compile and execute the above program, it produces the following result −

WS-NUM1     : 000000005
WS-NUM2     : 000000050
WS-NUMA     : 000000100
WS-NUMB     : 000000015
WS-NUMC     : 000000006
WS-REM      : 000000010

Compute Statement

Compute statement is used to write arithmetic expressions in COBOL. This is a replacement for Add, Subtract, Multiply, and Divide.

Example

IDENTIFICATION DIVISION.
PROGRAM-ID. HELLO.

DATA DIVISION.
   WORKING-STORAGE SECTION.
   01 WS-NUM1 PIC 9(9) VALUE 10 .
   01 WS-NUM2 PIC 9(9) VALUE 10.
   01 WS-NUM3 PIC 9(9) VALUE 10.
   01 WS-NUMA PIC 9(9) VALUE 50.
   01 WS-NUMB PIC 9(9) VALUE 10.
   01 WS-NUMC PIC 9(9).

PROCEDURE DIVISION.
   COMPUTE WS-NUMC= (WS-NUM1 * WS-NUM2) - (WS-NUMA / WS-NUMB) + WS-NUM3.
   DISPLAY "WS-NUM1     : " WS-NUM1
   DISPLAY "WS-NUM2     : " WS-NUM2
   DISPLAY "WS-NUM3     : " WS-NUM3
   DISPLAY "WS-NUMA     : " WS-NUMA
   DISPLAY "WS-NUMB     : " WS-NUMB
   DISPLAY "WS-NUMC     : " WS-NUMC

STOP RUN.

JCL to execute the above COBOL program.

//SAMPLE JOB(TESTJCL,XXXXXX),CLASS = A,MSGCLASS = C
//STEP1 EXEC PGM = HELLO

When you compile and execute the above program, it produces the following result −

WS-NUM1     : 000000010
WS-NUM2     : 000000010
WS-NUM3     : 000000010
WS-NUMA     : 000000050
WS-NUMB     : 000000010
WS-NUMC     : 000000105

COBOL - Data Layout

COBOL layout is the description of use of each field and the values present in it. Following are the data description entries used in COBOL −

    Redefines Clause

    Renames Clause

    Usage Clause

    Copybooks

Redefines Clause

Redefines clause is used to define a storage with different data description. If one or more data items are not used simultaneously, then the same storage can be utipzed for another data item. So the same storage can be referred with different data items.

Syntax

Following is the syntax for Redefines clause −

01 WS-OLD PIC X(10).
01 WS-NEW1 REDEFINES WS-OLD PIC 9(8).
01 WS-NEW2 REDEFINES WS-OLD PIC A(10).

Following are the details of the used parameters −

    WS-OLD is Redefined Item

    WS-NEW1 and WS-NEW2 are Redefining Item

Level numbers of redefined item and redefining item must be the same and it cannot be 66 or 88 level number. Do not use VALUE clause with a redefining item. In File Section, do not use a redefines clause with 01 level number. Redefines definition must be the next data description you want to redefine. A redefining item will always have the same value as a redefined item.

Example

IDENTIFICATION DIVISION.
PROGRAM-ID. HELLO.

DATA DIVISION.
   WORKING-STORAGE SECTION.
   01 WS-DESCRIPTION.
   05 WS-DATE1 VALUE  20140831 .
   10 WS-YEAR PIC X(4).
   10 WS-MONTH PIC X(2).
   10 WS-DATE PIC X(2).
   05 WS-DATE2 REDEFINES WS-DATE1 PIC 9(8).

PROCEDURE DIVISION.
   DISPLAY "WS-DATE1 : "WS-DATE1.
   DISPLAY "WS-DATE2 : "WS-DATE2.

STOP RUN.

JCL to execute the above COBOL program −

//SAMPLE JOB(TESTJCL,XXXXXX),CLASS = A,MSGCLASS = C
//STEP1 EXEC PGM = HELLO

When you compile and execute the above program it produces the following result −

WS-DATE1 : 20140831
WS-DATE2 : 20140831

Renames Clause

Renames clause is used to give different names to existing data items. It is used to re-group the data names and give a new name to them. The new data names can rename across groups or elementary items. Level number 66 is reserved for renames.

Syntax

Following is the syntax for Renames clause −

01 WS-OLD.
10 WS-A PIC 9(12).
10 WS-B PIC X(20).
10 WS-C PIC A(25).
10 WS-D PIC X(12).
66 WS-NEW RENAMES WS-A THRU WS-C.

Renaming is possible at same level only. In the above example, WS-A, WS-B, and WS-C are at the same level. Renames definition must be the next data description you want to rename. Do not use Renames with 01, 77, or 66 level number. The data names used for renames must come in sequence. Data items with occur clause cannot be renamed.

Example

IDENTIFICATION DIVISION.
PROGRAM-ID. HELLO.

DATA DIVISION.
   WORKING-STORAGE SECTION.
   01 WS-DESCRIPTION.
   05 WS-NUM.
   10 WS-NUM1 PIC 9(2) VALUE 20.
   10 WS-NUM2 PIC 9(2) VALUE 56.
   05 WS-CHAR.
   10 WS-CHAR1 PIC X(2) VALUE  AA .
   10 WS-CHAR2 PIC X(2) VALUE  BB .
   66 WS-RENAME RENAMES WS-NUM2 THRU WS-CHAR2.

PROCEDURE DIVISION.
   DISPLAY "WS-RENAME : " WS-RENAME.
   
STOP RUN.

JCL to execute the above COBOL program −

//SAMPLE JOB(TESTJCL,XXXXXX),CLASS = A,MSGCLASS = C
//STEP1 EXEC PGM = HELLO

When you compile and execute the above program, it produces the following result −

WS-RENAME : 56AABB

Usage Clause

Usage clause specifies the operating system in which the format data is stored. It cannot be used with level numbers 66 or 88. If usage clause is specified on a group, then all the elementary items will have the same usage clause. The different options available with Usage clause are as follows −

Display

Data item is stored in ASCII format and each character will take 1 byte. It is default usage.

The following example calculates the number of bytes required −

01 WS-NUM PIC S9(5)V9(3) USAGE IS DISPLAY.
It requires 8 bytes as sign and decimal doesn t require any byte.

01 WS-NUM PIC 9(5) USAGE IS DISPLAY.
It requires 5 bytes as sign.

COMPUTATIONAL / COMP

Data item is stored in binary format. Here, data items must be integer.

The following example calculates the number of bytes required −

01 WS-NUM PIC S9(n) USAGE IS COMP.

If  n  = 1 to 4, it takes 2 bytes.
If  n  = 5 to 9, it takes 4 bytes.
If  n  = 10 to 18, it takes 8 bytes.

COMP-1

Data item is similar to Real or Float and is represented as a single precision floating point number. Internally, data is stored in hexadecimal format. COMP-1 does not accept PIC clause. Here 1 word is equal to 4 bytes.

COMP-2

Data item is similar to Long or Double and is represented as double precision floating point number. Internally, data is stored in hexadecimal format. COMP-2 does not specify PIC clause. Here 2 word is equal to 8 bytes.

COMP-3

Data item is stored in packed decimal format. Each digit occupies half a byte (1 nibble) and the sign is stored at the rightmost nibble.

The following example calculates the number of bytes required −

01 WS-NUM PIC 9(n) USAGE IS COMP.
Number of bytes = n/2 (If n is even)
Number of bytes = n/2 + 1(If n is odd, consider only integer part)

01 WS-NUM PIC 9(4) USAGE IS COMP-3 VALUE 21.
It requires 2 bytes of storage as each digit occupies half a byte.

01 WS-NUM PIC 9(5) USAGE IS COMP-3 VALUE 21.
It requires 3 bytes of storage as each digit occupies half a byte.

Copybooks

A COBOL copybook is a selection of code that defines data structures. If a particular data structure is used in many programs, then instead of writing the same data structure again, we can use copybooks. We use the COPY statement to include a copybook in a program. COPY statement is used in the WorkingStorage Section.

The following example includes a copybook inside a COBOL program −

DATA DIVISION.
WORKING-STORAGE SECTION.
COPY ABC.

Here ABC is the copybook name. The following data items in ABC copybook can be used inside a program.

01 WS-DESCRIPTION.
   05 WS-NUM.
      10 WS-NUM1 PIC 9(2) VALUE 20.
      10 WS-NUM2 PIC 9(2) VALUE 56.
   05 WS-CHAR.
      10 WS-CHAR1 PIC X(2) VALUE  AA .
      10 WS-CHAR2 PIC X(2) VALUE  BB .

COBOL - Conditional Statements

Conditional statements are used to change the execution flow depending on certain conditions specified by the programmer. Conditional statements will always evaluate to true or false. Conditions are used in IF, Evaluate, and Perform statements. The different types of conditions are as follows −

    IF Condition Statement

    Relation Condition

    Sign Condition

    Class Condition

    Condition-Name Condition

    Negated Condition

    Combined Condition

IF Condition Statement

IF statement checks for conditions. If a condition is true, the IF block is executed; and if the condition is false, the ELSE block is executed.

END-IF is used to end the IF block. To end the IF block, a period can be used instead of END-IF. But it is always preferable to use END-IF for multiple IF blocks.

Nested-IF − IF blocks appearing inside another IF block. There is no pmit to the depth of nested IF statements.

Syntax

Following is the syntax of IF condition statements −

IF [condition] THEN
   [COBOL statements]
ELSE
   [COBOL statements]
END-IF.

Example

IDENTIFICATION DIVISION.
PROGRAM-ID. HELLO.

DATA DIVISION.
   WORKING-STORAGE SECTION.
   01 WS-NUM1 PIC 9(9).
   01 WS-NUM2 PIC 9(9).
   01 WS-NUM3 PIC 9(5).
   01 WS-NUM4 PIC 9(6).

PROCEDURE DIVISION.
   A000-FIRST-PARA.
   MOVE 25 TO WS-NUM1 WS-NUM3.
   MOVE 15 TO WS-NUM2 WS-NUM4.
   
   IF WS-NUM1 > WS-NUM2 THEN
      DISPLAY  IN LOOP 1 - IF BLOCK 
      
      IF WS-NUM3 = WS-NUM4 THEN
         DISPLAY  IN LOOP 2 - IF BLOCK 
      ELSE
         DISPLAY  IN LOOP 2 - ELSE BLOCK 
      END-IF
      
   ELSE
      DISPLAY  IN LOOP 1 - ELSE BLOCK 
   END-IF.
   
STOP RUN.

JCL to execute the above COBOL program −

//SAMPLE JOB(TESTJCL,XXXXXX),CLASS = A,MSGCLASS = C
//STEP1 EXEC PGM = HELLO

When you compile and execute the above program, it produces the following result −

IN LOOP 1 - IF BLOCK
IN LOOP 2 - ELSE BLOCK

Relation Condition

Relation condition compares two operands, either of which can be an identifier, pteral, or arithmetic expression. Algebraic comparison of numeric fields is done regardless of size and usage clause.

For non-numeric operands

If two non-numeric operands of equal size are compared, then the characters are compared from left with the corresponding positions till the end is reached. The operand containing greater number of characters is declared greater.

If two non-numeric operands of unequal size are compared, then the shorter data item is appended with spaces at the end till the size of the operands becomes equal and then compared according to the rules mentioned in the previous point.

Syntax

Given below is the syntax of Relation condition statements −

[Data Name/Arithmetic Operation]

   [IS] [NOT] 

[Equal to (=),Greater than (>), Less than (<), 
Greater than or Equal (>=), Less than or equal (<=) ]

[Data Name/Arithmetic Operation] 

Example

IDENTIFICATION DIVISION.
PROGRAM-ID. HELLO.

DATA DIVISION.
   WORKING-STORAGE SECTION.
   01 WS-NUM1 PIC 9(9).
   01 WS-NUM2 PIC 9(9).

PROCEDURE DIVISION.
   A000-FIRST-PARA.
   MOVE 25 TO WS-NUM1.
   MOVE 15 TO WS-NUM2.
   
   IF WS-NUM1 IS GREATER THAN OR EQUAL TO WS-NUM2 THEN
      DISPLAY  WS-NUM1 IS GREATER THAN WS-NUM2 
   ELSE
      DISPLAY  WS-NUM1 IS LESS THAN WS-NUM2 
   END-IF.
   
STOP RUN.

JCL to execute the above COBOL program −

//SAMPLE JOB(TESTJCL,XXXXXX),CLASS = A,MSGCLASS = C
//STEP1 EXEC PGM = HELLO

When you compile and execute the above program it produces the following result −

WS-NUM1 IS GREATER THAN WS-NUM2

Sign Condition

Sign condition is used to check the sign of a numeric operand. It determines whether a given numeric value is greater than, less than, or equal to ZERO.

Syntax

Following is the syntax of Sign condition statements −

[Data Name/Arithmetic Operation] 

   [IS] [NOT] 

[Positive, Negative or Zero]

[Data Name/Arithmetic Operation]

Example

IDENTIFICATION DIVISION.
PROGRAM-ID. HELLO.

DATA DIVISION.
   WORKING-STORAGE SECTION.
   01 WS-NUM1 PIC S9(9) VALUE -1234.
   01 WS-NUM2 PIC S9(9) VALUE 123456.

PROCEDURE DIVISION.
   A000-FIRST-PARA.
   IF WS-NUM1 IS POSITIVE THEN
      DISPLAY  WS-NUM1 IS POSITIVE .
      
   IF WS-NUM1 IS NEGATIVE THEN
      DISPLAY  WS-NUM1 IS NEGATIVE .
      
   IF WS-NUM1 IS ZERO THEN
      DISPLAY  WS-NUM1 IS ZERO .
      
   IF WS-NUM2 IS POSITIVE THEN
      DISPLAY  WS-NUM2 IS POSITIVE .

STOP RUN.

JCL to execute the above COBOL program −

//SAMPLE JOB(TESTJCL,XXXXXX),CLASS = A,MSGCLASS = C
//STEP1 EXEC PGM = HELLO

When you compile and execute the above program it produces the following result −

WS-NUM1 IS NEGATIVE
WS-NUM2 IS POSITIVE

Class Condition

Class condition is used to check if an operand contains only alphabets or numeric data. Spaces are considered in ALPHABETIC, ALPHABETIC-LOWER, and ALPHABETIC-UPPER.

Syntax

Following is the syntax of Class condition statements −

[Data Name/Arithmetic Operation>]

   [IS] [NOT] 

[NUMERIC, ALPHABETIC, ALPHABETIC-LOWER, ALPHABETIC-UPPER]

[Data Name/Arithmetic Operation]

Example

IDENTIFICATION DIVISION.
PROGRAM-ID. HELLO.

DATA DIVISION.
   WORKING-STORAGE SECTION.
   01 WS-NUM1 PIC X(9) VALUE  ABCD  .
   01 WS-NUM2 PIC 9(9) VALUE 123456789.

PROCEDURE DIVISION.
   A000-FIRST-PARA.
   
   IF WS-NUM1 IS ALPHABETIC THEN
      DISPLAY  WS-NUM1 IS ALPHABETIC .
      
   IF WS-NUM1 IS NUMERIC THEN
      DISPLAY  WS-NUM1 IS NUMERIC .
      
   IF WS-NUM2 IS NUMERIC THEN
      DISPLAY  WS-NUM2 IS NUMERIC .
   
STOP RUN.

JCL to execute the above COBOL program −

//SAMPLE JOB(TESTJCL,XXXXXX),CLASS = A,MSGCLASS = C
//STEP1 EXEC PGM = HELLO

When you compile and execute the above program, it produces the following result −

WS-NUM1 IS ALPHABETIC
WS-NUM2 IS NUMERIC

Condition-name Condition

A condition-name is a user-defined name. It contains a set of values specified by the user. It behaves pke Boolean variables. They are defined with level number 88. It will not have a PIC clause.

Syntax

Following is the syntax of user-defined condition statements −

88 [Condition-Name] VALUE [IS, ARE] [LITERAL] [THRU LITERAL].

Example

IDENTIFICATION DIVISION.
PROGRAM-ID. HELLO.

DATA DIVISION.
   WORKING-STORAGE SECTION.
   01 WS-NUM PIC 9(3).
   88 PASS VALUES ARE 041 THRU 100.
   88 FAIL VALUES ARE 000 THRU 40.

PROCEDURE DIVISION.
   A000-FIRST-PARA.
   MOVE 65 TO WS-NUM.
   
   IF PASS 
      DISPLAY  Passed with   WS-NUM   marks .
      
   IF FAIL 
      DISPLAY  FAILED with   WS-NUM  marks .
      
STOP RUN.

JCL to execute the above COBOL program −

//SAMPLE JOB(TESTJCL,XXXXXX),CLASS = A,MSGCLASS = C
//STEP1 EXEC PGM = HELLO

When you compile and execute the above program, it produces the following result −

Passed with 065 marks

Negated Condition

Negated condition is given by using the NOT keyword. If a condition is true and we have given NOT in front of it, then its final value will be false.

Syntax

Following is the syntax of Negated condition statements −

IF NOT [CONDITION] 
   COBOL Statements
END-IF.

Example

IDENTIFICATION DIVISION.
PROGRAM-ID. HELLO.

DATA DIVISION.
   WORKING-STORAGE SECTION.
   01 WS-NUM1 PIC 9(2) VALUE 20.
   01 WS-NUM2 PIC 9(9) VALUE 25.

PROCEDURE DIVISION.
   A000-FIRST-PARA.
   
   IF NOT WS-NUM1 IS LESS THAN WS-NUM2 THEN
      DISPLAY  IF-BLOCK 
   ELSE
      DISPLAY  ELSE-BLOCK 
   END-IF.
   
STOP RUN.

JCL to execute the above COBOL program −

//SAMPLE JOB(TESTJCL,XXXXXX),CLASS = A,MSGCLASS = C
//STEP1 EXEC PGM = HELLO

When you compile and execute the above program, it produces the following result −

ELSE-BLOCK

Combined Condition

A combined condition contains two or more conditions connected using logical operators AND or OR.

Syntax

Following is the syntax of combined condition statements −

IF [CONDITION] AND [CONDITION]
   COBOL Statements
END-IF.

Example

IDENTIFICATION DIVISION.
PROGRAM-ID. HELLO.

DATA DIVISION.
   WORKING-STORAGE SECTION.
   01 WS-NUM1 PIC 9(2) VALUE 20.
   01 WS-NUM2 PIC 9(2) VALUE 25.
   01 WS-NUM3 PIC 9(2) VALUE 20.

PROCEDURE DIVISION.
   A000-FIRST-PARA.
   
   IF WS-NUM1 IS LESS THAN WS-NUM2 AND WS-NUM1=WS-NUM3 THEN
      DISPLAY  Both condition OK 
   ELSE
      DISPLAY  Error 
   END-IF.
   
STOP RUN.

JCL to execute the above COBOL program −

//SAMPLE JOB(TESTJCL,XXXXXX),CLASS = A,MSGCLASS = C
//STEP1 EXEC PGM = HELLO

When you compile and execute the above program, it produces the following result −

Both condition OK

Evaluate Verb

Evaluate verb is a replacement of series of IF-ELSE statement. It can be used to evaluate more than one condition. It is similar to SWITCH statement in C programs.

Example

IDENTIFICATION DIVISION.
PROGRAM-ID. HELLO.

DATA DIVISION.
   WORKING-STORAGE SECTION.
   01 WS-A PIC 9 VALUE 0.
   
PROCEDURE DIVISION.
   MOVE 3 TO WS-A.
   
   EVALUATE TRUE
      WHEN WS-A > 2
         DISPLAY  WS-A GREATER THAN 2 

      WHEN WS-A < 0
         DISPLAY  WS-A LESS THAN 0 

      WHEN OTHER
         DISPLAY  INVALID VALUE OF WS-A 
   END-EVALUATE.
   
STOP RUN.

JCL to execute the above COBOL program −

//SAMPLE JOB(TESTJCL,XXXXXX),CLASS = A,MSGCLASS = C
//STEP1 EXEC PGM = HELLO

When you compile and execute the above program, it produces the following result −

WS-A GREATER THAN 2

COBOL - Loop Statements

There are some tasks that need to be done over and over again pke reading each record of a file till its end. The loop statements used in COBOL are −

    Perform Thru

    Perform Until

    Perform Times

    Perform Varying

Perform Thru

Perform Thru is used to execute a series of paragraph by giving the first and last paragraph names in the sequence. After executing the last paragraph, the control is returned back.

In-pne Perform

Statements inside the PERFORM will be executed till END-PERFORM is reached.

Syntax

Following is the syntax of In-pne perform −

PERFORM 
   DISPLAY  HELLO WORLD 
END-PERFORM.

Out-of-pne Perform

Here, a statement is executed in one paragraph and then the control is transferred to other paragraph or section.

Syntax

Following is the syntax of Out-of-pne perform −

PERFORM PARAGRAPH1 THRU PARAGRAPH2

Example

IDENTIFICATION DIVISION.
PROGRAM-ID. HELLO.

PROCEDURE DIVISION.
   A-PARA.
   PERFORM DISPLAY  IN A-PARA 
   END-PERFORM.
   PERFORM C-PARA THRU E-PARA.
   
   B-PARA.
   DISPLAY  IN B-PARA .
   STOP RUN.
   
   C-PARA.
   DISPLAY  IN C-PARA .
   
   D-PARA.
   DISPLAY  IN D-PARA .
   
   E-PARA.
   DISPLAY  IN E-PARA .

JCL to execute the above COBOL program.

//SAMPLE JOB(TESTJCL,XXXXXX),CLASS = A,MSGCLASS = C
//STEP1 EXEC PGM = HELLO

When you compile and execute the above program, it produces the following result −

IN A-PARA
IN C-PARA
IN D-PARA
IN E-PARA
IN B-PARA

Perform Until

In ‘perform until’, a paragraph is executed until the given condition becomes true. ‘With test before’ is the default condition and it indicates that the condition is checked before the execution of statements in a paragraph.

Syntax

Following is the syntax of perform until −

PERFORM A-PARA UNTIL COUNT=5

PERFORM A-PARA WITH TEST BEFORE UNTIL COUNT=5

PERFORM A-PARA WITH TEST AFTER UNTIL COUNT=5

Example

IDENTIFICATION DIVISION.
PROGRAM-ID. HELLO.

DATA DIVISION.
   WORKING-STORAGE SECTION.
   01 WS-CNT PIC 9(1) VALUE 0. 

PROCEDURE DIVISION.
   A-PARA.
   PERFORM B-PARA WITH TEST AFTER UNTIL WS-CNT>3.
   STOP RUN.
   
   B-PARA.
   DISPLAY  WS-CNT :  WS-CNT.
   ADD 1 TO WS-CNT.

JCL to execute the above COBOL program −

//SAMPLE JOB(TESTJCL,XXXXXX),CLASS = A,MSGCLASS = C
//STEP1 EXEC PGM = HELLO

When you compile and execute the above program, it produces the following result −

WS-CNT : 0
WS-CNT : 1
WS-CNT : 2
WS-CNT : 3

Perform Times

In ‘perform times’, a paragraph will be executed the number of times specified.

Syntax

Following is the syntax of perform times −

PERFORM A-PARA 5 TIMES.

Example

IDENTIFICATION DIVISION.
PROGRAM-ID. HELLO.

PROCEDURE DIVISION.
   A-PARA.
   PERFORM B-PARA 3 TIMES.
   STOP RUN.
   
   B-PARA.
   DISPLAY  IN B-PARA .

JCL to execute the above COBOL program −

//SAMPLE JOB(TESTJCL,XXXXXX),CLASS = A,MSGCLASS = C
//STEP1 EXEC PGM = HELLO

When you compile and execute the above program, it produces the following result −

IN B-PARA
IN B-PARA
IN B-PARA

Perform Varying

In perform varying, a paragraph will be executed till the condition in Until phrase becomes true.

Syntax

Following is the syntax of perform varying −

PERFORM A-PARA VARYING A FROM 1 BY 1 UNTIL A = 5.

Example

IDENTIFICATION DIVISION.
PROGRAM-ID. HELLO.

DATA DIVISION.
   WORKING-STORAGE SECTION.
   01 WS-A PIC 9 VALUE 0.

PROCEDURE DIVISION.
   A-PARA.
   PERFORM B-PARA VARYING WS-A FROM 1 BY 1 UNTIL WS-A=5
   STOP RUN.
   
   B-PARA.
   DISPLAY  IN B-PARA   WS-A.

JCL to execute the above COBOL program −

//SAMPLE JOB(TESTJCL,XXXXXX),CLASS = A,MSGCLASS = C
//STEP1 EXEC PGM = HELLO

When you compile and execute the above program, it produces the following result −

IN B-PARA 1
IN B-PARA 2
IN B-PARA 3
IN B-PARA 4

GO TO Statement

GO TO statement is used to change the flow of execution in a program. In GO TO statements, transfer goes only in the forward direction. It is used to exit a paragraph. The different types of GO TO statements used are as follows −

Unconditional GO TO

GO TO para-name.

Conditional GO TO

GO TO para-1 para-2 para-3 DEPENDING ON x.

If x is equal to 1, then the control will be transferred to the first paragraph; and if x is equal to 2, then the control will be transferred to the second paragraph, and so on.

Example

IDENTIFICATION DIVISION.
PROGRAM-ID. HELLO.

DATA DIVISION.
   WORKING-STORAGE SECTION.
   01 WS-A PIC 9 VALUE 2.
   
PROCEDURE DIVISION.
   A-PARA.
   DISPLAY  IN A-PARA 
   GO TO B-PARA.
   
   B-PARA.
   DISPLAY  IN B-PARA  .
   GO TO C-PARA D-PARA DEPENDING ON WS-A.
   
   C-PARA.
   DISPLAY  IN C-PARA  .
   
   D-PARA.
   DISPLAY  IN D-PARA  .
   STOP RUN.

JCL to execute the above COBOL program:

//SAMPLE JOB(TESTJCL,XXXXXX),CLASS = A,MSGCLASS = C
//STEP1 EXEC PGM = HELLO

When you compile and execute the above program, it produces the following result:

IN A-PARA
IN B-PARA 
IN D-PARA 

COBOL - String Handpng

String handpng statements in COBOL are used to do multiple functional operations on strings. Following are the string handpng statements −

    Inspect

    String

    Unstring

Inspect

Inspect verb is used to count or replace the characters in a string. String operations can be performed on alphanumeric, numeric, or alphabetic values. Inspect operations are performed from left to right. The options used for the string operations are as follows −

Tallying

Tallying option is used to count the string characters.

Syntax

Following is the syntax of Tallying option −

INSPECT input-string
TALLYING output-count FOR ALL CHARACTERS

The parameters used are −

    input-string − The string whose characters are to be counted.

    output-count − Data item to hold the count of characters.

Example

IDENTIFICATION DIVISION.
PROGRAM-ID. HELLO.

DATA DIVISION.
   WORKING-STORAGE SECTION.
   01 WS-CNT1 PIC 9(2) VALUE 0.
   01 WS-CNT2 PIC 9(2) VALUE 0.
   01 WS-STRING PIC X(15) VALUE  ABCDACDADEAAAFF .
   
PROCEDURE DIVISION.
   INSPECT WS-STRING TALLYING WS-CNT1 FOR CHARACTER.
   DISPLAY "WS-CNT1 : "WS-CNT1.
   INSPECT WS-STRING TALLYING WS-CNT2 FOR ALL  A .
   DISPLAY "WS-CNT2 : "WS-CNT2
   
STOP RUN.

JCL to execute the above COBOL program.

//SAMPLE JOB(TESTJCL,XXXXXX),CLASS = A,MSGCLASS = C
//STEP1 EXEC PGM = HELLO

When you compile and execute the above program, it produces the following result −

WS-CNT1 : 15
WS-CNT2 : 06

Replacing

Replacing option is used to replace the string characters.

Syntax

Following is the syntax of Replacing option −

INSPECT input-string REPLACING ALL char1 BY char2.

The parameter used is −

    input-string − The string whose characters are to be replaced from char1 to char2.

Example

IDENTIFICATION DIVISION.
PROGRAM-ID. HELLO.

DATA DIVISION.
   WORKING-STORAGE SECTION.
   01 WS-STRING PIC X(15) VALUE  ABCDACDADEAAAFF .

PROCEDURE DIVISION.
   DISPLAY "OLD STRING : "WS-STRING.
   INSPECT WS-STRING REPLACING ALL  A  BY  X .
   DISPLAY "NEW STRING : "WS-STRING.
   
STOP RUN.

JCL to execute the above COBOL program.

//SAMPLE JOB(TESTJCL,XXXXXX),CLASS = A,MSGCLASS = C
//STEP1 EXEC PGM = HELLO

When you compile and execute the above program, it produces the following result −

OLD STRING : ABCDACDADEAAAFF
NEW STRING : XBCDXCDXDEXXXFF

String

String verb is used to concatenate the strings. Using STRING statement, two or more strings of characters can be combined to form a longer string. ‘Depmited By’ clause is compulsory.

Syntax

Following is the syntax of String verb −

STRING ws-string1 DELIMITED BY SPACE
   ws-string2 DELIMITED BY SIZE
   INTO ws-destination-string
   WITH POINTER ws-count
   ON OVERFLOW DISPLAY message1
   NOT ON OVERFLOW DISPLAY message2
END-STRING.

Following are the details of the used parameters −

    ws-string1 and ws-string2 : Input strings to be concatenated

    ws-string : Output string

    ws-count : Used to count the length of new concatenated string

    Depmited specifies the end of string

    Pointer and Overflow are optional

Example

IDENTIFICATION DIVISION.
PROGRAM-ID. HELLO.

DATA DIVISION.
   WORKING-STORAGE SECTION.
   01 WS-STRING PIC A(30).
   01 WS-STR1 PIC A(15) VALUE  Tutorialspoint .
   01 WS-STR2 PIC A(7) VALUE  Welcome .
   01 WS-STR3 PIC A(7) VALUE  To AND .
   01 WS-COUNT PIC 99 VALUE 1.

PROCEDURE DIVISION.
   STRING WS-STR2 DELIMITED BY SIZE
      WS-STR3 DELIMITED BY SPACE
      WS-STR1 DELIMITED BY SIZE
      INTO WS-STRING 
      WITH POINTER WS-COUNT
      ON OVERFLOW DISPLAY  OVERFLOW!  
   END-STRING.
   
   DISPLAY  WS-STRING :  WS-STRING.
   DISPLAY  WS-COUNT :  WS-COUNT.

STOP RUN.

JCL to execute the above COBOL program −

//SAMPLE JOB(TESTJCL,XXXXXX),CLASS = A,MSGCLASS = C
//STEP1 EXEC PGM = HELLO

When you compile and execute the above program, it produces the following result −

WS-STRING : WelcomeToTutorialspoint       
WS-COUNT : 25

Unstring

Unstring verb is used to sppt one string into multiple sub-strings. Depmited By clause is compulsory.

Syntax

Following is the syntax of Unstring verb −

UNSTRING ws-string DELIMITED BY SPACE
INTO ws-str1, ws-str2
WITH POINTER ws-count
ON OVERFLOW DISPLAY message
NOT ON OVERFLOW DISPLAY message
END-UNSTRING.

Example

IDENTIFICATION DIVISION.
PROGRAM-ID. HELLO.

DATA DIVISION.
   WORKING-STORAGE SECTION.
   01 WS-STRING PIC A(30) VALUE  WELCOME TO TUTORIALSPOINT .
   01 WS-STR1 PIC A(7).
   01 WS-STR2 PIC A(2).
   01 WS-STR3 PIC A(15).
   01 WS-COUNT PIC 99 VALUE 1.

PROCEDURE DIVISION.
   UNSTRING WS-STRING DELIMITED BY SPACE
      INTO WS-STR1, WS-STR2, WS-STR3
   END-UNSTRING.
   
   DISPLAY  WS-STR1 :  WS-STR1.
   DISPLAY  WS-STR2 :  WS-STR2.
   DISPLAY  WS-STR3 :  WS-STR3.
   
STOP RUN.

JCL to execute the above COBOL program −

//SAMPLE JOB(TESTJCL,XXXXXX),CLASS = A,MSGCLASS = C
//STEP1 EXEC PGM = HELLO

When you compile and execute the above program, it produces the following result −

WS-STR1 : WELCOME
WS-STR2 : TO
WS-STR3 : TUTORIALSPOINT 

COBOL - Table Processing

Arrays in COBOL are known as tables. An array is a pnear data structure and is a collection of inspanidual data items of same type. Data items of a table are internally sorted.

Table Declaration

Table is declared in Data Division. Occurs clause is used to define a table. Occurs clause indicates the repetition of data name definition. It can be used only with level numbers starting from 02 to 49. Do not use occurs clause with Redefines. Description of one-dimensional and two-dimensional table is as follows −

One-Dimensional Table

In a one-dimensional table, occurs clause is used only once in declaration. WSTABLE is the group item that contains table. WS-B names the table elements that occur 10 times.

Syntax

Following is the syntax for defining a one-dimensional table −

01 WS-TABLE.
   05 WS-A PIC A(10) OCCURS 10 TIMES.

Example

IDENTIFICATION DIVISION.
PROGRAM-ID. HELLO.

DATA DIVISION.
   WORKING-STORAGE SECTION.
   01 WS-TABLE.
      05 WS-A PIC A(10) VALUE  TUTORIALS  OCCURS 5 TIMES.     

PROCEDURE DIVISION.
   DISPLAY "ONE-D TABLE : "WS-TABLE.
STOP RUN.

JCL to execute the above COBOL program −

//SAMPLE JOB(TESTJCL,XXXXXX),CLASS = A,MSGCLASS = C
//STEP1 EXEC PGM = HELLO

When you compile and execute the above program, it produces the following result −

ONE-D TABLE : TUTORIALS TUTORIALS TUTORIALS TUTORIALS TUTORIALS

Two-Dimensional Table

A two-dimensional table is created with both data elements being variable length. For reference, go through the syntax and then try to analyze the table. The first array (WS-A) can occur from 1 to 10 times and the inner array (WS-C) can occur from 1 to 5 times. For each entry of WS-A, there will be corresponding 5 entries of WS-C.

Syntax

Following is the syntax for defining a two-dimensional table −

01 WS-TABLE.
   05 WS-A OCCURS 10 TIMES.
      10 WS-B PIC A(10).
      10 WS-C OCCURS 5 TIMES.
         15 WS-D PIC X(6).

Example

IDENTIFICATION DIVISION.
PROGRAM-ID. HELLO.

DATA DIVISION.
   WORKING-STORAGE SECTION.
   01 WS-TABLE.
      05 WS-A OCCURS 2 TIMES.
         10 WS-B PIC A(10) VALUE   TUTORIALS .
         10 WS-C OCCURS 2 TIMES.
            15 WS-D PIC X(6) VALUE   POINT .

PROCEDURE DIVISION.
   DISPLAY "TWO-D TABLE : "WS-TABLE.

STOP RUN.

JCL to execute the above COBOL program −

//SAMPLE JOB(TESTJCL,XXXXXX),CLASS = A,MSGCLASS = C
//STEP1 EXEC PGM = HELLO

When you compile and execute the above program, it produces the following result −

TWO-D TABLE :  TUTORIALS POINT POINT TUTORIALS POINT POINT

Subscript

Table inspanidual elements can be accessed by using subscript. Subscript values can range from 1 to the number of times the table occurs. A subscript can be any positive number. It does not require any declaration in data spanision. It is automatically created with occurs clause.

Example

IDENTIFICATION DIVISION.
PROGRAM-ID. HELLO.

DATA DIVISION.
   WORKING-STORAGE SECTION.
   01 WS-TABLE.
      05 WS-A OCCURS 3 TIMES.
         10 WS-B PIC A(2).
         10 WS-C OCCURS 2 TIMES.
            15 WS-D PIC X(3).

PROCEDURE DIVISION.
   MOVE  12ABCDEF34GHIJKL56MNOPQR  TO WS-TABLE.
   DISPLAY  WS-TABLE  :   WS-TABLE.
   DISPLAY  WS-A(1)   :   WS-A(1).
   DISPLAY  WS-C(1,1) :   WS-C(1,1).
   DISPLAY  WS-C(1,2) :   WS-C(1,2).
   DISPLAY  WS-A(2)   :   WS-A(2).
   DISPLAY  WS-C(2,1) :   WS-C(2,1).
   DISPLAY  WS-C(2,2) :   WS-C(2,2).
   DISPLAY  WS-A(3)   :   WS-A(3).
   DISPLAY  WS-C(3,1) :   WS-C(3,1).
   DISPLAY  WS-C(3,2) :   WS-C(3,2).
   
STOP RUN.

JCL to execute the above COBOL program −

//SAMPLE JOB(TESTJCL,XXXXXX),CLASS = A,MSGCLASS = C
//STEP1 EXEC PGM = HELLO

When you compile and execute the above program, it produces the following result −

WS-TABLE  : 12ABCDEF34GHIJKL56MNOPQR
WS-A(1)   : 12ABCDEF
WS-C(1,1) : ABC
WS-C(1,2) : DEF
WS-A(2)   : 34GHIJKL
WS-C(2,1) : GHI
WS-C(2,2) : JKL
WS-A(3)   : 56MNOPQR
WS-C(3,1) : MNO
WS-C(3,2) : PQR

Index

Table elements can also be accessed using index. An index is a displacement of element from the start of the table. An index is declared with Occurs clause using INDEXED BY clause. The value of index can be changed using SET statement and PERFORM Varying option.

Syntax

Following is the syntax for defining Index in a table −

01 WS-TABLE.
   05 WS-A PIC A(10) OCCURS 10 TIMES INDEXED BY I.

Example

IDENTIFICATION DIVISION.
PROGRAM-ID. HELLO.

DATA DIVISION.
   WORKING-STORAGE SECTION.
   01 WS-TABLE.
      05 WS-A OCCURS 3 TIMES INDEXED BY I.
         10 WS-B PIC A(2).
         10 WS-C OCCURS 2 TIMES INDEXED BY J.
            15 WS-D PIC X(3).

PROCEDURE DIVISION.
   MOVE  12ABCDEF34GHIJKL56MNOPQR  TO WS-TABLE.
   PERFORM A-PARA VARYING I FROM 1 BY 1 UNTIL I >3 
   STOP RUN.
   
   A-PARA.
   PERFORM C-PARA VARYING J FROM 1 BY 1 UNTIL J>2.
   
   C-PARA.
   DISPLAY WS-C(I,J).

JCL to execute the above COBOL program −

//SAMPLE JOB(TESTJCL,XXXXXX),CLASS = A,MSGCLASS = C
//STEP1 EXEC PGM = HELLO

When you compile and execute the above program, it produces the following result −

ABC
DEF
GHI
JKL
MNO
PQR

Set Statement

Set statement is used to change the index value. Set verb is used to initiapze, increment, or decrement the index value. It is used with Search and Search All to locate elements in table.

Syntax

Following is the syntax for using a Set statement −

SET I J TO positive-number
SET I TO J
SET I TO 5
SET I J UP BY 1
SET J DOWN BY 5

Example

IDENTIFICATION DIVISION.
PROGRAM-ID. HELLO.

DATA DIVISION.
   WORKING-STORAGE SECTION.
   01 WS-TABLE.
      05 WS-A OCCURS 3 TIMES INDEXED BY I.
         10 WS-B PIC A(2).
         10 WS-C OCCURS 2 TIMES INDEXED BY J.
            15 WS-D PIC X(3).

PROCEDURE DIVISION.
   MOVE  12ABCDEF34GHIJKL56MNOPQR  TO WS-TABLE.
   SET I J TO 1.
   DISPLAY WS-C(I,J).
   SET I J UP BY 1.
   DISPLAY WS-C(I,J).
   
STOP RUN.

JCL to execute the above COBOL program.

//SAMPLE JOB(TESTJCL,XXXXXX),CLASS = A,MSGCLASS = C
//STEP1 EXEC PGM = HELLO

When you compile and execute the above program, it produces the following result −

ABC
JKL

Search

Search is a pnear search method, which is used to find elements inside the table. It can be performed on sorted as well as unsorted table. It is used only for tables declared by Index phrase. It starts with the initial value of index. If the searched element is not found, then the index is automatically incremented by 1 and it continues till the end of table.

Example

IDENTIFICATION DIVISION.
PROGRAM-ID. HELLO.

DATA DIVISION.
   WORKING-STORAGE SECTION.
   01 WS-TABLE.
      05 WS-A PIC X(1) OCCURS 18 TIMES INDEXED BY I.
   01 WS-SRCH PIC A(1) VALUE  M .

PROCEDURE DIVISION.
   MOVE  ABCDEFGHIJKLMNOPQR  TO WS-TABLE.
   SET I TO 1.
   SEARCH WS-A
      AT END DISPLAY  M NOT FOUND IN TABLE 
      WHEN WS-A(I) = WS-SRCH
      DISPLAY  LETTER M FOUND IN TABLE 
   END-SEARCH.  

STOP RUN.

JCL to execute the above COBOL program.

//SAMPLE JOB(TESTJCL,XXXXXX),CLASS = A,MSGCLASS = C
//STEP1 EXEC PGM = HELLO

When you compile and execute the above program, it produces the following result −

LETTER M FOUND IN TABLE

Search All

Search All is a binary search method, which is used to find elements inside the table. Table must be in sorted order for Search All option. The index does not require initiapzation. In binary search, the table is spanided into two halves and it determines in which half the searched element is present. This process repeats till the element is found or the end is reached.

Example

IDENTIFICATION DIVISION.
PROGRAM-ID. HELLO.

DATA DIVISION.
   WORKING-STORAGE SECTION.
   01 WS-TABLE.
      05 WS-RECORD OCCURS 10 TIMES ASCENDING KEY IS WS-NUM INDEXED BY I.
      10 WS-NUM PIC 9(2).
      10 WS-NAME PIC A(3).

PROCEDURE DIVISION.
   MOVE  12ABC56DEF34GHI78JKL93MNO11PQR  TO WS-TABLE.
   SEARCH ALL WS-RECORD
     AT END DISPLAY  RECORD NOT FOUND 
     WHEN WS-NUM(I) = 93
     DISPLAY  RECORD FOUND  
     DISPLAY WS-NUM(I)
     DISPLAY WS-NAME(I)

END-SEARCH. 

JCL to execute the above COBOL program −

//SAMPLE JOB(TESTJCL,XXXXXX),CLASS = A,MSGCLASS = C
//STEP1 EXEC PGM = HELLO

When you compile and execute the above program, it produces the following result −

RECORD FOUND 
93
MNO

COBOL - File Handpng

The concept of files in COBOL is different from that in C/C++. While learning the basics of File in COBOL, the concepts of both languages should not be corelated. Simple text files cannot be used in COBOL, instead PS (Physical Sequential) and VSAM files are used. PS files will be discussed in this module.

To understand file handpng in COBOL, one must know the basic terms. These terms only serve to understand the fundamentals of file handpng. Further in depth terminology would be discussed in the chapter File Handpng Verbs . Following are the basic terms −

    Field

    Record

    Physical Record

    Logical Record

    File

The following example helps in understanding these terms −

Program Structure

Field

Field is used to indicate the data stored about an element. It represents a single element as shown in the above example such as student id, name, marks, total marks, and percentage. The number of characters in any field is known as field size, for example, student name can have 10 characters. Fields can have the following attributes −

    Primary keys are those fields that are unique to each record and are used to identify a particular record. For example, in students marks file, each student will be having a unique student id which forms the primary key.

    Secondary keys are unique or non-unique fields that are used to search for related data. For example, in students marks file, full name of student can be used as secondary key when student id is not known.

    Descriptors fields are used to describe an entity. For example, in students marks file, marks and percentage fields that add meaning to the record are known descriptors.

Record

Record is a collection of fields that is used to describe an entity. One or more fields together form a record. For example, in students marks file, student id, name, marks, total marks, and percentage form one record. The cumulative size of all the fields in a record is known as the record size. The records present in a file may be of fixed length or variable length.

Physical Record

Physical record is the information that exists on the external device. It is also known as a block.

Logical Record

Logical record is the information used by the program. In COBOL programs, only one record can be handled at any point of time and it is called as logical record.

File

File is a collection of related records. For example, the students marks file consists of records of all the students.

COBOL - File Organization

File organization indicates how the records are organized in a file. There are different types of organizations for files so as to increase their efficiency of accessing the records. Following are the types of file organization schemes −

    Sequential file organization

    Indexed sequential file organization

    Relative file organization

The syntaxes in this module, mentioned along with their respective terms, only refer to their usage in the program. The complete programs using these syntaxes would be discussed in the chapter File handpng Verbs .

Sequential File Organization

A sequential file consists of records that are stored and accessed in sequential order. Following are the key attributes of sequential file organization −

    Records can be read in sequential order. For reading the 10th record, all the previous 9 records should be read.

    Records are written in sequential order. A new record cannot be inserted in between. A new record is always inserted at the end of the file.

    After placing a record into a sequential file, it is not possible to delete, shorten, or lengthen a record.

    Order of the records, once inserted, can never be changed.

    Updation of record is possible. A record can be overwritten, if the new record length is same as the old record length.

    Sequential output files are good option for printing.

Syntax

Following is the syntax of sequential file organization −

INPUT-OUTPUT SECTION.
FILE-CONTROL.
   SELECT file-name ASSIGN TO dd-name-jcl
   ORGANIZATION IS SEQUENTIAL

Indexed Sequential File Organization

An indexed sequential file consists of records that can be accessed sequentially. Direct access is also possible. It consists of two parts −

    Data File contains records in sequential scheme.

    Index File contains the primary key and its address in the data file.

Following are the key attributes of sequential file organization −

    Records can be read in sequential order just pke in sequential file organization.

    Records can be accessed randomly if the primary key is known. Index file is used to get the address of a record and then the record is fetched from the data file.

    Sorted index is maintained in this file system which relates the key value to the position of the record in the file.

    Alternate index can also be created to fetch the records.

Syntax

Following is the syntax of indexed sequential file organization −

INPUT-OUTPUT SECTION.
FILE-CONTROL.
   SELECT file-name ASSIGN TO dd-name-jcl
   ORGANIZATION IS INDEXED
   RECORD KEY IS primary-key
   ALTERNATE RECORD KEY IS rec-key

Relative File Organization

A relative file consists of records ordered by their relative address. Following are the key attributes of relative file organization −

    Records can be read in sequential order just pke in sequential and indexed file organization.

    Records can be accessed using relative key. Relative key represents the record’s location relative to the address of the start of the file.

    Records can be inserted using relative key. Relative address is calculated using relative key.

    Relative file provides the fastest access to the records.

    The main disadvantage of this file system is that if some intermediate records are missing, they will also occupy space.

Syntax

Following is the syntax of relative file organization −

INPUT-OUTPUT SECTION.
FILE-CONTROL.
   SELECT file-name ASSIGN TO dd-name-jcl
   ORGANIZATION IS RELATIVE
   RELATIVE KEY IS rec-key

COBOL - File Access Mode

Till now, file organization schemes have been discussed. For each file organization scheme, different access modes can be used. Following are the types of file access modes −

    Sequential Access

    Random Access

    Dynamic Access

The syntaxes in this module, mentioned along with their respective terms, only refer to their usage in the program. The complete programs using these syntaxes would be discussed in the next chapter.

Sequential Access

When the access mode is sequential, the method of record retrieval changes as per the selected file organization.

    For sequential files, records are accessed in the same order in which they were inserted.

    For indexed files, the parameter used to fetch the records are the record key values.

    For relative files, relative record keys are used to retrieve the records.

Syntax

Following is the syntax of sequential access mode −

ENVIRONMENT DIVISION.
INPUT-OUTPUT SECTION.
FILE-CONTROL.
   SELECT file-name ASSIGN TO dd-name
   ORGANIZATION IS SEQUENTIAL
   ACCESS MODE IS SEQUENTIAL
	
	
ENVIRONMENT DIVISION.
INPUT-OUTPUT SECTION.
   FILE-CONTROL.
   SELECT file-name ASSIGN TO dd-name
   ORGANIZATION IS INDEXED
   ACCESS MODE IS SEQUENTIAL
   RECORD KEY IS rec-key1
   ALTERNATE RECORD KEY IS rec-key2

		
ENVIRONMENT DIVISION.
INPUT-OUTPUT SECTION.
   FILE-CONTROL.
   SELECT file-name ASSIGN TO dd-name
   ORGANIZATION IS RELATIVE
   ACCESS MODE IS SEQUENTIAL
   RELATIVE KEY IS rec-key1

Random Access

When the access mode is RANDOM, the method of record retrieval changes as per the selected file organization.

    For indexed files, records are accessed according to the value placed in a key field which can be primary or alternate key. There can be one or more alternate indexes.

    For relative files , records are retrieved through relative record keys.

Syntax

Following is the syntax of random access mode −

ENVIRONMENT DIVISION.
INPUT-OUTPUT SECTION.
   FILE-CONTROL.
   SELECT file-name ASSIGN TO dd-name
   ORGANIZATION IS INDEXED
   ACCESS MODE IS RANDOM
   RECORD KEY IS rec-key1
   ALTERNATE RECORD KEY IS rec-key2

		
ENVIRONMENT DIVISION.
INPUT-OUTPUT SECTION.
   FILE-CONTROL.
   SELECT file-name ASSIGN TO dd-name
   ORGANIZATION IS RELATIVE
   ACCESS MODE IS RANDOM
   RELATIVE KEY IS rec-key1

Dynamic Access

Dynamic access supports both sequential and random access in the same program. With dynamic access, one file definition is used to perform both sequential and random processing pke accessing some records in sequential order and other records by their keys.

With relative and indexed files, the dynamic access mode allows you to switch back and forth between sequential access mode and random access mode while reading a file by using the NEXT phrase on the READ statement. NEXT and READ functionapties will be discussed in the next chapter.

Syntax

Following is the syntax of dynamic access mode −

ENVIRONMENT DIVISION.
INPUT-OUTPUT SECTION.
   FILE-CONTROL.
   SELECT file-name ASSIGN TO dd-name
   ORGANIZATION IS SEQUENTIAL
   ACCESS MODE IS DYNAMIC
   RECORD KEY IS rec-key1
   ALTERNATE RECORD KEY IS rec-key2

		
ENVIRONMENT DIVISION.
INPUT-OUTPUT SECTION.
   FILE-CONTROL.
   SELECT file-name ASSIGN TO dd-name
   ORGANIZATION IS RELATIVE
   ACCESS MODE IS DYNAMIC
   RELATIVE KEY IS rec-key1

COBOL - File Handpng Verbs

File handpng verbs are used to perform various operations on files. Following are the file handpng verbs −

    Open

    Read

    Write

    Rewrite

    Delete

    Start

    Close

Open Verb

Open is the first file operation that must be performed. If Open is successful, then only further operations are possible on a file. Only after opening a file, the variables in the file structure are available for processing. FILE STATUS variable is updated after each file operation.

Syntax

OPEN "mode" file-name.

Here, file-name is string pteral, which you will use to name your file. A file can be opened in the following modes −

Sr.No. Mode & Description
1

Input

Input mode is used for existing files. In this mode, we can only read the file, no other operations are allowed on the file.

2

Output

Output mode is used to insert records in files. If a sequential file is used and the file is holding some records, then the existing records will be deleted first and then new records will be inserted in the file. It will not happen so in case of an indexed file or a relative file.

3

Extend

Extend mode is used to append records in a sequential file. In this mode, records are inserted at the end. If file access mode is Random or Dynamic, then extend mode cannot be used.

4

I-O

Input-Output mode is used to read and rewrite the records of a file.

Read Verb

Read verb is used to read the file records. The function of read is to fetch records from a file. At each read verb, only one record can be read into the file structure. To perform a read operation, open the file in INPUT or I-O mode. At each read statement, the file pointer is incremented and hence the successive records are read.

Syntax

Following is the syntax to read the records when the file access mode is sequential −

READ file-name NEXT RECORD INTO ws-file-structure
   AT END DISPLAY  End of File 
   NOT AT END DISPLAY  Record Details:  ws-file-structure
END-READ.

Following are the parameters used −

    NEXT RECORD is optional and is specified when an indexed sequential file is being read sequentially.

    INTO clause is optional. ws-file-structure is defined in the WorkingStorage Section to get the values from the READ statement.

    AT END condition becomes True when the end of file is reached.

Example − The following example reads an existing file using pne sequential organization. This program can be compiled and executed using Live Demo option where it will display all the records present in the file.

IDENTIFICATION DIVISION.
PROGRAM-ID. HELLO.

ENVIRONMENT DIVISION.
   INPUT-OUTPUT SECTION.
      FILE-CONTROL.
      SELECT STUDENT ASSIGN TO  input.txt 
      ORGANIZATION IS LINE SEQUENTIAL.            

DATA DIVISION.
   FILE SECTION.
   FD STUDENT.
   01 STUDENT-FILE.
      05 STUDENT-ID PIC 9(5).
      05 NAME PIC A(25).

   WORKING-STORAGE SECTION.
   01 WS-STUDENT.
      05 WS-STUDENT-ID PIC 9(5).
      05 WS-NAME PIC A(25).
   01 WS-EOF PIC A(1). 

PROCEDURE DIVISION.
   OPEN INPUT STUDENT.
      PERFORM UNTIL WS-EOF= Y 
         READ STUDENT INTO WS-STUDENT
            AT END MOVE  Y  TO WS-EOF
            NOT AT END DISPLAY WS-STUDENT
         END-READ
      END-PERFORM.
   CLOSE STUDENT.
STOP RUN.

Suppose the input file data available in the input.txt file contains the following −

20003 Mohtashim M.
20004 Nishant Mapk
20005 Amitabh Bachhan

When you compile and execute the above program, it produces the following result −

20003 Mohtashim M.            
20004 Nishant Mapk           
20005 Amitabh Bachhan 

Syntax

Following is the syntax to read a record when the file access mode is random −

READ file-name RECORD INTO ws-file-structure
   KEY IS rec-key
   INVALID KEY DISPLAY  Invapd Key 
   NOT INVALID KEY DISPLAY  Record Details:   ws-file-structure
END-READ.

Example − The following example reads an existing file using indexed organization. This program can be compiled and executed using JCL on Mainframes where it will display all the records present in the file. On Mainframes server, we do not use text files; instead we use PS files.

Let s assume that the file present on Mainframes have same content as input.txt file in the above example.

IDENTIFICATION DIVISION.
PROGRAM-ID. HELLO.

ENVIRONMENT DIVISION.
   INPUT-OUTPUT SECTION.
   FILE-CONTROL.
   SELECT STUDENT ASSIGN TO IN1
      ORGANIZATION IS INDEXED
      ACCESS IS RANDOM
      RECORD KEY IS STUDENT-ID
      FILE STATUS IS FS.

DATA DIVISION.
   FILE SECTION.
   FD STUDENT.
      01 STUDENT-FILE.
      05 STUDENT-ID PIC 9(5).
      05 NAME PIC A(25).
     
   WORKING-STORAGE SECTION.
   01 WS-STUDENT.
      05 WS-STUDENT-ID PIC 9(5).
      05 WS-NAME PIC A(25).

PROCEDURE DIVISION.
   OPEN INPUT STUDENT.
      MOVE 20005 TO STUDENT-ID.
      
      READ STUDENT RECORD INTO WS-STUDENT-FILE
         KEY IS STUDENT-ID
         INVALID KEY DISPLAY  Invapd Key 
         NOT INVALID KEY DISPLAY WS-STUDENT-FILE
      END-READ.
      
   CLOSE STUDENT.
STOP RUN.

JCL to execute the above COBOL program −

//SAMPLE JOB(TESTJCL,XXXXXX),CLASS = A,MSGCLASS = C
//STEP1 EXEC PGM = HELLO
//IN1 DD DSN = STUDENT-FILE-NAME,DISP=SHR

When you compile and execute the above program, it produces the following result −

20005 Amitabh Bachhan 

Write Verb

Write verb is used to insert records in a file. Once the record is written, it is no longer available in the record buffer. Before inserting records into the file, move the values into the record buffer and then perform write verb.

Write statement can be used with FROM option to directly write records from the working storage variables. From is an optional clause. If the access mode is sequential, then to write a record, the file must open in Output mode or Extend mode. If the access mode is random or dynamic, then to write a record, the file must open in Output mode or I-O mode.

Syntax

Following is the syntax to read a record when the file organization is sequential −

WRITE record-buffer [FROM ws-file-structure]
END-WRITE.

Following is the syntax to read a record when the file organization is indexed or relative −

WRITE record-buffer [FROM ws-file-structure]
   INVALID KEY DISPLAY  Invapd Key 
   NOT INVALID KEY DISPLAY  Record Inserted 
END-WRITE.

Example − The following example shows how to insert a new record in a new file when the organization is sequential.

IDENTIFICATION DIVISION.
PROGRAM-ID. HELLO.

ENVIRONMENT DIVISION.
   INPUT-OUTPUT SECTION.
   FILE-CONTROL.
   SELECT STUDENT ASSIGN TO OUT1
      ORGANIZATION IS SEQUENTIAL
      ACCESS IS SEQUENTIAL
      FILE STATUS IS FS.

DATA DIVISION.
   FILE SECTION.
   FD STUDENT
   01 STUDENT-FILE.
      05 STUDENT-ID PIC 9(5).
      05 NAME PIC A(25).
      05 CLASS PIC X(3).

   WORKING-STORAGE SECTION.
   01 WS-STUDENT.
      05 WS-STUDENT-ID PIC 9(5).
      05 WS-NAME PIC A(25).
      05 WS-CLASS PIC X(3).

PROCEDURE DIVISION.
   OPEN EXTEND STUDENT.
      MOVE 1000 TO STUDENT-ID.
      MOVE  Tim  TO NAME.
      MOVE  10  TO CLASS.
      WRITE STUDENT-FILE
      END-WRITE.	
   CLOSE STUDENT.
STOP RUN.

JCL to execute the above COBOL program −

//SAMPLE JOB(TESTJCL,XXXXXX),CLASS = A,MSGCLASS = C
//STEP1 EXEC PGM = HELLO
//OUT1 DD DSN = OUTPUT-FILE-NAME,DISP = (NEW,CATALOG,DELETE)

When you compile and execute the above program, it will add a new record to the output file.

1000 Tim         10

Rewrite Verb

Rewrite verb is used to update the records. File should be opened in I-O mode for rewrite operations. It can be used only after a successful Read operation. Rewrite verb overwrites the last record read.

Syntax

Following is the syntax to read a record when the file organization is sequential −

REWRITE record-buffer [FROM ws-file-structure]
END-REWRITE.

Following is the syntax to read a record when the file organization is indexed or relative −

REWRITE record-buffer [FROM ws-file-structure]
   INVALID KEY DISPLAY  Invapd Key 
   NOT INVALID KEY DISPLAY  Record Updated 
END-REWRITE.

Example − The following example shows how to update an existing record which we have inserted in the previous Write step −

IDENTIFICATION DIVISION.
PROGRAM-ID. HELLO.

ENVIRONMENT DIVISION.
   INPUT-OUTPUT SECTION.
   FILE-CONTROL.
   SELECT STUDENT ASSIGN TO IN1
      ORGANIZATION IS INDEXED
      ACCESS IS RANDOM
      RECORD KEY IS STUDENT-ID
      FILE STATUS IS FS.

DATA DIVISION.
   FILE SECTION.
   FD STUDENT
   01 STUDENT-FILE.
      05 STUDENT-ID PIC 9(4).
      05 NAME PIC A(12).
      05 CLASS PIC X(3).
      
   WORKING-STORAGE SECTION.
   01 WS-STUDENT.
      05 WS-STUDENT-ID PIC 9(5).
      05 WS-NAME PIC A(25).
      05 WS-CLASS PIC X(3).

PROCEDURE DIVISION.
   OPEN I-O STUDENT.
   MOVE  1000  TO STUDENT-ID.
  
   READ STUDENT
      KEY IS STUDENT-ID
      INVALID KEY DISPLAY ‘KEY IS NOT EXISTING’
   END-READ.
  
   MOVE  Tim Dumais  TO NAME.
   REWRITE STUDENT-FILE
   END-REWRITE.
   CLOSE STUDENT.
STOP RUN.

JCL to execute the above COBOL program −

//SAMPLE JOB(TESTJCL,XXXXXX),CLASS = A,MSGCLASS = C
//STEP1 EXEC PGM = HELLO
//IN1 DD DSN = OUTPUT-FILE-NAME,DISP = SHR

When you compile and execute the above program, it will update the record −

1000 Tim Dumais  10

Delete Verb

Delete verb can be performed only on indexed and relative files. The file must be opened in I-O mode. In sequential file organization, records cannot be deleted. The record last read by the Read statement is deleted in case of sequential access mode. In random access mode, specify the record key and then perform the Delete operation.

Syntax

Following is the syntax to delete a record −

DELETE file-name RECORD
   INVALID KEY DISPLAY  Invapd Key 
   NOT INVALID KEY DISPLAY  Record Deleted 
END-DELETE.

Example − to delete an existing record −

IDENTIFICATION DIVISION.
PROGRAM-ID. HELLO.

ENVIRONMENT DIVISION.
   INPUT-OUTPUT SECTION.
   FILE-CONTROL.
   SELECT STUDENT ASSIGN TO OUT1
      ORGANIZATION IS INDEXED
      ACCESS IS RANDOM
      RECORD KEY IS STUDENT-ID
      FILE STATUS IS FS.

DATA DIVISION.
   FILE SECTION.
   FD STUDENT
   01 STUDENT-FILE.
      05 STUDENT-ID PIC 9(4).
      05 NAME PIC A(12).
      05 CLASS PIC X(3).
   WORKING-STORAGE SECTION.
   01 WS-STUDENT.
      05 WS-STUDENT-ID PIC 9(5).
      05 WS-NAME PIC A(25).
      05 WS-CLASS PIC X(3).

PROCEDURE DIVISION.
   OPEN I-O STUDENT.
   MOVE  1000  TO STUDENT-ID.
   
   DELETE STUDENT RECORD
      INVALID KEY DISPLAY  Invapd Key 
      NOT INVALID KEY DISPLAY  Record Deleted 
   END-DELETE.
   
   CLOSE STUDENT.
STOP RUN.

JCL to execute the above COBOL program −

//SAMPLE JOB(TESTJCL,XXXXXX),CLASS = A,MSGCLASS = C
//STEP1 EXEC PGM = HELLO
//OUT1 DD DSN = OUTPUT-FILE-NAME,DISP = SHR

When you compile and execute the above program, it produces the following result −

Record Deleted

Start Verb

Start verb can be performed only on indexed and relative files. It is used to place the file pointer at a specific record. The access mode must be sequential or dynamic. File must be opened in I-O or Input mode.

Syntax

Following is the syntax to place the pointer at a specific record −

START file-name KEY IS [=, >, <, NOT, <= or >=] rec-key
   INVALID KEY DISPLAY  Invapd Key 
   NOT INVALID KEY DISPLAY  File Pointer Updated 
END-START.

Close Verb

Close verb is used to close a file. After performing Close operation, the variables in the file structure will not be available for processing. The pnk between program and file is lost.

Syntax

Following is the syntax to close a file −

CLOSE file-name.

COBOL - Subroutines

Cobol subroutine is a program that can be compiled independently but cannot be executed independently. There are two types of subroutines: internal subroutines pke Perform statements and external subroutines pke CALL verb.

Call Verb

Call verb is used to transfer the control from one program to another program. The program that contains the CALL verb is the Calpng Program and the program being called is known as the Called Program. Calpng program execution will halt until the called program finishes the execution. Exit Program statement is used in the Called program to transfer the control back.

Called Program Constraints

Following are the called program requirements −

    Linkage section must be defined in the called program. It consists of data elements passed in the program. The data items should not have Value clause. PIC clause must be compatible with the variables passed through the calpng program.

    Procedure spanision using has a pst of variables passed from the calpng program and the order must be same as mentioned in the Call verb.

    Exit program statement is used in the called program to transfer the control back. It must be the last statement in the called program.

The parameters can be passed between programs in two ways −

    By Reference

    By Content

Call By Reference

If the values of variables in the called program are modified, then their new values will reflect in the calpng program. If BY clause is not specified, then variables are always passed by reference.

Syntax

Following is the syntax of calpng subroutine by reference −

CALL sub-prog-name USING variable-1, variable-2.

Example

Following example is the MAIN calpng program and UTIL is the called program −

IDENTIFICATION DIVISION.
PROGRAM-ID. MAIN.

DATA DIVISION.
   WORKING-STORAGE SECTION.
   01 WS-STUDENT-ID PIC 9(4) VALUE 1000.
   01 WS-STUDENT-NAME PIC A(15) VALUE  Tim .

PROCEDURE DIVISION.
   CALL  UTIL  USING WS-STUDENT-ID, WS-STUDENT-NAME.
   DISPLAY  Student Id :   WS-STUDENT-ID
   DISPLAY  Student Name :   WS-STUDENT-NAME
STOP RUN.

Called Program

IDENTIFICATION DIVISION.
PROGRAM-ID. UTIL.

DATA DIVISION.
   LINKAGE SECTION.
   01 LS-STUDENT-ID PIC 9(4).
   01 LS-STUDENT-NAME PIC A(15).

PROCEDURE DIVISION USING LS-STUDENT-ID, LS-STUDENT-NAME.
   DISPLAY  In Called Program .
   MOVE 1111 TO LS-STUDENT-ID.
EXIT PROGRAM.

JCL to execute the above COBOL program −

//SAMPLE JOB(TESTJCL,XXXXXX),CLASS = A,MSGCLASS = C
//STEP1 EXEC PGM = MAIN

When you compile and execute the above program, it produces the following result −

In Called Program
Student Id : 1111
Student Name : Tim

Call By Content

If the values of variables in the called program are modified, then their new values will not reflect in the calpng program.

Syntax

Following is the syntax of calpng subroutine by content −

CALL sub-prog-name USING 
BY CONTENT variable-1, BY CONTENT variable-2.

Example

Following example is the MAIN calpng program and UTIL is the called program −

IDENTIFICATION DIVISION.
PROGRAM-ID. MAIN.

DATA DIVISION.
   WORKING-STORAGE SECTION.
   01 WS-STUDENT-ID PIC 9(4) VALUE 1000.
   01 WS-STUDENT-NAME PIC A(15) VALUE  Tim .

PROCEDURE DIVISION.
   CALL  UTIL  USING BY CONTENT WS-STUDENT-ID, BY CONTENT WS-STUDENT-NAME.
   DISPLAY  Student Id :   WS-STUDENT-ID
   DISPLAY  Student Name :   WS-STUDENT-NAME
STOP RUN.

Called Program

IDENTIFICATION DIVISION.
PROGRAM-ID. UTIL.

DATA DIVISION.
   LINKAGE SECTION.
   01 LS-STUDENT-ID PIC 9(4).
   01 LS-STUDENT-NAME PIC A(15).

PROCEDURE DIVISION USING LS-STUDENT-ID, LS-STUDENT-NAME.
   DISPLAY  In Called Program .
   MOVE 1111 TO LS-STUDENT-ID.
EXIT PROGRAM.

JCL to execute the above COBOL program −

//SAMPLE JOB(TESTJCL,XXXXXX),CLASS = A,MSGCLASS = C
//STEP1 EXEC PGM = MAIN

When you compile and execute the above program, it produces the following result −

In Called Program
Student Id : 1000
Student Name : Tim

Types of Call

There are two types of calls −

    Static Call occurs when a program is compiled with the NODYNAM compiler option. A static called program is loaded into storage at compile time.

    Dynamic Call occurs when a program is compiled with the DYNAM and NODLL compiler option. A dynamic called program is loaded into storage at runtime.

COBOL - Internal Sort

Sorting of data in a file or merging of two or more files is a common necessity in almost all business-oriented apppcations. Sorting is used for arranging records either in ascending or descending order, so that sequential processing can be performed. There are two techniques which are used for sorting files in COBOL −

    External sort is used to sort files by using the SORT utipty in JCL. We have discussed this in the JCL chapter. As of now, we will focus on internal sort.

    Internal sort is used to sort files within a COBOL program. SORT verb is used to sort a file.

Sort Verb

Three files are used in the sort process in COBOL −

    Input file is the file which we have to sort either in ascending or descending order.

    Work file is used to hold records while the sort process is in progress. Input file records are transferred to the work file for the sorting process. This file should be defined in the File-Section under SD entry.

    Output file is the file which we get after the sorting process. It is the final output of the Sort verb.

Syntax

Following is the syntax to sort a file −

SORT work-file ON ASCENDING KEY rec-key1
   [ON DESCENDING KEY rec-key2]
USING input-file GIVING output-file.

SORT performs the following operations −

    Opens work-file in I-O mode, input-file in the INPUT mode and output-file in the OUTPUT mode.

    Transfers the records present in the input-file to the work-file.

    Sorts the SORT-FILE in ascending/descending sequence by rec-key.

    Transfers the sorted records from the work-file to the output-file.

    Closes the input-file and the output-file and deletes the work-file.

Example

In the following example, INPUT is the input file which needs to be sorted in ascending order −

IDENTIFICATION DIVISION.
PROGRAM-ID. HELLO.

ENVIRONMENT DIVISION.
   INPUT-OUTPUT SECTION.
   FILE-CONTROL.
      SELECT INPUT ASSIGN TO IN.
      SELECT OUTPUT ASSIGN TO OUT.
      SELECT WORK ASSIGN TO WRK.

DATA DIVISION.
   FILE SECTION.
   FD INPUT.
      01 INPUT-STUDENT.
         05 STUDENT-ID-I PIC 9(5).
         05 STUDENT-NAME-I PIC A(25).
   FD OUTPUT.
      01 OUTPUT-STUDENT.
         05 STUDENT-ID-O PIC 9(5).
         05 STUDENT-NAME-O PIC A(25).
   SD WORK.
      01 WORK-STUDENT.
         05 STUDENT-ID-W PIC 9(5).
         05 STUDENT-NAME-W PIC A(25).

PROCEDURE DIVISION.
   SORT WORK ON ASCENDING KEY STUDENT-ID-O
   USING INPUT GIVING OUTPUT.
   DISPLAY  Sort Successful .
STOP RUN.

JCL to execute the above COBOL program −

//SAMPLE JOB(TESTJCL,XXXXXX),CLASS = A,MSGCLASS = C
//STEP1 EXEC PGM = HELLO
//IN DD DSN = INPUT-FILE-NAME,DISP = SHR
//OUT DD DSN = OUTPUT-FILE-NAME,DISP = SHR
//WRK DD DSN = &&TEMP

When you compile and execute the above program, it produces the following result −

Sort Successful

Merge Verb

Two or more identically sequenced files are combined using Merge statement. Files used in the merge process −

    Input Files − Input-1, Input-2

    Work File

    Output File

Syntax

Following is the syntax to merge two or more files −

MERGE work-file ON ASCENDING KEY rec-key1
   [ON DESCENDING KEY rec-key2]

USING input-1, input-2 GIVING output-file.

Merge performs the following operations −

    Opens the work-file in I-O mode, input-files in the INPUT mode and output-file in the OUTPUT mode.

    Transfers the records present in the input-files to the work-file.

    Sorts the SORT-FILE in ascending/descending sequence by rec-key.

    Transfers the sorted records from the work-file to the output-file.

    Closes the input-file and the output-file and deletes the work-file.

Example

In the following example, INPUT1 and INPUT2 are the input files which are to be merged in ascending order −

IDENTIFICATION DIVISION.
PROGRAM-ID. HELLO.

ENVIRONMENT DIVISION.
   INPUT-OUTPUT SECTION.
   FILE-CONTROL.
      SELECT INPUT1 ASSIGN TO IN1.
      SELECT INPUT2 ASSIGN TO IN2.
      SELECT OUTPUT ASSIGN TO OUT.
      SELECT WORK ASSIGN TO WRK.

DATA DIVISION.
   FILE SECTION.
   FD INPUT1.
      01 INPUT1-STUDENT.
         05 STUDENT-ID-I1 PIC 9(5).
         05 STUDENT-NAME-I1 PIC A(25).
   FD INPUT2.
      01 INPUT2-STUDENT.
         05 STUDENT-ID-I2 PIC 9(5).
         05 STUDENT-NAME-I2 PIC A(25).
   FD OUTPUT.
      01 OUTPUT-STUDENT.
         05 STUDENT-ID-O PIC 9(5).
         05 STUDENT-NAME-O PIC A(25).
   SD WORK.
      01 WORK-STUDENT.
         05 STUDENT-ID-W PIC 9(5).
         05 STUDENT-NAME-W PIC A(25).

PROCEDURE DIVISION.
   MERGE WORK ON ASCENDING KEY STUDENT-ID-O
   USING INPUT1, INPUT2 GIVING OUTPUT.
   DISPLAY  Merge Successful .
STOP RUN.

JCL to execute the above COBOL program −

//SAMPLE JOB(TESTJCL,XXXXXX),CLASS = A,MSGCLASS = C
//STEP1 EXEC PGM = HELLO
//IN1 DD DSN=INPUT1-FILE-NAME,DISP=SHR
//IN2 DD DSN=INPUT2-FILE-NAME,DISP=SHR
//OUT DD DSN = OUTPUT-FILE-NAME,DISP=SHR
//WRK DD DSN = &&TEMP

When you compile and execute the above program, it produces the following result −

Merge Successful

COBOL - Database Interface

As of now, we have learnt the use of files in COBOL. Now, we will discuss how a COBOL program interacts with DB2. It involves the following terms −

    Embedded SQL

    DB2 Apppcation Programming

    Host Variables

    SQLCA

    SQL Queries

    Cursors

Embedded SQL

Embedded SQL statements are used in COBOL programs to perform standard SQL operations. Embedded SQL statements are preprocessed by the SQL processor before the apppcation program is compiled. COBOL is known as the Host Language. COBOL-DB2 apppcations are those apppcations that include both COBOL and DB2.

Embedded SQL statements work pke normal SQL statements with some minor changes. For example, the output of a query is directed to a predefined set of variables which are referred as Host Variables. An additional INTO clause is placed in the SELECT statement.

DB2 Apppcation Programming

Following are rules to be followed while coding a COBOL-DB2 program −

    All the SQL statements must be depmited between EXEC SQL and ENDEXEC..

    SQL statements must be coded in Area B.

    All the tables that are used in a program must be declared in the WorkingStorage Section. This is done by using the INCLUDE statement.

    All SQL statements other than INCLUDE and DECLARE TABLE must appear in the Procedure Division.

Host Variables

Host variables are used for receiving data from a table or inserting data in a table. Host variables must be declared for all values that are to be passed between the program and the DB2. They are declared in the Working-Storage Section.

Host variables cannot be group items, but they may be grouped together in host structure. They cannot be Renamed or Redefined. Using host variables with SQL statements, prefix them with a colon (:)..

Syntax

Following is the syntax to declare host variables and include tables in the Working-Storage section −

DATA DIVISION.
   WORKING-STORAGE SECTION.
   
   EXEC SQL
   INCLUDE table-name
   END-EXEC.

   EXEC SQL BEGIN DECLARE SECTION
   END-EXEC.
   
   01 STUDENT-REC.
      05 STUDENT-ID PIC 9(4).
      05 STUDENT-NAME PIC X(25).
      05 STUDENT-ADDRESS X(50).
   EXEC SQL END DECLARE SECTION
   END-EXEC.

SQLCA

SQLCA is a SQL communication area through which DB2 passes the feedback of SQL execution to the program. It tells the program whether an execution was successful or not. There are a number of predefined variables under SQLCA pke SQLCODE which contains the error code. The value 000 in SQLCODE states a successful execution.

Syntax

Following is the syntax to declare an SQLCA in the Working-Storage section −

DATA DIVISION.
WORKING-STORAGE SECTION.
	EXEC SQL
	INCLUDE SQLCA
	END-EXEC.

SQL Queries

Let’s assume we have one table named as Student that contains Student-Id, Student-Name, and Student-Address.

The STUDENT table contains the following data −

Student Id		Student Name		Student Address
1001 			   Mohtashim M.		Hyderabad
1002			   Nishant Mapk		Delhi
1003 			   Amitabh Bachan		Mumbai
1004			   Chulbul Pandey		Lucknow

The following example shows the usage of SELECT query in a COBOL program −

IDENTIFICATION DIVISION.
PROGRAM-ID. HELLO.

DATA DIVISION.
   WORKING-STORAGE SECTION.
   EXEC SQL
      INCLUDE SQLCA
   END-EXEC.
   
   EXEC SQL
      INCLUDE STUDENT
   END-EXEC.
   
   EXEC SQL BEGIN DECLARE SECTION
   END-EXEC.
      01 WS-STUDENT-REC.
         05 WS-STUDENT-ID PIC 9(4).
         05 WS-STUDENT-NAME PIC X(25).
         05 WS-STUDENT-ADDRESS X(50).
   EXEC SQL END DECLARE SECTION
   END-EXEC.

PROCEDURE DIVISION.
   EXEC SQL
      SELECT STUDENT-ID, STUDENT-NAME, STUDENT-ADDRESS
      INTO :WS-STUDENT-ID, :WS-STUDENT-NAME, WS-STUDENT-ADDRESS FROM STUDENT
      WHERE STUDENT-ID=1004
   END-EXEC.
   
   IF SQLCODE = 0 
      DISPLAY WS-STUDENT-RECORD
   ELSE DISPLAY  Error 
   END-IF.
STOP RUN.

JCL to execute the above COBOL program −

//SAMPLE JOB(TESTJCL,XXXXXX),CLASS = A,MSGCLASS = C
//STEP001  EXEC PGM = IKJEFT01
//STEPLIB  DD DSN = MYDATA.URMI.DBRMLIB,DISP = SHR
//SYSPRINT DD SYSOUT=*
//SYSUDUMP DD SYSOUT=*
//SYSOUT   DD SYSOUT=*
//SYSTSIN  DD *
   DSN SYSTEM(SSID)
   RUN PROGRAM(HELLO) PLAN(PLANNAME) -
   END
/*

When you compile and execute the above program, it produces the following result −

1004 Chulbul Pandey		Lucknow

The following example shows the usage of INSERT query in a COBOL program −

IDENTIFICATION DIVISION.
PROGRAM-ID. HELLO.

DATA DIVISION.
   WORKING-STORAGE SECTION.
   EXEC SQL
   INCLUDE SQLCA
   END-EXEC.
   
   EXEC SQL
   INCLUDE STUDENT
   END-EXEC.
   
   EXEC SQL BEGIN DECLARE SECTION
   END-EXEC.
      01 WS-STUDENT-REC.
         05 WS-STUDENT-ID PIC 9(4).
         05 WS-STUDENT-NAME PIC X(25).
         05 WS-STUDENT-ADDRESS X(50).
   EXEC SQL END DECLARE SECTION
   END-EXEC.

PROCEDURE DIVISION.
   MOVE 1005 TO WS-STUDENT-ID.
   MOVE  TutorialsPoint  TO WS-STUDENT-NAME.
   MOVE  Hyderabad  TO WS-STUDENT-ADDRESS.
   
   EXEC SQL
      INSERT INTO STUDENT(STUDENT-ID, STUDENT-NAME, STUDENT-ADDRESS)
      VALUES (:WS-STUDENT-ID, :WS-STUDENT-NAME, WS-STUDENT-ADDRESS)
   END-EXEC.
   
   IF SQLCODE = 0 
      DISPLAY  Record Inserted Successfully 
      DISPLAY WS-STUDENT-REC
   ELSE DISPLAY  Error 
   END-IF.
STOP RUN.

JCL to execute the above COBOL program −

//SAMPLE JOB(TESTJCL,XXXXXX),CLASS = A,MSGCLASS = C
//STEP001  EXEC PGM = IKJEFT01
//STEPLIB  DD DSN = MYDATA.URMI.DBRMLIB,DISP=SHR
//SYSPRINT DD SYSOUT = *
//SYSUDUMP DD SYSOUT = *
//SYSOUT   DD SYSOUT = *
//SYSTSIN  DD *
   DSN SYSTEM(SSID)
   RUN PROGRAM(HELLO) PLAN(PLANNAME) -
   END
/*

When you compile and execute the above program, it produces the following result −

Record Inserted Successfully
1005 TutorialsPoint		Hyderabad

The following example shows the usage of UPDATE query in a COBOL program −

IDENTIFICATION DIVISION.
PROGRAM-ID. HELLO.

DATA DIVISION.
   WORKING-STORAGE SECTION.
   
   EXEC SQL
   INCLUDE SQLCA
   END-EXEC.
   
   EXEC SQL
   INCLUDE STUDENT
   END-EXEC.
   
   EXEC SQL BEGIN DECLARE SECTION
   END-EXEC.
      01 WS-STUDENT-REC.
         05 WS-STUDENT-ID PIC 9(4).
         05 WS-STUDENT-NAME PIC X(25).
         05 WS-STUDENT-ADDRESS X(50).
   EXEC SQL END DECLARE SECTION
   END-EXEC.

PROCEDURE DIVISION.
   MOVE  Bangalore  TO WS-STUDENT-ADDRESS.
   EXEC SQL
      UPDATE STUDENT SET STUDENT-ADDRESS=:WS-STUDENT-ADDRESS
      WHERE STUDENT-ID = 1003
   END-EXEC.
   
   IF SQLCODE = 0 
      DISPLAY  Record Updated Successfully 
   ELSE DISPLAY  Error 
   END-IF.
STOP RUN.

JCL to execute the above COBOL program −

//SAMPLE JOB(TESTJCL,XXXXXX),CLASS = A,MSGCLASS = C
//STEP001  EXEC PGM = IKJEFT01
//STEPLIB  DD DSN = MYDATA.URMI.DBRMLIB,DISP = SHR
//SYSPRINT DD SYSOUT = *
//SYSUDUMP DD SYSOUT = *
//SYSOUT   DD SYSOUT = *
//SYSTSIN  DD *
   DSN SYSTEM(SSID)
   RUN PROGRAM(HELLO) PLAN(PLANNAME) -
   END
/*

When you compile and execute the above program, it produces the following result −

Record Updated Successfully

The following example shows the usage of DELETE query in a COBOL program −

IDENTIFICATION DIVISION.
PROGRAM-ID. HELLO.

DATA DIVISION.
WORKING-STORAGE SECTION.

   EXEC SQL
   INCLUDE SQLCA
   END-EXEC.
   
   EXEC SQL
   INCLUDE STUDENT
   END-EXEC.
   
   EXEC SQL BEGIN DECLARE SECTION
   END-EXEC.
      01 WS-STUDENT-REC.
         05 WS-STUDENT-ID PIC 9(4).
         05 WS-STUDENT-NAME PIC X(25).
         05 WS-STUDENT-ADDRESS X(50).
   EXEC SQL END DECLARE SECTION
   END-EXEC.

PROCEDURE DIVISION.
   MOVE 1005 TO WS-STUDENT-ID.
   
   EXEC SQL
      DELETE FROM STUDENT
      WHERE STUDENT-ID=:WS-STUDENT-ID
   END-EXEC.
   
   IF SQLCODE = 0 
      DISPLAY  Record Deleted Successfully 
   ELSE DISPLAY  Error 
   END-IF.
STOP RUN.

JCL to execute the above COBOL program −

//SAMPLE JOB(TESTJCL,XXXXXX),CLASS = A,MSGCLASS = C
//STEP001  EXEC PGM = IKJEFT01
//STEPLIB  DD DSN = MYDATA.URMI.DBRMLIB,DISP=SHR
//SYSPRINT DD SYSOUT = *
//SYSUDUMP DD SYSOUT = *
//SYSOUT   DD SYSOUT = *
//SYSTSIN  DD *
   DSN SYSTEM(SSID)
   RUN PROGRAM(HELLO) PLAN(PLANNAME) -
   END
/*

When you compile and execute the above program, it produces the following result −

Record Deleted Successfully

Cursors

Cursors are used to handle multiple row selections at a time. They are data structures that hold all the results of a query. They can be defined in the Working-Storage Section or the Procedure Division. Following are the operations associated with Cursor −

    Declare

    Open

    Close

    Fetch

Declare Cursor

Cursor declaration can be done in the Working-Storage Section or the Procedure Division. The first statement is the DECLARE statement which is a nonexecutable statement.

EXEC SQL
   DECLARE STUDCUR CURSOR FOR
   SELECT STUDENT-ID, STUDENT-NAME, STUDENT-ADDRESS FROM STUDENT
   WHERE STUDENT-ID >:WS-STUDENT-ID
END-EXEC.

Open

Before using a cursor, Open statement must be performed. The Open statement prepares the SELECT for execution.

EXEC SQL
   OPEN STUDCUR
END-EXEC.

Close

Close statement releases all the memory occupied by the cursor. It is mandatory to close a cursor before ending a program.

EXEC SQL
   CLOSE STUDCUR
END-EXEC.

Fetch

Fetch statement identifies the cursor and puts the value in the INTO clause. A Fetch statement is coded in loop as we get one row at a time.

EXEC SQL
   FETCH STUDCUR
   INTO :WS-STUDENT-ID, :WS-STUDENT-NAME, WS-STUDENT-ADDRESS
END-EXEC.

The following example shows the usage of cursor to fetch all the records from the STUDENT table −

IDENTIFICATION DIVISION.
PROGRAM-ID. HELLO.

DATA DIVISION.
   WORKING-STORAGE SECTION.
   
   EXEC SQL
   INCLUDE SQLCA
   END-EXEC.
   
   EXEC SQL
   INCLUDE STUDENT
   END-EXEC.
   
   EXEC SQL BEGIN DECLARE SECTION
   END-EXEC.
      01 WS-STUDENT-REC.
         05 WS-STUDENT-ID PIC 9(4).
         05 WS-STUDENT-NAME PIC X(25).
         05 WS-STUDENT-ADDRESS X(50).
   EXEC SQL END DECLARE SECTION
   END-EXEC.
   
   EXEC SQL
      DECLARE STUDCUR CURSOR FOR
      SELECT STUDENT-ID, STUDENT-NAME, STUDENT-ADDRESS FROM STUDENT
      WHERE STUDENT-ID >:WS-STUDENT-ID
   END-EXEC.

PROCEDURE DIVISION.
   MOVE 1001 TO WS-STUDENT-ID.
   PERFORM UNTIL SQLCODE = 100
   
   EXEC SQL
      FETCH STUDCUR
      INTO :WS-STUDENT-ID, :WS-STUDENT-NAME, WS-STUDENT-ADDRESS
   END-EXEC
   
   DISPLAY WS-STUDENT-REC
END-PERFORM	
STOP RUN.

JCL to execute the above COBOL program −

//SAMPLE JOB(TESTJCL,XXXXXX),CLASS = A,MSGCLASS = C
//STEP001  EXEC PGM=IKJEFT01
//STEPLIB  DD DSN=MYDATA.URMI.DBRMLIB,DISP=SHR
//SYSPRINT DD SYSOUT=*
//SYSUDUMP DD SYSOUT=*
//SYSOUT   DD SYSOUT=*
//SYSTSIN  DD *
   DSN SYSTEM(SSID)
   RUN PROGRAM(HELLO) PLAN(PLANNAME) -
   END
/*

When you compile and execute the above program, it produces the following result −

1001 Mohtashim M.		Hyderabad
1002 Nishant Mapk		Delhi
1003 Amitabh Bachan		Mumbai
1004 Chulbul Pandey		Lucknow
Advertisements