copy of cobol
TRANSCRIPT
Table of Contents
UNIT 1. Introduction to Language FeaturesCOMMON BUSINESS ORIENTED LANGUAGECOBOL PROGRAM ORGANIZATIONCOBOL LANGUAGE STRUCTURESTRUCTURE OF COBOL PROGRAMCHARACTER SET OF COBOLSAMPLE COBOL PROGRAMCODING FORMATUSER-DEFINED WORDS
UNIT 2. The Organization of a COBOL ProgramIDENTIFICATION DIVISIONENVIRONMENT DIVISIONDATA DIVISIONDATA-ITEMSLEVEL NUMBERSSPECIAL LEVEL NUMBERSW-S DECLARATIONSFILLERPICTURE CLAUSEUSAGE CLAUSEVALUE CLAUSEREDEFINES CLAUSEDULPICATE DATA NAMESRENAMES CLAUSEFIGURATIVE CONSTANTSEDITED FIELDS
MORE EDITING CHARACTER EXAMPLES
UNIT 3. PROCEDURE DIVISIONPROCEDURE DIVISIONCOBOL VERBSPARAGRAPHSTERMINATOR STATEMENTSSCOPE TERMINATORSDISPLAY VERBACCEPT VERBMOVE VERBELEMENTARY & GROUP MOVESCORRESPONDING PHASEREFERENCE MODIFICATIONADD VERBADD CORRESPONDING STATEMENTON SIZE ERROR PHRASENUMERIC DATASUBTRACT VERBSUBTRACT CORRESPONDING STATEMENTMULTIPLY VERBDIVIDE VERBCOMPUTE STATEMENTPERFORM STATEMENTPERFORM THROUGHPERFORM N TIMESPERFORM…VARYING
IN-LINE PERFORMRELATIONAL EXPRESSIONSIF STATEMENTCOMPOUND CONDITIONALSCLASS CONDITIONCONTINUE & NEXT STATEMENTEVALUATE STATEMENTSET TO TRUEINITIALIZE
UNIT 4. FILE HANDLING IN COBOL
FILESFIXED VS VARIABLE LENGTH RECORDSFILE-CONTROL-SEQUENTIALACCESS MODEFILE STATUS CLAUSEI-O CONTROL PARAGRAPHFILE SECTIONFILE OPERATIONSOPEN MODESREAD-SEQUENTIAL ACCESSEND OF FILE PROCESSINGREAD – RANDOM ACCESSREAD – DYNAMIC ACCESSSTART STATEMENTWRITE STATEMENTWRITE…FROMREAD…INTOREWRITE & DELETEAPPENDING TO SEQUENTIAL FILESFILE COMPARISONCLOSE STATEMENTSEQUENTIAL FILESINDEXED FILESINVALID KEYACCESS MODE: SEQUENTIAL & RANDOMACCESS MODE: DYNAMICRELATIVE FILES
UNIT 5. TABLE HANDLING
INTRODUCTION: TABLE HANDLINGOCCURS CLAUSESUBSCRIPTINDEXINGONE DIMENSIONAL TABLETWO DIMENSIONAL TABLEMULTIDIMENTIONAL TABLETABLE-SORTINGSETSEARCHBINARY SEARCH
UNIT 6. Library Services
COPY STATEMENTNESTED COPYCOPY REPLACINGCOPY PSEUDO-TESTREPLACE PSEUDO-TEST
UNIT 7. CHARACTER HANDLING
STRINGUNSTRING STATEMENTINSPECT TALLYING STATEMENTINSPECT REPLACING STATEMENTEXAMINE STATEMENT
UNIT 8. SORT / MERGESORT/MERGESORT STATEMENTMERGE STATEMENTSORT PROCEDURESRELEASE STATEMENTRETURN STATEMENT
UNIT 9. CALL and LINKAGECALL STATEMENTCALL BY CONTENT/REFERENCELINKAGE SECTION
UNIT 1
Introduction To Language Features
Common Business Oriented Language
1959 – New Language is named COBOL
1960 – Codasyl established COBOL maintenance committee
1961 – 1st version of complier made available. Users started writing programs
1968 –2nd version of cobol was approved and standardized by ANSI
1974 – Revised and released as COBOL-74
1985- Revised and released as COBOL-85
To meet the increasing demands for a high level language suitable for business data processing, the United States Department of Defense Convened a Conference on 28 th and 29th of May 1958.Three committee were formed for the actual design of the language.In September 1959 the short term committee submitted a report to the Defense Directorate thus COBOL came into existence.COBOL is known as a structured programming language because it allows programmers to segregate the modules and put them into different paragraphs in a more efficient way.Some of the features of COBOL areIt is English-like and more easily readableEfficient file handling capabilities.More than 70% of business applications are running on COBOLReduces the efforts required for documentation of the program.
The following features are available with VS COBOL II: - MVS/XA and MVS/ESA support - The compiler and the object programs it produces can be run in either 24- or 31-bit addressing mode
COBOL PROGRAM ORGANIZATION
Notes: The four divisions of the COBOL source program are :
IDENTIFICATION DIVISION This division’s primary purpose is to name the program
ENVIRONMENT DIVISION This division is primarily used to tell the computer about the input and output devices such
as files or printers.
IDENTIFICATION DIVISION
ENVIRONMENT DIVISION
DATA DIVISION
PROCEDURE DIVISION
DATA DIVISION
This division describes the data the program will be using and carves out sections of memory to map the data. Here you would distinguish between data, which
will be used for a “ scratch pad” area called WORKING-STORAGE and the holding area for data that will be used by the files.
PROCEDURE DIVISION
The PROCEDURE DIVISION is the section of our program where the logic or commands reside. This is the logic or rules we will use to manipulate the data
defined in the DATA DIVISION to solve a business problem.
Cobol Language Structure
. Characters
· Character String
· COBOL Words
· User-Defined Words
· Reserved Words
· Figurative Words
· Special Registers
· IBM Extensions
· Non-numeric and numeric Literals
Structure of a Cobol Program
Examples
Divisions DATA DIVISION
Sections or Paragraphs PROGRAM-ID
FILE SECTION, 100-PARA
Statements MOVE A TO B
Sentences IF A>B MOVE A TO B ELSE
ADD C TO D
Notes:
All COBOL programs should follow the structure. Rules of coding varies, depending
on the compiler versions but the structure remains same. A period (.) is a must at the end of
each sentence and indicates the end of the sentence.
Character Set of COBOL
COBOL supports the following characters
Numbers : 0-9
Alphabets : a-z, A-Z
Spaces or blanks
Arithmetic operators : ex: **, *, +, -, /
Special characters : ex: - \ / , ;
Notes: The COBOL dictionary words used for coding are called COBOL reserved words and they should not be used as user-defined words. Lower case alphabets can be used for coding depending on the compiler version.comma (,) or space is used as separators for user-defined words.
Sample COBOL Program
Columns1 6 7 8 11 12 72 73 80 * This is a sample program
IDENTIFICATION DIVISION. PROGRAM-ID. SAMPLE. ENVIRONMENT DIVISION. DATA DIVISION. WORKING-STORAGE SECTION. 01 A PIC 9(2) VALUE 20. 01 B PIC 9(2) VALUE 3O. 01 C PIC 9(3) VALUE ZEROS. PROCEDURE DIVISION. DISPLAY ‘THE SUM IS’. ADD A ,B GIVING C. DISPLAY C. STOP RUN.
Notes:1-6 -------------- Sequence numbers7 -------------- Indicator/Comment/Continuation8-11 -------------- Area A12-72 -------------- Area B73-80 -------------- DescriptorThis foil shows a sample COBOL program to ‘ADD’ two numbers and ‘DISPLAY’ the sum. SAMPLE is the program name.SAMPLE, A, B AND C are called user-defined words.A, B,C are called variables or data-items.
Coding Format
Columns Name Purpose
01-06
07
08-11
12-72
73-80
Sequence
Indicator
Area A
Area B
Description
Sequence numbers are generated by Cobol Compiler for each line.To mark an asterisk (*) or a slash (/) for comment line, or a hyphen (-) for continuation of a statement. All division headings, section and paragraph headings and ‘01’ level entries should begin from this area.All Cobol statements and sentences should lie within this area Any thing written in this area is ignored.
Notes: COBOL coding should follow the standard format.The Screen is divided into different areas for the purposes explained above.All statements indicating action are called COBOL verbs and should begin from 12 th column or after.-E.g MOVE, ADD, DIVIDE, STOP RUN
User-defined Words
Valid Invalid Reason
TOTAL-OF-FIGURES DATA Cobol reserved word34B100-PARA1 -48B Hyphen in beginningGROSS-PAY GROSS PAY space in b/w 2 words
Literals Examples
Numeric constants 35, -345.67Alphanumeric constants ‘Leo talstoy’
‘ka01-h215’
Paragraph names, Identifiers, File names can be defined by users.The terms identifiers, data-names, variables, data-items are often used interchangeably indicates memory.
Notes:
All user-defined words should conform to following rules
Length should not exceed 30 characters.
At least one character must be an alphabet.
Spaces and special characters are not allowed.
Word can contain hyphens (-) but not in the beginning or at the end
Cannot be a COBOL reserved word
UNIT 2
THE ORGANIZATION OF A COBOL PROGRAM
IDENTIFICATION DIVISION.PROGRAM-ID. <Pgm-name>AUTHOR. <Pgmr-name> DATE –WRITTEN. <Entry>DATE-COMPILED. <Entry>SECURITY. <Entry>
RequiredRequiredOptionalOptionalOptionalOptional
At least one space required after the period
Notes:The Identification Division must be the first division in every COBOL source program. It must be coded as IDENTIFICATION DIVISION or ID DIVISION followed by a separator period.
IDENTIFICATION DIVISION
ENVIRONMENT DIVISION
ENVIRONMENT DIVISION. CONFIGURATION SECTION. SOURCE-COMPUTER. <Entry>.
OBJECT-COMPUTER. <Entry>. INPUT-OUTPUT SECTION.
FILE-CONTROL.--------------------------------------------------------
I-O-CONTROL. ----------------------------- ----------------------------- Notes: The Environment Division is divided into two sections: The CONFIGURATION SECTION The Configuration Section is an optional section for programs which describe the computer environment on which the program is compiled and executed. The Configuration Section can be specified only in the ENVIRONMENT DIVISION of the outermost program of a COBOL source program. The INPUT-OUTPUT SECTION The Input-Output Section of the Environment Division contains two paragraphs: FILE-CONTROL paragraph I-O-CONTROL paragraph
FILE-CONTROL paragraph
The keyword FILE-CONTROL can appear only once, at the beginning of the FILE-CONTROL paragraph. It must begin in Area A, and be followed by a separator period.
The FILE-CONTROL paragraph is optional.
The FILE-CONTROL paragraph associates each file in the COBOL program with an
external dataset, and specifies file organization, access mode, and other information.
There are three formats for the FILE-CONTROL paragraph:
QSAM, SAM, and VSAM sequential file entries
VSAM indexed file entries VSAM relative file entries.
The FILE-CONTROL paragraph begins with the word "FILE-CONTROL", followed by a
separator period. It must contain one and only one entry for each file described in an FD or SD
entry in the Data Division. Within each entry, the SELECT clause must appear first, followed
by the ASSIGN clause. The other clauses can appear in any order.
I-O-CONTROL paragraph
Specifies information needed for efficient transmission of data between
the external data set and the COBOL program. The series of entries must
end with a separator period
The keyword I-O-CONTROL can appear only once, at the beginning of the
paragraph. The word I-O-CONTROL must begin in Area A, and must
be followed by a separator period.
Each clause within the paragraph can be separated from the next by
a separator comma or a separator semicolon. The order in which
I-O-CONTROL paragraph clauses are written is not significant
DATA DIVISION
Data division is the third and most frequently used division in all programs. Every variable required by the program should be declared in appropriate section of the data division, before using in procedure division The Data Division is divided into three sections: . File Section Defines the structure of data files (including sort-merge files). . Working-Storage Section Describes records and subordinate data items that are not part of data files but are required by the program. . Linkage Section Describes data made available by another program. It usually appears in the called program and describes data items that are referred to by the calling and the called programs. Each section has a specific logical function within a COBOL source program, and each can be omitted from the source program when that logical function is not needed. If included, the sections must be written in the order shown.
DATA DIVISION.
FILE SECTION.
FD . ---------------
----------------
----------------
WORKING-STORAGE SECTION. DATA TYPES
01 VAR-1 PIC A(5). -Alphabetic
01 ID-1 PIC X(10) -Alphanumeric
01 DATA-NAME PIC 9(5) -Numeric
Level number picture data type (length)
Clause
LINKAGE SECTION.
record-description-entry
data-item-description-entry
DATA-ITEMS
Explicitly identifies the data being described
The data-item must be the first word following the level-number.
The data-item values can be changed during program execution.
A data-item name cannot be the same as a section-name or a paragraph
Notes:
Data item is a user-defined word which is associated with Level number.
COBOL Reserved words should not be Data items.
Level Numbers
. Range of level numbers available are 01 to 49 and
66 level specified for RENAMING CLAUSE
77 levels specified exclusively for elementary item
88 levels specified for CONDITION NAMES.
. An elementary item can be declared with level numbers
. 01 and 77 01 and 77 level entries must begin from area A and other level entries can begin
from any where in area A or area B
Notes:
Level represents the nature of a data item.
The level-number specifies the hierarchy of data within a record, and identifies special-purpose data entries. A level- number begins a data description entry, a renamed or redefined item, or a condition-name entry. A level- number has a value taken from the set of integers between 01 and 49, or from one of the special level-numbers, 66, 77, or 88.
Level-number 01 and 77 must begin in Area A and must be followed either by a separator period; or by a space, followed by its associated data-name, FILLER, or appropriate data description clause.
Level numbers 02 through 49 can begin in Areas A or B and must be followed by a space or a separator period.
Level number 66 and 88 can begin in Areas A or B and must be followed by a space.
Single-digit level-numbers 1 through 9 can be substituted for level-numbers 01 through 09.
Successive data description entries can start in the same column as the first or they can be indented according to the level-number. Indentation does not affect the magnitude of a level-number.
When level-numbers are indented, each new level-number can begin any number of spaces to
the right of Area A. The extend of indentation to the right is limited only by the width of Area B.
Higher numbered level(s) represent subordinate definition(s).
Level numbers need not be consecutive(but should be in ascending order)
Special Level Numbers
LEVEL-66 contains a RENAMES clause. It regroups previously defined names LEVEL-77 defines ELEMENTARY items with no subdivision and are unique LEVEL-88 establishes condition-name entries, associated with a VALUE clause 66 data-name-1 renames-clause. 88 condition-name-1 value-clause.
Notes: LEVEL-66 regroups previously defined items. A level-66 entry cannot rename another level-66 entry, nor can it rename a level-01, level-77, or level-88 entry. All level-66 entries associated with one record must immediately follow the last data description entry in that record. LEVEL-77 items are ELEMENATARY items with no subdivision. LEVEL-77 names are unique because they can not bequalified. LEVEL-88 describes condition-names.
LEVEL-88 can be used to describe both elementary and group items.
Describes the characteristics of the data
Picture Clause
CODE Meaning A Alphabetic or space B Blanks or spaces G or N Graphical data 9 Indicates a Numeric X Indicates an Alpha Numeric
P Indicates the position of the assumed Decimal point when the point lies Outside the data item.
V Indicates the position of assumed Decimal point of numeric field.
S Indicates whether the data item signed.
Notes:
Picture clause specifies the data type of an identifier.
Identifier with PIC clause ‘9’ implies that it is numeric data type, which can take art in arithmetic computations. ‘V’ and ‘S’ clauses are allowed with numeric data types only.
‘X’ clause represents an alphanumeric data type which can hold any character including numbers also.
‘A’ clause indicates an alphabetic data type.
Group items are always considered as alphanumeric only. Therefore GROSS-PAY, DEDUCTIONS can not be used for computations
W-S Declarations
WOKING-STORAGE SECTION.
01 PAY. 05 GROSS-PAY.Alternatively 10 BASIC PIC 9(4)V99. 10 DA PIC 9(4)V99.9(4)V9(2) 10 HRA PIC 9(4)V999999V99
05 DEDUCTIONS. 07 PF-DED PIC 9(3)V99. 07 IT-DED PIC 9(3)V99. 05 NET-PAY PIC 9(4)V99. 05 NAME PIC A(5).AAAAA 05 E-CODE PIC X(6).XXXXXX
Notes: Pay, gross-pay, deductions are called group items and they don’t have PICTURE clause. Other elements with picture clause are called elementary items, which cannot be broken further. Pay is a Group item is divided into Gross-pay, Deductions, net-pay, name, e-code further Gross-pay sub-divided into Basic, DA, HRA and DEDUCTIONS sub-divided into PF-DED and IT-DED.
FILLER
FILLER is a COBOL Reserved Word used to describe data fields that will not
be referenced in the PROCEDURE DIVISION.
If the data-name of FILLER clause is omitted, the data item being described is treated as
though it was FILLER
01 EMPLOYEE-RECORD.
05 EMPLOYEE-TYPE PIC X.
05 EMPLOYEE-SERIAL PIC X(6).
05 EMPLOYEE-NAME PIC X(30).
05 PIC X(2).
05 EMPLOYEE-ADDRESS PIC X(60).
05 FILLER PIC X(34).
Notes:
FILLER is a data item that is not explicitly referred to in a program. The key word FILLER is optional.
If specified, FILLER must be the first word following the level-number.
IF data-name or FILLER clause is omitted, the data item being described is treated as though FILLER had been specified.
The VALUE clause may be used on FILLER items, e.g. to assure BLANKS in header lines between fields.
In a MOVE CORRESPONDING statement ,or in an ADD CORRESPONDING or SUBTRACT CORRESPONDING statement ,FILLER items are ignored.
In an INITIALIZE statement, elementary FILLER items are ignored.
USAGE Clause <level number> data-name [PIC X(n)] [USAGE] COMP
COMP-1 COMP-2
COMP-3
COMP - Binary Representation Size: Half/Full/Double word COMP-1 - Hexa Decimal Representation Size: Full word for Float COMP-2 - Hexa Decimal Representation Size: Double word for Float
for float COMP-3 - Packed Decimal Representation Size: round(n/2)+1
Where n is number of digits. Notes:
The USAGE clause can be specified for a data description entry with a level-number other than 66 or 88.
However, if it is specified at the group level, it applies to each Elementary item in the group. The usage of an elementary item must not contradict the usage of a group to which the elementary item belongs.
The USAGE clause specifies the format in which data is represented in storage. The format can be restricted
if certain Procedure Division statements When the USAGE clause is not specified at either the group or elementary level, it assumed that the usage is DISPLAY
Computational ( COMP) Usage
When usage is specified as COMP, the numeric data item is represented in pure binary. The item
must be an integer( no assumed decimal point is allowed). Such that data items are often used
as subscripts.The PICTURE of a COMP item should not contain any character other than 9, S.
COMPUTATIONAL-1 (COMP-1) Usage
If the usage of a numeric data item is specified as COMP-1, it will be represented in one word
in the floating –point form. The number is actually represented in Hexa decimal (base 16).
Such representation is suitable for arithmetic operations. The PICTURE clause cannot be specified
for COMP-1 items.
COMPUTATIONAL-2(COMP-2)Usage
This usage is same as COMP-1, except that the data is represented internally in two words.
The advantages is that this increases the precision of the data which means that more significant
digits can be available for the item. The PICTURE clause cannot be specified for COMP-2 items.
COMPUTATIONAL-3(COMP-3)Usage
In this form of internal representation the numeric data is the decimal form, but one digit
takes half-a-byte. The sign is stored separately as the right most half –a-byte regardless of whether
S is specified in the PICTURE or not. The hexa decimal number C or F denotes a positive sign
and the Hexa –decimal number D denotes a negative sign. Inorder that data fields can start and end
on byte boundaries, numbers with an even number of digits are stored with an extra half-byte of
zeroes on the left hand side.
PICTURE S9(5)V9(3) USAGE IS COMP-3
Will require 5 bytes to be stored internally. Only the characters 9,S, V and P can be used in the
PICTURE of a COMP-3 item.
Value Clause
Value Clause defines the initial value of a data item Must not be used for items declared in FILE SECTION. Can also specify FIGURATIVE CONSTANTS. If defined at the group level can be used for array declaration also
EXAMPLES.01 NUM-1 PIC 9(3) VALUE 245.01 E-CODE PIC X(6) VALUE “E10K3”.
At group level contents
01 GROUP-ITEM VALUE IS ‘ER34155’ 05 E-ITEM-1 PIC X(2). ‘ER’ 05 E-ITEM-2 PIC XXX ‘341’
05 E-ITEM-3 PIC X(3) ‘55’
Group item is considered as alphanumeric.
Notes:
Assigning values to identifiers is called initialization. If variables are not initialized, then they may contain any value, which was stored at the time of last execution of program. It is advised to always initialize working-storage variables.
REDEFINES Clause
Two or more data items can share the same working storage area by
REDEFINING a storage area.
Level number data name-1 REDEFINES data-name-2
Level numbers of data-name-1 and data-name-2 must be identical
The redefines clause must immediately follow data-name-I
must not be used for level number 66 or 88 items.
Data-name-1 should not contain VALUE clause
Multiple redefinition is allowed
Notes:
Two or more storage areas defined in the data sometimes may not be used simultaneously, in such
cases, only one storage area can serve the purpose of two or more areas if the area is defined.
The REDEFINES clause used allows the said area to be referred to by more than one data name
with different sizes and pictures.
ILLUSTRATES REDEFINES CLAUSE
DATA DIVISION. WORKING-STORAGE SECTION. 01 X1
02 Y PIC 99.02 Y1 REDEFINES Y PIC XX.
01 X302 Z PIC X VALUE “M”.02 ZZ PIC X (25) VALUE ALL “*”.02 ZZZ PIC X (45) VALUE ALL “- “.
01 X4 REDEFINES X3.02 FILL1 PIC X.02 FILL2 PIC X (70).
01 X5 REDEFINES X4.02 BUFFER PIC X (71).
PROCEDURE DIVISIONPARA 1.
MOVE 20 TO Y. DISPLAY X1. MOVE “A1” TO Y1. DISPLAY X1 DISPLAY X3. DISPLAY X4.
DISPLAY X5. STOP RUN.
Duplicate Data Names
Are allowed, provided they belong to a group item
01 Pay-Rec.02 Id-numbers PIC 9(5).02 Name PIC X (25).02 Dept PIC X (20).
01 Print-Rec.02 Filler PIC X (5).02 Id-numbers PIC X (5)02 Filler PIC X (5).02 Name PIC X (25).02 Dept PIC X (920).
MOVE Id-Numbers (OF | IN) Pay-Rec TO Id-Numbers (OF | IN)Print-Rec.
* OF and IN are called Qualifiers. To move the data stored in the four fields of Pay-Rec. the four MOVE statements serve the purpose. Using the MOVE CORRESPONDING statement the same can be accomplished.
RENAMES Clause
Syntax:66 data-name-1 RENAMES data-name-2 THRU data-name-3
E.g. :01 PAY – REC.
02 FIXED-PAY.05 BASIC PIC 9(6) V99.05 DA PIC 9(6) V99.
02 ADDITIONAL-PAY.05 HRD PIC 9(4) V99.05 INCENT PIC 9(3) V99.
02 DEDUCTIONS.05 PF PIC 9(3) V99.05 IT PIC 9(4) V99.05 OTHER PIC 9(3) V99.
66 PAY-OTHER-THAN-BASIC RENAMES DA THRU INCENT.66 IT-AND-PF-DEDUCTIONS RENAMES PF THRU IT.
ILLUSTRATES RENAMES CLAUSE
DATE DIVISION.
WORKING-STORAGE SECTION.
01 PAY
02 FIXED-PAY
10 E-BASIC PIC 9(6). 99
10 E-DA PIC 9(6). 99.
05 ADDL-PAY.
10 HRA PIC 9(4). 99.
10 INCENTIVE PIC 9(3). 99.
05 DEDUCTIONS.
10 E-PF PIC 9(3). 99.
10 E-IT PIC 9(4). 99.
10 OTHERS PIC 9(3). 99.
66 PAY-LESS-BASIC RENAMES E-DA THRU INCENTIVE.
66 IT-AND-PF RENAMES E-PF THRU E-IT.
PROCEDURE DIVISION.
MAIN-PARA
MOVE-123456.78 TO E-BASIC.
MOVE 234567.89 TO E-DA.
MOVE 1234.56 TO HRA.
MOVE 123.45 TO INCENTIVE.
MOVE 123.45 TO E-PF.
MOVE 1234.56 TO E-IT.
MOVE 123.45 TO OTHERS.
DISPLAY PAY.
DISPLAY FIXED-PAY.
DISPLAY ADDL-PAY.
DISPLAY DEDUCTIONS.
DISPLAY PAY-LESS-BASIC.
DISPLAY IT-AND-PF.
STOP RUN.
Figurative Constants
Constants frequently used by most programs
Figurative Constants Meaning
HIGH-VALUE(S) Represents the highest and lowest
LOW-VALUES (S) value in the collating sequence.
ZERO, ZEROS, ZEROES One or more Zeroes
SPACE (S) One or more blanks
Example 01 ID-1 PIC X(3) VALUE SPACES.
Collating sequence is the order in which the characters are compared by the system.
Notes:
Figurative constants are reserved words that name and refer to specific constant values.
Edited Fields
Move 345.46 to a field of picture 9(3)v99 & display or print You may see different number in result
Characters must be edited before report is taken to suppress leading zeros, to include currency signs or to include date separators.
Editing Codes Effect
Z Leading Zeros if any will be suppressed* Leading Zeros are replaced by asterisks(*)$ Currency sign appears in the left most of the
field.- Appears at left or right of the field as specified in
the picture clause if value is negative
+ Appears if value is positive, else minus sign appears
Editing Codes are specified in the picture clause for variables intended for report purpose.
These variables cannot be used for arithmetic calculations.
More Editing Characters
EDIT CODES
CR or DB
.
,
B
0
-(hyphen) / (slash)
BLANK WHEN ZERO
MEANING
To be specified in the right most position of the pic clause. Appears only if the value is negative ,if value is positive it replaced by two characters.
Stands for decimal point. Cannot be specified with V clause
Inserted in the position where specified
Blank is appeared
Zero is appeared. To be specified left most position of pic clause.
Used as date separators. Appears where specified.
Sets all null values to blanks
EXAMPLES
DATA
PIC CLAUSEUNEDITED
PIC CLAUSEEDITED
EDITEDVALUE
02346 9(5) ZZ999 2346
0005 9(4) ZZ99 05
03.42 99V99 Z999 003
0.007 9V999 ZV999 007
05634 9(5) **999 *5634
00143 9(5) $9(5) $00143
453 9(3) $**999 $**453
-0453 s9(4) -ZZ9(2) - b453
-0453 s9(4) 9999- 0453-
453 9(3) 999- 453
-453 s9(3) 999+ 453-
70.46 99V99 99.99- 70.46
156758 9(6) 99/99/99 15/67/58
00 99V9 99.9 Blank when zero
0.00
8654 9(4) 99b9b9 86b5b4
24 99 9900 2400
Notes:
The above table shows contents of unedited fields in the first column. Contents of edited fields
after moving the data-1 shown in last column.
Edited fields (Fields with editing codes) cannot take part in arithmetic computations. Moving of numeric edited fields to unedited fields is illegal.
UNIT 3
PROCEDURE DIVISION
PROCEDURE DIVISION
PROCEDURE DIVISION[USING <DATA-ITEM1>, <DATA-ITEM2>.MAIN-PARA. DISPLAY ‘ENTER VALUE OF A:’. ACCEPT A. DISPLAY ‘ENTER VALUE OF B:’. ACCEPT A. MOVE A TO B. ADD A TO B. DISPLAY ‘A VALUE :’ A. DISPLAY ‘B VALUE :’ B. --------------------------------- --------------------------------
STOP RUN.
Notes :
Procedure Division can consists of
Sections (Optional)Paragraphs(Optional)Statements.
While coding, we must follow the following Hierarchy:SECTION------- PARAGRAPHS ------ STATEMENTSOrPARAGRAPH------- STATEMENTSOr
STATEMENTS
COBOL VERBS
All instructions are coded in Procedure division. BASIC COBOL VERBS
• MOVE
• ACCEPT
• DISPLAY
• PERFORM
• GOTO
• STOP RUN
• CALL
• COPY
• SORT
• MERGE
• FILE OPERATIONS
• CHARACTER
HANDLING
• TABLE HANDLING
• CONDITIONS
• ARITHMETIC VERBS
Notes:
Arithmetic Verbs : ADD, SUBTRACT, MULTIPLY, DIVIDE, COMPUTE
Conditions : IF….ELSE, EVALUATE
File handling : READ, WRITE, REWRITE, DELETE
Character handling : INSPECT, STRING, UNSTRING
Table handling : SET, SEARCH
Paragraphs
Paragraphs are building blocks of the PROCEDURE DIVISION
PROCEDURE DIVISION.MAIN-PARA. STATEMENT1. STATEMENT2. --------------------- --------------------- ----------------------PARA-100. ----------------------- -------------------------
Notes:
A paragraph-name must begin in Area A and must be followed by a separator period. A paragraph-name need not be unique because it can qualified by a SECTION name. Paragraph-names need NOT contain any alphabetic character (i.e. can be all numeric).A paragraph ends at:• The next paragraph-name or section header• The end of the PROCEDURE DIVISION• The Scope terminator END-PARAGRAPH
Terminator statements
EXIT PROGRAM.The EXIT PROGRAM statement specifies the end of a called program and returns control to the calling program
STOP RUN.The STOP RUN statements halts the execution of the object program, and returns control to the system
GOBACK.The GOBACK statement functions like the EXIT PROGRAM statement When it is coded as part of a called program and like the STOP RUN when coded in a main program Notes:
If these statements are not the last statements in a sequence, statements following them will not be executed.
Scope Terminators
Explicit scope terminators mark the end of certain PROCEDURE DIVISION statements. Explicit scope terminators are COBOL Reserved Words.END-ADD END-SEARCH END-CALL END-MULTIPLY END-START END-COMPUTE END-PERFORM END-STRING END-DELETE END-READ END-DIVIDE END-UNSTRINGEND-EVALUATE END-REWRITE END-WRITEEND-IF An explicit Scope Terminator is paired with the unpaired occurrence of the verb. An implicit Scope Terminator is a separator period.
Notes:
Example: PERFORM PARA-1 UNTIL A > 10 STATEMENT1 STATEMENT2 ------------------- ------------------- --------------------END-PERFORM.Period(.) should not encounter in between PERFORM and END-PERFORM. Since it indicates end of the PERFORM statement, then compiler error will raise.
Display verb
The function of the DISPLAY statement is to display low-volume results on the operator’s console or some other hardware device.Syntax : >>____DISPLAY_____ __identifier-1___ __ | _____________________________________________> | _ literal-1______| e.g: PROCEDURE DIVISION.DISP-PARA. DISPLAY SRCH-ARG ‘NOT IN TABLE.’. ---------------------------------- ------------------------------- DISPLAY ‘HELLO HOW ARE YOU’.
Notes:
The DISPLAY statement transfers the contents of each operand to the output device. The contents are displayed on the output device in the order, left to right, in which the operands are listed. WITH NO ADVANCING When specified, the positioning of the output device will not be changed in any way following the display of the last operand.
ACCEPT Verb
Format 1 transfers data from an input/output device into identifier-1.
When the FROM phrase is omitted, the system input device is assumed. Format 1 is useful for exceptional situations in a program when operator intervention (to supply a given message, code, or exception indicator) is required.
Format 1 : >>__ACCEPT______identifier-1___ __________________________________________><
| _ FROM__ _mnemonic-name-1___ _| | _ environment-name _ |
77 SEARCH-VALUE PIC X(10).…. ACCEPT SEARCH-VALUE FROM SYSIN.
Notes:
The ACCEPT statement transfers data into the specified identifier. There is no editing or error checking of the incoming data. If the source of the ACCEPT statement is a file and identifier-1 is filled without using the full record delimited by the record terminator, the remainder of the input record is used in the next ACCEPT statement for the file. The record delimiter characters are removed from the input data before the input records are moved into the ACCEPT receiving area. If the source of the ACCEPT statement is a terminal, the data entered at the terminal, followed by the enter key, is treated as the input data. If the input data is shorter than identifier-1, the area is padded with spaces.
MOVE Verb
MOVE verb is used to copy the contents of an identifier into another identifier. MOVE <identifier-1> Or TO <identifier-2>[<identifier-3>,……….]. <literal-1> E.g.: MOVE A TO B,C,DMOVE dataname-1 to dataname-2MOVE 345 to num-1MOVE ‘345’ TO KMOVE ‘XYZ’ TO data-name-1 If the length of the receiving field is less than the length of sending field then truncation occurs.
Notes:
The MOVE statement transfers data from one area of storage to one or more other areas. An index data item cannot be specified in a MOVE statement. If the sending field(identifier-1) is reference-modified, subscripted, or is an alphanumeric or alphabetic function-identifier, the reference-modifier, subscript, or function is evaluated only once, immediately before data is moved to the first of the receiving operands.
Elementary & Group Moves
The receiving or sending field of a MOVE statement can be either an elementary item or a group item.When both the fields are elementary items the data movement is known as an elementary move. When at least one of the fields is a group item, it is called group move. 01 MSG-FLD PIC X(10).01 DATA-FLD PIC X(10).01 OLD-ADDR. 05 NO PIC X(5). 05 NAME PIC X(15). ------------------------------- -------------------------------01 NEW-ADDR. 05 N-NO PIC X(5). 05 N-NAME PIC X(15). ------------------------------- ------------------------------- MOVE ‘OUT OF SEQUENCE’ TO MSG-FIELD MOVE SPACES TO OLD-ADDR, NEW-ADDR MOVE DATA-FLD TO MSG-FIELD. MOVE NEW-ADDR TO OLD-ADDR
Notes:
Elementary move - Both sending and receiving data items are elementary items- Data conversion may take place, as well as editing or de-editing- On alphabetic moves, all necessary space-fill or truncation will occur Group Move - Both sending and receiving data items are group items- No data conversion takes place
CORRESPONDING Phrase
01 STRUCT-1. 03 FIELD-A PIC 9(9) VALUE 123456789. 03 FIELD-B PIC X(5) VALUE “abcde”. 03 FIELD-C PIC 9(4)V99 VALUE 1234.56. 03 FIELD-D PIC 9(4)V99 VALUE 123456789.01 STRUCT-2. 10 FIELD-C PIC Z(4).99. 10 FILLER PIC XXX. 10 FIELD-B PIC X(5). 10 FILLER PIC XXX. 10 FIELD-A PIC Z(9) 10 FILLER PIC XXX. MOVE CORRESPONDING STRUCT-1 TO STRUCT-2 Statement moves 3 fields but gives warning.
Given the data definitions in the visual, the MOVE CORRESPONDING statements in the visual move three fields ( FIELD-S, FIELS-B and FIELD-C) but gives a warning message similar to the one below
ILLUSTRATES MOVE CORRESPONDING
DATA DIVISION WORKING – STORAGE SECTION.01 DATA-1
05 E-ID PIC 9(5) VALUE 2345.05 E-NAME PIC X (25) VALUE ALL “N”.05 E-DEPT PIC X (20) VALUE ALL “D”05 E-BASIC PIC 9(4) V99 VALUE 1234.67.
01 DATA-2.05 FILLER PIC X(5)05 E-ID PIC 9(5)05 FILLER PIC X(5)05 E-NAME PIC X (25).05 FILLER PIC X(5).05 E-DEPT PIC X(20)05 FILLER PIC X(5)05 E-BASIC PIC 9(4). 99
PROCEDURE DIVISION. PARA 1. MOVE E-ID OF DATA-1 TO E-ID OF DATA-2 MOVE E-NAME OF DATA-1 TO E-NAME OF DATA-2. MOVE E-DEPT OF DATA-1 TO E-BASIC OF DATA-2. DISPLAY DATA-1 DISPLAY DATA-2 MOVE SPACES TO DATA-2. MOVE CORRESPONDING DATA-1 TO DATA-2. DISPLAY DATA-1 DISPLAY DATA-2. STOP RUN.
Reference Modification
• Reference Modification defines a data item by specifying its leftmost character and optionally, a length
MOVE data-name1(begin : [length]) TO data-name2
• If ‘Length’ is omitted, the data item continues to rightmost character of data-name1 (the colon is required).
• The data name must have usage DISPLAY. It may be qualified or subscripted. When qualified or subscripted, the reference modification is specified last.
WORKING-STORAGE SECTION.
01 CAT-TYPE PIC X(15) VALUE 'CALICO'. 01 DOG-TYPE PIC X(15) VALUE 'SCHNAUZER'. 01 CAT-ABBREV PIC X(5). 01 DOG-END PIC X(10). PROCEDURE DIVISION.
*Reference Modification Example Number 1: (From position 1:For 5 positions.) MOVE CAT-TYPE(1:5) TO CAT-ABBREV.
*This will move "CALIC" to CAT-ABBREV. (The letters from position 1 of CAT-TYPE for 5 positions.)
DISPLAY CAT-ABBREV.
*Reference Modification Example Number 2: (From position 2:For 4 Bytes.)
MOVE CAT-TYPE(2:4) TO CAT-ABBREV.
*This will move "ALIC" to CAT-ABBREV2. (The letters from position 2 of CAT-TYPE for 4 positions.)
DISPLAY CAT-ABBREV.
*Reference Modification Example Number 3: (From position number 5 to the end of the field.) MOVE DOG-TYPE(5:) TO DOG-END.
*This will move "AUZER" to DOG-END. (The letters from position 5 of DOG-TYPE to the end of DOG-TYPE.)
DISPLAY DOG-END.
ADD Verb
All identifiers (or literals) preceding the word TO are added together, and then this sum is added to, and replaces, each identifier-2. The action is repeated in order left-to- right for each identifier-2. Identifiers must be elementary numeric items.
Format 1 :
>>___ADD_______ identifier-1_ _|__ To _____identifier-2__ _ ______ _______|____> |_literal-1___| |_ROUNDED _|
>___ _______________________________________ ___________________________> |_ ____ __SIZE ERROR imperative-statement-1______|
>___ ________________________________________ ___________________________>
|_ NOT___ ______ ___SIZE ERROR__imperative –statement_2_|
>___ _______ ___________________________________________________________> |_ END-ADD_|
In Format 1, all identifiers or literals preceding the key word TO are added together, and this sum is stored in a temporary data item. This| temporary data item is then added to each
successive occurrence of identifier-2, in the left-to-right order in which identifier-2 is specified. Identifier must name an elementary numeric item.Literal must be a numeric.The ADD statement sums two or more numeric operands and stores the result.Example :
ADD A TO B. ADD 112 TO B. ADD A TO B ON SIZE ERROR GO TO ERR-PARA.
ADD Verb(Continue……)
The operands preceding the GIVING are added together and the sum replaces the value of each identifier-3. Identifiers must be elementary numeric items, except when following GIVING then they may also be numeric –edited.Format 2 :
>>___ADD_______ identifier-1_ _|__ _ _ __ _ identifier2____________________> |_literal-1___| |_TO_| |_literal-2______|
>___ GIVING ___________identifier-3__ ______________ _| ________________ > |_ ROUNDED__|
>___ _____________________________________________________ __________ > |_ _________ ___SIZE ERROR__imperative –statement_1_|
>___ ____________________________ _________________________________ > |_ NOT___ ______ _SIZE ERROR__imperative –statement_2_| |_ ON_|
>___ _______ _______________________________________________________ > |_ END-ADD_|
In Format 2, the values of the operands preceding the word GIVING are added together, and the sum is stored as the new value of each data item referenced by identifier-3. Identifier must name an elementary numeric item, except when following the word GIVING. Each identifier following the word GIVING must name an elementary numeric or numeric-edited itemLiteral must be a numeric. Example : ADD A TO B GIVING C
ADD CORRESPONDING Statement
•Elementary data items within identifer-1 are added to, and stored in the corresponding elementary data items with identifer-2..ADD CORRESPONDING identifiers must be group items
Format : >>___ADD_______ CORRESPONDING_ ___identifier-1___ TO___ identifier-2____________> |_CORR___________| >___ ______________ __ ______________________________________ ________________ > |_ ROUNDED__| | _ ___ __SIZE ERROR____ imperative-statement-1_| |_ ON_ | >___ _____________________________________________ ___________________________ > |_NOT___ ______ __SIZE ERROR__imperative –statement_1_| |_ON___|>___ _____________________________________________ ___________________________ > |_ NOT___ ______ _SIZE ERROR__imperative –statement_2_| |_ ON_| >___ _______ __________________________________________________________________ > |_ END-ADD_|
ON SIZE ERROR Phrase
If the value of an arithmetic evaluation exceeds the largest value that can be contained in a result, then a size error condition exists.
The SIZE ERROR condition applies to final results, not intermediate calculations
If ON SIZE ERROR phrase is not specified, then truncation of the results will occur.
If ON SIZE ERROR phrase is specified, the imperative statement (in ON SIZE ERROR) is taken, following which control is transferred to the end of the arithmetic statement.
For ADD CORRESPONDING or SUBTRACT CORRESPONDING, the ON SIZE ERROR imperative is not taken until all individual additions or subtractions have been completed.
A size error condition can occur in three different ways
. When the absolute value of the result of an arithmetic evaluation, after decimal point alignment,
exceeds the largest value that can be contained in the result field
. When division by zero occurs
. In an exponential expression, as indicated in the following table
The size error condition applies only to final results, not to any intermediate results
Size error Action taken when a size error clause is present
Action taken when a size error clause is not present
Zero raised to zero power
The size error imperative is executed
The value returned is 1, and message is issued
Zero raised to a negative power
The size error imperative is executed
Program is terminated abnormally
A negative number raised to a fractional power
The size error imperative is executed
The absolute value of the base is used, and a message is issued.
NUMERIC Data
Types of numeric items are: Binary Packed decimal. (internal decimal) Floating point representation. The PICTURE character-string can contain only the symbols 9, P, S, and V The number of digit positions must range from 1 through 18, inclusive If unsigned, the contents of the item in standard data format must contain a combination of the Arabic numerals 0-9. If signed, it may also contain a +, -, or other representation of the operation sign
Notes:
A VALUE clause can specify a figurative constant ZERO
SUBTRACT Verb
Format 1 : >>___SUBTRACT_______ identifier-1_ _|__ FROM____________________________> |_literal-1___| > ______identifier-2__ ___ _|________________________________________________> | _ ROUNDED ____| >___ ________________________________________ ___________________________> |_ ____ __SIZE ERROR imperative-statement-1______| |_ON _| >___ ________________________________________ ___________________________> |_ NOT___ ______ ___SIZE ERROR__imperative –statement_2_| >___ _______ _________________________________________________> |_ END-SUBTRACT_|
All identifiers or literals preceding the key word FROM are added together and this sum is subtracted from and stored immediately in identifier-2. This process is repeated for each successive occurrence of identifier-2, in the left-to-right order in which identifier-2 is specified.
SUBTRACT Verb(Continue………….)
Format 2 : >>___SUBTRACT_______ identifier-1_ _|__ FROM ___ _ identifier-2__ _______________> |_literal-1___| |_literal-2______| >___ GIVING ___________identifier-3__ ______________ _| _________________________ > |_ ROUNDED__| >___ ____________________________________________ ____________________________ > |_ _______ ___SIZE ERROR__imperative –statement_1_| |_ ON _| >___ ____________________________________________ ____________________________ > |_ NOT___ ______ _SIZE ERROR__imperative –statement_2_| |_ ON_| >___ _______ __________________________________________________________________ > |_ END-SUBTRACT_|
All identifier or literals preceding the key word FROM are added together and this sum is subtracted from identifier-2 or literals-2. The result of the subtraction is stored as the new value of
each data item referenced by identifier-3.
Notes:
Example: 1. SUBTRACT A FROM B. The value of A subtttracted from the value of B and then the resultant value will be stored in B.
2. SUBTRACT 9 FROM C.
3. SUBTRACT C FROM 9. Is not valid because 9 is a Literal.
SUBTRACT CORRESPONDING Statement
Format : >>___SUBTRACT____ CORRESPONDING_ ___identifier-1__ FROM_________________> |_CORR__________| >___ identfier-2____ __ ___________ _________________________________________ > |_ ROUNDED__| >___ _________________________________________ ____________________________ > |____ ______ __SIZE ERROR__imperative –statement_1_| |_ON___|>___ ________________________________________ ____________________________ > |_ NOT___ ______ _SIZE ERROR__imperative –statement_2_| |_ ON__| >___ _______ ______________________________________________________________ > |_ END-SUBTRACT_|
Elementary data items within identifier-1 are subtracted from, and the results are stored in, the corresponding elementary data items within identifier-2.
MULTIPLY Verb
Format 1 :
>>___MULTIPLY_______ identifier-1___ ___BY____identifier-2___ ______________| __________> |_ literal-1________|
>___ _______________________________________________________________________________ >
|____ ______ __SIZE ERROR__imperative –statement_1_| |_ON___|
>___ _________________________________________________ ____________________________ > |_ NOT___ ______ _SIZE ERROR__imperative –statement_2_|
|_ ON__| >___ _______ ________________________________________________________________________ >< |_ END-MULTIPLY_|
In Format 1, the value of identifier-1 or literal-1 is multiplied by the value of identifier-2; the product is then placed in identifier-2. For each successive occurrence of identifier-2, the multiplication takes place in the left-to-right order in which identifier-2 is specified.
MULTIPLY Verb(Continue…..)
Format 2 :
>>___MULTIPLY_______ identifier-1_ _|__ BY_______ _ identifier-2__ ______________> |_literal-1___| |_literal-2______|
>___ GIVING ___________identifier-3__ ______________ _| _______________________ > |_ ROUNDED__|
>___ _____________________________________________________ ________________ > |_ _______ ___SIZE ERROR__imperative –statement_1_| |_ ON _|
>___ _____________________________________________________ ________________> |_ NOT___ ______ _SIZE ERROR__imperative –statement_2_| |_ ON_|
>___ _______ ______________________________________________________________ > |_ END-MULTIPLY_|
In Format 2, the value of identifier-1 or literal-1 is multiplied by the value of identifier-2 or literal-2.The product is then stored in the data item(s) referenced by identifier-3.
DIVIDE Verb
Format 1 :
>>___DIVIDE_____ _____ identifier-1_ _|__ INTO__________identifier-2____ _____ __ |____>
|_literal-1___| |_ROUNDED _|
>___ ________________________________________________ ____________________________>
|_ ____ __SIZE ERROR imperative-statement-1____________|
|_ON _|
>___ _________________________________________________ ____________________________>
|_ NOT___ ______ ___SIZE ERROR__imperative –statement_2_|
|_ON __|
>___ _______ ______________________________________________________________________>
|_ END-DIVIDE_|
In Format 1, the value of identifier-1 or literal is divided into the value of identifier-2, and the quotient is then stored in identifier-2. For each successive occurrence of identifier-2, the division takes place in the left-to-right order in which identifier-2 is specified.
DIVIDE Verb(Continue……)
Format 2 :
>>___DIVIDE_______ identifier-1_ _|__ INTO_______ _ identifier-2__ ___________________________>
|_literal-1___| |_literal-2______|
>___ GIVING ___________identifier-3__ ______________ _| ___________________________________ >
|_ ROUNDED__|
>___ _____________________________________________________ ____________________________ >
|_ _______ ___SIZE ERROR__imperative –statement_1_|
|_ ON _|
>___ _____________________________________________________ ____________________________>
|_ NOT___ ______ _SIZE ERROR__imperative –statement_2_|
|_ ON_|
>___ _______ _________________________________________________ >
|_ END-DIVIDE_|
In Format 2, the value of identifier-1 or literal-1 is divided into or by the value of identifier-2 or literal-2. The value of the result is stored in each data item referenced by identifier-3.
COMPUTE Verb
Format :
>>___COMPUTE_______ identifier-1_ ____________ _|____ _ =______ __________________________>
|_ ROUNDED _| |_ EQUAL_|
>___ arithmetic –expression________________________________________________________________ >
>___ _____________________________________________________ ____________________________ >
|_ _______ ___SIZE ERROR__imperative –statement_1_|
|_ ON _|
>___ _____________________________________________________ ____________________________ >
|_ NOT___ ______ _SIZE ERROR__imperative –statement_2_|
|_ ON_|
>___ _______ __________________________________________________ >
|_ END-COMPUTE_|
The arithmetic expression is calculated and replaces the value for each identifier-1 item. Valid operators allowed in the expression are:
+ addition - subtraction
* multiplication / division
** exponentiation
Notes:
The COMPUTE statement assigns the value of an arithmetic expression to one or more data items.
With the COMPUTE statement, arithmetic operations can be combined without the restrictions on receiving
data items imposed by the rules for the ADD, SUBTRACT, MULTIPLY, and DIVIDE statements.
Must name elementary numeric item(s) or elementary numeric-edited item(s).
Can name an elementary floating-point data item.
The word EQUAL can be used in place of =.
An arithmetic expression ca consist of any of the following:
1. An identifier described as a numeric elementary item
2. A numeric literal
3. The figurative constant ZERO
4. Identifiers are literals, as defined in terms 1,2, and 3, separated by arithmetic operators
5. Two arithmetic expressions, as defined in items 1,2,3, and/or 4, separated by an arithmetic operator
6. An arithmetic expression, as defined in items 1,2,3,4 and/or 5, enclosed in parentheses.
When the COMPUTE statement is executed, the value of the arithmetic expression is calculated, and this value is stored as the new value of each data item referenced by identifier-1.
PERFORM Statement
PERFORM Paragraph-name/Section-header
Transfer the control to the specified paragraph or section and expects the control back after
executing the paragraph.
PERFORM Para-name-1 [ THROUGH (or) THRU Para-name-n]
Notes:
PERFORM types
PERFORM para-name
PERFORM para-name N TIMES
PERFORM para-name VARYING K FROM M BY N
UNTIL CONDITION K>20
PERFORM para-name VARYING K FROM M BY N UNTIL CONDITION K>20 AFTER VARYING….
PERFORM THROUGH
PROCEDURE DIVISION.
100-MAIN-PARA.
PERFORM 200-PARA THRU 500-PARA.
STOP RUN.
200-PARA.
* Statements.
400-PARA.
* Statements
500-PARA.
* Statements
300-PARA.
* Statement - Not executed
All the paragraphs between 200-PARA and 500-PARA are executed.
PERFORM…………N times
PERFORM PARA-NAME-1[THROUGH (or) THRU PARA-NAME-N] N TIMES.
EX:PERFORM PARA-1000 15 TIMES.
PERFORM PARA-1000 THRU PARA-4000 15 TIMES.
PARA-1000.
ADD A TO B. ------------------------
-------------------------PARA-2000.
SUBTRACT A FROM B. ------------------------------- --------------------------------
PARA-4000. MULTIPLY A BY B. ----------------------------
PERFORM…………VARYING
PERFORM PARA-NAME-1 [THRU (or) THROUGH PARA-NAME-N] VARYING { identifier- 1 } {identifier-2 } {Index-name-1} FROM {index-name-2} { Literal-1 } BY {identifier-3 } UNTIL Condition {Literal-2 } EX:
1. PERFORM PARA-2000 THRU PARA-5000 VARYING A FROM M BY N UNTIL A > Y 2. PERFORM para-1 Varying K FROM 10 BY 5
UNTIL K>100Notes:Example 2 says :Sets the value of K to 10 initiallyExecute para-1Check the condition K>100If condition is true, transfer the control to next lineIf condition is false, increment K by 5Execute para-1 againCheck the condition K > 100Repeat steps from 2 through 7 until Condition K > 100 becomes true
Flow Chart for PERFORM ….. VARYING
Enter
Set identifier –1 to initial value
Condition
Execute range
Add increment to - identifier.
Exit
False
PERFORM with the VARYING-AFTER Option
PERFORM PARA-NAME-1 [THRU (or) THROUGH PARA-NAME-N] VARYING { identifier- 1 } {identifier-2 } {Index-name-1} FROM {index-name-2} { Literal-1 } BY {identifier-3 } UNTIL Condition-1 {Literal-2 }
AFTER { identifier- 4 } {identifier-5 } {Index-name-3} FROM {index-name-4} { Literal-3 } BY {identifier-6 } UNTIL Condition-2 {Literal-4 }
AFTER { identifier- 7 } {identifier-8 } {Index-name-5} FROM {index-name-6} { Literal-5 }
BY {identifier-9 } UNTIL Condition-3 {Literal-6 } This form is used when a nested repetition of the range is required while varying more than
one identifier.
For example
PERFORM RANGE-TO-BE-EXECUTED
VARYING I FROM 1 BY 1 UNTIL I > 50
AFTER J FROM 1 BY 1 UNTIL J > 10.
The range RANGE-TO-BE-EXECUTED will be performed 500 times,.
In-Line PERFORM
The in-line PERFORM will be coded using END-PERFORM.
Named Paragraph
PERFORM MOVEIT VARYING X FROM 1 BY 1 UNTIL X = 5.
. . . MOVEIT. MOVE DATA-FLD (X) TO PRINT (X).
In-line PERFORM
PERFORM VARYING X FROM 1 BY 1 UNTIL X = 5. MOVE DATA-FLD (X) TO PRINT (X).
END-PERFORM.
Notes:
An In-line PERFORM requires the END-PERFORM terminator. Conversely the END-PERFORM phrase must not be specified when the statement is “PERFORM procedure name…”.
…
IN-LINE PERFORM Considerations
DO not use for procedures executed from several places/
Use for procedures referenced only once.
Consider not using if readability is affected , such as multiple-page PERFORM,
No periods may appear within the in-line PERFORM.
Delimited by END-PERFORM.
END-PERFORM cannot be used at end of an out-of-line PERFORM.
The OPTIMIZE compile option may move the PERFORM in-line in the object code at
the compile time.
IF .. ELSE Statement
The IF statement evaluates a condition and provides for alternative actions in the object program, depending on the evaluation.
Format :
>>_______IF_____Condition-1____ __________ _____ ___statement-1___|__ ________>
|_THEN_____| |_NEXT SENTENCE _|
>___ ______________ ____ ________________ ______________________________>
| <____________ | | (1) |
| _ ELSE__ ___statement-2_|_____ | |___END-IF________|
Note :
(1) END-IF can be specified with NEXT SENTENCE as an IBM extension.
Notes:
The IF statement evaluates a condition and provides for different sets of statements to execute, depending
on the evaluation of the IF.
Condition can be any simple or complex condition.
Statement-1, statement-2 Can be any one of the following:
An imperative statement
An conditional statement
An imperative statement followed by a conditional statement
NEXT SENTENCE
If the NEXT SENTENCE phrase is specified, and then the END-IF phrase must not be specified. NEXT SENTENCE passes control to the statement after the closest following period. However, if the NEXT SENTENCE phrase is executed, control will not pass to the statement after the closest following period.
Compound Conditionals
Conditional expressions can be “compound” using the AND and OR logical operators Conditional conditions can also use parentheses to group conditions.
IF ITEM-1 = DOMESTIC-ITEM-NO AND ITEM-2 = OVERSEAS-ITEM-NO OR ITEM-1 = OVERSEAS-ITEM-NO AND ITEM-2 = DOMESTIC-ITEM-NO SET MIXED-SHIPMENT-FLAG TO TRUE
END-IF
……………. SEARCH TABLEPAIR VARYING NDX WHEN ITEM-1(NDX) = FROM-CITY AND ITEM-2(NDX) = TO-CITY MOVE ……… WHEN ITEM-2(NDX) = FROM-CITY AND ITEM-1(NDX) = TO-CITY MOVE ……..
END-SEARCH
Relational Expressions
Relational tests (comparisons) can be express as:
IS LESS THAN IS <
IS NOT LESS THAN IS NOT <
GREATER THAN IS >
IS NOT GREATER THAN IS NOT >
IS EQUAL TO IS =
IS NOT EQUAL TO IS NOT =
IS GREATER THAN OR EQUAL TO IS >=
IS LESS THAN OR EQUAL TO IS <=
CONTINUE & NEXT SENTENCE Statement
Example 1 - NEXT SENTENCE
IF A = B
IF C = D
NEXT SENTENCE
ELSE
MOVE MESSAGE-1 TO RPT-MESSAGE-1
END-IF
ADD C TO TOTAL
DISPLAY TOTAL
IF E = F
MOVE MESSAGE-4 TO RPT-MESSAGE-2
END-IF
END-IF.
Example 2 – CONTINUE
IF A=B
IF C=D
CONTINUE
ELSE
MOVE MESSAGE-1 TO RPT-MESSAGE-1
END-IF
ADD C TO TOTAL
DISPLAY TOTAL
IF E=F
MOVE MESSAGE-4 TO RPT-MESSAGE-2
END-IF
END-IF.
EVALUATE Statement
EVALUATE is a great way to implement the “case” programming construct
EVALUATE datanameWHEN value-1 …….WHEN value-2 {THROUGH | THRU} value-3 ….WHEN NOT value-4……WHEN OTHEREND-EVALUATE
EVALUATE datanameWHEN ‘A’ Perform add-transWHEN ‘D’ Perform delete-transWHEN ‘U’ WHEN ‘W’ Perform update-trans WHEN OTHER Perform bad-transEND-EVALUATE
Basic EVALUATE Example:
The scope of a WHEN clause is all statements UNTIL the next WHEN clause, the END-EVALUATE, or a period
Notes:The EVALUATE statement provides a shorthand notation for a series of nested IF statements.
It can evaluate multiple conditions. That is, the IF Statements can be made up of compound conditions.
Examples: Working-Storage for all Examples:
01 PLANET. 05 PLANET-NUMBER PIC 9. 05 PLANET-NAME PIC X(7).
Evaluate Example Number 1: (Evaluate a PIC 9 field) EVALUATE PLANET-NUMBER
WHEN 1 MOVE "Mercury" TO PLANET-NAME WHEN 2 MOVE "Venus " TO PLANET-NAME WHEN 3 MOVE "Earth " TO PLANET-NAME WHEN 4 MOVE "Mars " TO PLANET-NAME WHEN 5 MOVE "Jupiter" TO PLANET-NAME WHEN 6 MOVE "Saturn " TO PLANET-NAME WHEN 7 MOVE "Uranus " TO PLANET-NAME WHEN 8 MOVE "Neptune" TO PLANET-NAME WHEN 9 MOVE "Pluto " TO PLANET-NAME WHEN OTHER MOVE " " TO PLANET-NAME END-EVALUATE.
Evaluate Example Number 2: (Evaluate a PIC X field)
EVALUATE PLANET-NAME WHEN "Mercury" MOVE 1 TO PLANET-NUMBER WHEN "Venus " MOVE 2 TO PLANET-NUMBER WHEN "Earth " MOVE 3 TO PLANET-NUMBER
WHEN "Mars " MOVE 4 TO PLANET-NUMBER WHEN "Jupiter" MOVE 5 TO PLANET-NUMBER
WHEN "Saturn " MOVE 6 TO PLANET-NUMBER WHEN "Uranus " MOVE 7 TO PLANET-NUMBER WHEN "Neptune" MOVE 8 TO PLANET-NUMBER WHEN "Pluto " MOVE 9 TO PLANET-NUMBER WHEN OTHER MOVE 0 TO PLANET-NUMBER
END-EVALUATE.
Evaluate Example Number 3:
Let each of MONTH and NO-OF-Days be two-digited numeric integer fields. The values 1,2,3, etc. for MONTH denote respectively, January, February, March etc. depending on the value of MONTH , we wish to ove 30,31 or 28 to NO-OF-DAYS. For example , if the value of MONTH is 1, we shall move 31; if it is 2, we shall move 28 and so on. The EVALUATE statement for the purpose is as follows:
EVALUATE TRUE WHEN MONTH = 4 OR 6 OR 9 OR 11 MOVE 30 TO NO-OF-DAYS
WHEN MONTH = 2 MOVE 28 TO NO-OF- DAYS
WHEN OTHER MOVE 31 TO NO-OF-DAYS END EVALUATE.
Evaluate Example Number 4:Suppose MARKS contains the marks obtained by a student. GRADE is an one-
character alphanumeric field. We wish to calculate GRADE according to the following rules
MARKS GRADE80 – 100 A60 - 79 B45 - 59 C30 - 44 D0 - 29 EThe EVALUATE statement for the purpose is shown below.EVALUATE MARKS
WHEN 80 THRU 100 MOVE “A” TO GRADEWHEN 60 THRU 79 MOVE “B” TO GRADEWHEN 45 THRU 59 MOVE “C” TO GRADEWHEN 30 THRU 44 MOVE “D” TO GRADEWHEN ZERO THRU 29 MOVE “E” TO GRADEWHEN OTHER MOVE “W” TO GRADE
END-EVALUATE.The literal “W” is moved to GRADE in the case of wrong marks.
ILLUSTRATES CONDITION NAMES DATA DIVISION.
WORKING-STORAGE SECTION. 77 MARTIAL-STATUS PIC 9.
88 SINGLE VALUE 0.88 MARRIED VALUE 1.88 WIDOWED VALUE 2.88 DIVORCED VALUE 3.88 ONCE-MARRIED VALUES ARE 1, 2, 3.88 VALID-STATUS VALUES ARE 0 THRU 3.77 AMOUNT PIC 9 (4) VALUE 1000.
PROCEDURE DIVISION. MAIN-PARA.
DISPLAY “Martial Status:” DISPLAY “0- Single / 1- Married / 2- Widowed / 3- Divorced”. ACCEPT MARTIAL-STATUS. IF NOT VALI-STATUS DISPLAY “Error in Entry”. IF SINGLE SUBTRACT 100 TO AMOUNT. IF MARRIED ADD 100 TO AMOUNT. IF WIDOWED ADD 200 TO AMOUNT. IF DIVORCED SUBTRACT 200 FROM AMOUNT. IF ONCE-MARRIED ADD 250 TO AMOUNT DISPLAY AMOUNT. STOP RUN.
INITIALIZE Statement
The INITIALIZE statement sets selected categories of data fields to predetermined values. It is functionally equivalent to one or more MOVE statements.
When the REPLACING phrase is not used:
SPACE is the implied sending field for alphabetic alphanumeric, alphanumeric-edited, and DBCS items.
ZERO is the implied sending field for numeric and numeric-edited items.
>>___INITIALIZE____identifier- 1 ________________________________________>
>___ ___________________________ _________________ _______><
| < ____________________________________________ __________________
|_REPLACING____ _ALPHABETIC_______ __ _______ __BY____ identifier-2 _ _ | _ |
|_ALPHANUMER____| |_DATA_| |_LITERAL-1__|
|_NUMERIC __________|
|_ALPHANUMERIC-EDITED_|
|_NUMERIC-EDITED__|
|_ DBCS _____________|
|_ EGCS _____________|
Notes:
The INITIALIZE statement sets selected categories of data fields to predetermined values. It is functionally equivalent to one or more MOVE statements.
A subscripted item can be specified for identifier-1. A complete table can be initialized only by specifying identifier-1 as a group that contains the complete table.
The data description entry for identifier-1 must not contain a RENAMES clause. An index data item
cannot be an operand of INITIALIZE.
Special registers can be specified for identifier-1 and identifier-2 only if they are valid receiving fields or sending fields, respectively, for the implied MOVE statement(s).
When the REPLACING phrase is used: The category of identifier-2 or literal-1 must be compatible with the category indicated in the
corresponding REPLACING phrase, according to the rules for the NUMERIC category. The same category cannot be repeated in a REPLACING phrase. The Key word following the word REPLACING corresponds to a category of data shown “Classes of
Data” visual.
SET TO TRUE Statement
When this form of the SET statement is executed, the value associated with a
condition-name is placed in its conditional variable according to the rules of the
VALUE clause.
>>__SET____condition-name-1_|_ TO TRUE_________________________><
condition-name-1: Must be associated with a conditional variable.
If more than one literal is specified in the VALUE clause of condition-name-1, its
associated conditional variable is set equal to the first literal.
01 CUST-TYPE PIC 99.
88 INACTIVE VALUE 9.
88 SPEC-ACCTS VALUE 20, 11, 40, 44.
……
SET INACTIVE TO TRUE
SET SPEC-ACCTS TO TRUE
Class Condition
· NUMERICThe item entirely contains characters 0 through 9 (with or without a sign determined by its PICTURE clause). It may be USAGE DISPLAY or PACKED DECIMAL. · ALPHABETICThe entire item contains only A through Z, a through z, or spaces · ALPHABETIC-UPPERThe entire item contains only A through Z (exclusively upper-case) or spaces. · ALPHABETIC-LOWER The entire item contains only a through z (exclusively lower-case) or spaces.
Notes:
Ex: 1. IF A IS NUMERIC ---------------------- -----------------------
2. IF C IS ALPHABETIC ----------------------- ------------------------ Where A and C are Data items.
UNIT 4
FILE HANDLING IN COBOL
FILES
A record is a group of logically or functionally related fields.
A File is a group of Records.
A group of records, which can be created, copied, modified, retrieved and deleted.
E.g.: Details of an employee
-Name, Adds, Phone no., Dept no etc… Forms a record
Details of all employees-Group of such record forms a file.
Notes:
Files can be broadly categorized into Program files and Data files. In COBOL the term “Files” is used to indicate data files. Data files are normally created on a tape or disk and subsequently program can refer them.
Fixed vs Variables Length Records
Fixed length records.
Corresponding fields of all the records have same length.
Variable length records.
Field lengths may vary from record to record.
Figure 4-2 Fixed vs. Variable Length Records
Notes:
The size of a record is the cumulative size of all the fields in it.
If all the records of a file have the same structure then they are called Fixed length-records.
For convenience,records of different lengths can be placed together in one file.
Then they are known as variable-length-records.
FILE-CONTROL Paragraph
Format:
SELECT [OPTIONAL] File-name-1 ASSIGN TO Assignment-name-1[ RESERVE <INTEGER> AREA ]
SEQUENTIAL [ ORGANIZATION IS INDEXED
RELATIVE
SEQUENTIAL [ACCESS MODE IS RANDOM
DYNAMIC
[FILE STATUS IS Data-name-1]
Figure 4-3 FILE-CONTROL - SEQUENTIAL Notes:
The FILE-CONTROL paragraph associates each file with an external data-set. FILE_CONTROL paragraph is in INPUT-OUTPUT Section of ENVIRONMENT Division.Not all options are available on all platforms.
SELECT OPTIONAL may be specified only for files opened in the input, I-O, or extended mode.
You must specify SELECT OPTIONAL for such input files that are not necessarily present each
time the program is executed.
The ‘file-name-1’ must be identified by an FD or SD entry in the DATA DIVISION.
The ASSIGN clause associates the program’s name for a file with the external name for the
actual data file.
The RESERVE clause allows you to specify the number of input/output buffers to be allocated at
run time for the file.
The ORGANIZATION clause identifies the logical structure of the file.
ORGANIZATION IS SEQUENTIAL
The Records are stored in contiguous allocation. To access the record in Sequential mode only
(I.e. to read the last record, it reads all the records until last record found.)Deletion of record
is not possible.Updating is possible but record length should not changed.
ORGANIZATION IS INDEXED
Each record in the file has one or more embedded keys; each key is associated with an index. An index provides a logical path to the data records, according to the contents of the
associated embedded record key data items. Indexed files must be direct-access storage files. Records can be fixed-length or variable-length.
Each record in an indexed file must have an embedded prime key data item. When records are inserted, updated, or deleted, they are identified solely by the values of their prime keys.
Thus, the value in each prime key data item must be unique and must not be changed when the record is updated.
In addition, each record in an indexed file can contain one or more embedded alternated key data items. Each alternated key provides another means of identifying which record to retrieve.
The RECORD KEY clause specifies the data item within the record that is the prime RECORD KEY for an indexed file. The values contained in the prime RECORD KEY data item must be unique among records in the file.
The ALTERNATRE RECORD KEY clause specifies a data item within the record that provides an alternated path to the data in an indexed file. Used like the RECORD KEY but for an alternate index.
ORGANIZATION IS RELATIVE The INPUT-OUTPUT FILE-CONTROL for Relative record files is very similar to that of
indexed files except you use the RELATIVE KEY clause of the ACCESS MODE phrase and each record identified by the Relative Record Number instead of Recoed Key.
ACCESS Mode
Meaning
Records of the file can be accessed sequentially, starting from first record till the required record is reached.
Any record can be accessed directly without beginning from the first record.
Records can be accessed both randomly and/or sequentially
Modes
SEQUENTIAL
RANDOM
DYNAMIC
Notes:
The record of a file stored on a magnetic tape can be accessed in sequential mode only. But the records of file stored on magnetic disk can be accessed in all the modes.
FILE STATUS Clause
A two-digit number indicates the status of the file.
Value Status
00 Successful Completion
10 At end condition
30 Permanent error
34 Boundary violation
Notes:
Input-Output operations may not be successful thus resulting in termination of the program.
The data-name specified in the file-status clause contains the status code and can be referred by the programmer. Depending on the code programmer can take specific actions by transferring the control to error-routine paragraphs.
The data name should be declared in working-storage section with alphanumeric data type of two characters.
I-O-CONTROL Paragraph
The Optional I-O-CONTROL paragraph of the Input-Output Section
specifies
when checkpoints are to be taken and the storage areas to be shared by different files.
Specifies information needed for efficient transmission of data between the external data
set and the COBOL program.
Notes:
The I-O-CONTROL paragraph is optional.
The key word I-O-CONTROL can appear only once, at the beginning of the paragraph. The word I-O-CONTROL must begin in Area A, and must be followed by a separator period.
Each clause within the paragraph can be separated from the next by a separator comma or a separator semicolon. The order in which I-O-CONTROL paragraph clauses are written is not significant. The I-O-CONTROL paragraph ends with a separator method.
FILE SECTION
FILE SECTION.
FD File-Name
BLOCK CONTAINS m RECORDS
RECORD CONTAINS n CHRACTERS
LABEL RECORDS ARE STANDARD/ OMMITED
01 File-record-structure.
Notes:
Each file used in the program should have an FD entry (File Description) in
FILE SECTION.
BLOCK CONTAINS clause specifies number of records in the block.
RECORD CONTAINS clause specifies total number of characters in each record.
LABEL RECORDS clause indicates
Disk files if STANDARD option is specified
Print files if OMITTED option is specified
Value clause specifies the name of the physical file and the path
01 level entry should follow immediately after FD paragraph.
Blocking
Input-Output operations are slower compared to CPU processing speed. To reduce the CPU waiting time, block of records from the disk can be moved to the memory space called buffer thus reducing number of I-O operations.
The Programmer can specify the number of records contained in a block. Suitable block size is to be selected by the programmer.
File Operations
Cobol Verbs
WRITE
REWRITE
READ
DELETE
Meaning
Writes the records into file. Required while creating a new file and while Adding new records to an existing file.
Rewrites on one or more existing fields of a file.Required while updating a file.
Reads the records of a file and make them available to program
Deletes the record from a file.
Notes:
This foil lists the possible operations that can be performed over files. Before doing any operation, files should be opened and they must be closed before exiting the program “OPEN” and “CLOSE” verbs are provided by COBOL.
OPEN MODES
Mode
INPUT
OUTPUT
I-O
EXTEND
Meaning
Stands for input mode.Only reading of records possible.
Stands for output mode.Only writing new records possible.
Stands for Input ---Output mode.All operations possible
Stands for extend mode.Only for appending the records in sequential mode.
Notes:SYNTAXOPEN Mode File-name1, File-name2.CLOSE File-name1, File-name2 While opening the file the mode must be specified depending on the operation to perform. More than one file can be opened and closed. Further, files can be opened and closed more than once in a program.
READ – Sequential Access When the READ statement is executed the file must already be open in INPUT or I-O mode The AT END clause must be before the NOT AT END Format 1: sequential retrieval >>____READ__file-name-1___ _________________ __ __________ ___________________>
|_ NEXT __________| |_RECORD__| |_ (1)| |_ PREVIOUS______| >_____ _______________________ ______________________________________________> |____ INTO___identifier-1____| >_____ ___________________________________ __________________________________> |_ ____ __END_imperative –statement-1_| |_ AT _| >_____ ____________________________________________ ____ __________ _______>< |_ NOT___ ______ ___END_imperative-statement-2_| |_END-READ_|
Notes:For sequential access, the READ statement makes the next logical record from a file available to the object program. For random access, the READ statement makes a specified record from a direct-access file available to the object program.
When the READ statement is executed, the associated file must be open in INPUT or I-O mode. NEXT RECORD Reads the next record in the logical sequence of records. NEXT is optional when ACCESS MODE
IS SEQUENTIAL; PREVIOUS RECORD Reads the previous record in the logical sequence of records.
END OF FILE Processing
When the ‘AT END’ condition occurs during sequential processing, the READ statement execution is unsuccessful. The contents of the record area are ‘undefined’
The following actions take place when ‘AT END’ occurs:
- The status indicator is posted.
- Control is transferred to the AT END phrase, if it is specified
- If AT END is not specified, then USE AFTER STANDARD ERROR could be specified and that procedure is executed. Then control is returned to the statement following the READ.
READ – Random Access
Format 2 : Random Retrieval
>>_____READ______file-name-1____ __________ ___ _______________ _____________>
>____ _____________________________ ________________________________________>
|_KEY_____ ___ __data-name-1__|
|_TO_|
>_____ _______________________________________________ ______________________>
|_INVALID_____ ______ ____imperative-statement-3__|
|_KEY __|
>____ ___________________________________________ ___ ____________ _______><
|_NOT INVALID___ ___ __imperative-statement-4_| |_END-READ__|
|_KEY_|
- For VSAM INDEXED files, the KEY field contains a data value that will be matched
against the key filed in the file records until the first record having an equal value is found.
- For VSAM RELATIVE files, the KEY phrase must not be specified.
Notes:
Format 2 must be specified for indexed and relative files in random access mode, and also for files in the dynamic access mode when record retrieval is random.
Execution of the READ statement depends on the file organization.
Indexed Files
Execution of a Format 2 READ statement causes the value of the key of reference to be compared with the value of the corresponding key data item in the file records, until the first record having an equal value is found. The file position indicator is positioned to this record, which is then made
available. If no record can be so identified, an INVALID KEY condition exists, and READ statement execution is unsuccessful.
If the KEY phrase is not specified, the prime RECORD KEY becomes the key of reference for this request. When dynamic access is specified, the prime RECORD KEY is also used as the key of reference for subsequent executions of sequential READ statements, until a different key of reference is established.
Relative Files
Execution of a Format 2 READ statement sets the file position indicator pointer to the record whose relative record number is contained in the RELATIVE KEY data item, and makes that record available.
The KEY phrase must not be specified for relative files.
READ – Dynamic Access
For dynamic access, either sequential or random access possible, depending upon
the format of the Read statement
Dynamic access is allowed only for VSAM indexed or VSAM relative organizations.
Dynamic access is established by ACCESS IS DYNAMIC in FILE-CONTROL
SELECT statement
The NEXT phrase must be specified for sequential access with dynamic mode. In order to READ NEXT, “position” must have been established in the file by a successful OPEN, START or READ statement
START Statement Format :
>>___START___file-name-1___________________________________________________________>
>__ _____________________________________________________________________ ________>
|_KEY___ ______ ____ __EQUAL___ ___ ________________ _data-name-1____|
|__TO _| | |_ TO_| |
|_ = ______________________________|
|_LESS__ _______ ________________|
| |_THAN_| |
|_ < ______________________________|
|_GREATER__ ____ _____________|
| |_THAN_| |
|_> _______________________________|
|_NOT LESS___ _______ ___________|
| |_THAN _| |
|_NOT < ___________________________|
|_NOT GREATER__ _______ ________|
| |_THAN_| |
|_NOT > ___________________________|
|_LESS_ ____ _ OR EQUAL_ __ _____|
| |THAN| |_TO_| |
|_ < = _____________________________|
|_GREATER__ ____ _OR EQUAL_ __ _|
| |_THAN_| \ TO|
|_>+_______________________________|
>__ _______________________________________ _____________________________________>
|_INVALID___ _____ _imperative-statement-1_|
|_KEY_|
>__ _______________________________________ ___________ ____________ _____________>
|_NOT INVALID___ _____ imperative-statement-1_| |_END-START_|
|_KEY_|
Notes: The START statement provides a means of positioning within an indexed or relative file for subsequent sequential record retrieval.
When the START statement is executed, the associated indexed or relative file must be open
in either INPUT or I-O mode.
file-name-1
Must name a file with sequential or dynamic access. File-name-1 must be defined in an
FD entry in the Data Division, and must not name a sort file.
END-START Phrase
This explicit scope terminator delimits the scope of the START statement. END-START converts a conditional START statement to an imperative statement so that it can be nested in another
conditional statement. END-START can also be used with an imperative START statement.
WRITE Statement
The WRITE statement releases a logical record for an output or input/output file.
When the WRITE statement is executed:
- The associated sequential file must be open in OUTPUT or EXTEND mode.
- The associated indexed or relative file must be open in OUTPUT, I-O, or EXTEND
mode.
Record-name must be defined in a Data Division FD entry. Record-name can be qualified. It must not be associated with a sort or merge file.
WRITE……….FROM
PROCEDURE DIVISION.
WRITE File-rec FROM Identifier.
File-rec is record-name declared in FILE-SECTION.
Identifier is a working-storage section variable
• The length of the identifier should be equal to the length of the record.
Notes: To Create a file, program can accept the data from the terminal into file record and write it. If the data need to be processed, it can be accepted in a W-S identifier. After processing the data the above WRITE……..FROM statement can be issued.Each WRITE statement writes one record at a time.
READ………….INTO
PROCEDURE DIVISION.
READ FILE-name (INTO W-S-Rec) | (AT END Statement)
File name is defined in SELECT clause.W-S-Rec is working-Storage section identifier.INTO clause moves the file record to W-S-rec.AT END clause if used, indicates the next action after the last record is read.
OPEN INPUT Mode
Notes:READ statement on sequential files reads one record at a time and makes it available to program. Reading begins from first record and if the READ statement is put in a loopThat is executing the statement repeatedly, then it is possible to read consecutive records. Loop can be terminated before AT END condition is reached if required so by the program. If the file is left open next time when the read statement executes, reading continuous from where it was stopped before the termination of loop.
If the file is closed then it is to be opened again before reading it.
REWRITE & DELETE
REWRITE record-name (FROM identifier)
Updates an existing record from W-S identifier.
OPEN I-O File-name
DELETE record-name ----------------- not allowed
Deleting of a record in sequential files not allowed.
Notes:It is often required to change the existing data and the process is called UPDATING. COBOL provides REWRITES verb to modify an existing record.
For example, changing the address field of an employee requires reading of employee number. Every record to be updated needs to be read first. To search the record of an employee, whose employee number is known, the process is as follows
Store the employee number in a variable Open the file Read first record Compare the variable with Emp-No field of the file If it matches update his address by REWRITE Else read next record his address by REWRITE
Repeat the process until the require record is read.
Appending to sequential files
Adding new records to the existing file.
OPEN EXTEND Mode
WRITE records.
When new records to be added to file open the file in EXTEND mode
EXTEND mode causes the pointer to move to the end of the file.
CLOSE Statement
Format :
CLOSE File-name-1, [File-name-2 ………….]
CLOSE Statement Releases the Resourcces which are assigned to that file.
Cannot Close the file which is not opened.
After performing the operations on the file (I,e no longer used in a program) needs to be closed but not necessary.
If the FILE STATUS clause is specified in the FILE-CONTROL entry, the associated status key is updated when the CLOSE statement is executed.
If the file is in an open status and the execution of a CLOSE statement is unsuccessful, the
EXCEPTION/ERROR procedure (if specified) for this file is executed.
Sequential Files
ENVIRONMENT DIVISION.INPUT-OUTPUT SECTION.FILE-CONTROLSELECT file-name ASSIGN TO DEVICE-NAME ORGANIZATION IS SEQUENTIAL.ACCESS MODE IS SEQUENTIAL. AreaFILE STATUS IS data-name. B
Notes: All the files used in the program should have an entry in FILE CONTROL paragraph. For each file used, there should be one SELECT………..ASSIGN clause.The file-name is select clause is user defined word and can be used throughout the program wherever required.ASSIGN clause specifies the device on which file stored.
EXAMPLE: SEQUENTIAL FILE ID DIVISION. PROGRAM-ID. SEQ1. ENVIRONMENT DIVISION. INPUT-OUTPUT SECTION. FILE-CONTROL.
SELECT INFILE ASSIGN TO DDNAME1 ORGANIZATION IS SEQUENTIAL. SELECT OUTFILE ASSIGN TO DDNAME2 ORGANIZATION IS SEQUENTIAL. DATA DIVISION. FILE SECTION. FD INFILE.
01 INREC. 02 ENO PIC X(5). 02 ENAME PIC X(10). 02 EADDRESS PIC X(15). 02 FILLER PIC X(50).
FD OUTFILE. 01 OUTREC PIC X(80). WORKING-STORAGE SECTION. 01 EOF PIC X. PROCEDURE DIVISION.
OPEN INPUT INFILE OUTPUT OUTFILE. READ INFILE INTO OUTREC AT END MOVE 'Y' TO EOF. PERFORM WRITE-PARA UNTIL EOF = 'Y'. CLOSE INFILE OUTFILE. STOP RUN.
READ-PARA. WRITE OUTREC. READ INFILE INTO OUTREC AT END MOVE 'Y' TO EOF.
Indexed Files
Index component consists of a index structure with a record key values and addresses of corresponding records.
RECORD KEY is one or more fields of the records.Suitable record key is to be chosen by the programmer depending on the functionality of the fields. E.g : Employee-code, Job-number.
ALTERNATE RECORD KEY can also be chosen. E.g : Employee-name, Job-name.
Indexed files facilitate faster accessing of records compared to that of sequential files.
Notes:When an indexed file is created
An index component is also created containing some index tables based on record keys.
A data component is created containing the actual records. Record keys identify every record in the file.
The process of accessing a record involves searching for the record key with matching index value. Then locate the record from the corresponding address.This is done by the system itself.
INVALID KEY
(READ | WRITE | REWRITE | DELETE) File-name(INVALID KEY Statement)(AT END Statement).
Records and indexes of an indexed file are stored in key sequence order to facilitate faster access.
Invalid key clause checks whether any input-output operation is violating the
Uniqueness of primary keys
E.g. add a record with duplicate value.
Sequence of the records.E.g. add a record with key value out of range.
Proper read
E.g. try to read a non-exist record
Reading of a record in indexed files required the key value to be provided by the program
ACCESS MODE: SEQUENTIAL & RANDOM ACCESS MODE SEQUENTIAL READ File-name NEXT RECORD to read sequentially. DELETE statement should not contain invalid key AT END clause is required.
ACCESS MODE RANDOM READ File-name INVALID KEY statement AT END clause not required.
Notes: When READ NEXT statement is to be executed each time the records are read consecutively. IF the access mode is RANDOM a record is read from corresponding key value.
ACCESS MODE: DYNAMIC
START file-name key
(NOT | LESS THAN | GREATER THAN| LESS THAN ) identifier
INVALID KEY statement
READ file-name NEXT RECORD AT END statement.
Notes:
In a situation demanding the access of more than one consecutive records from the middle of the file then
dynamic access is used.
The “START” verb places the read pointer to the record whose key value is compared with an identifier. Record is accessed randomly.
‘READ…NEXT’ can be put into loop for sequential reading.
For the Rewrite/ Delete operations the records must be read at first.
IDENTIFICATION DIVISION. PROGRAM-ID. SEQFILE. ENVIRONMENT DIVISION. INPUT-OUTPUT SECTION. FILE-CONTROL. SELECT IND-FILE ASSIGN TO DD1 ORGANIZATION IS INDEXED ACCESS MODE IS RANDOM RECORD KEY IS NUM. SELECT OUT-FILE ASSIGN TO DD2 ORGANIZATION IS INDEXED ACCESS MODE IS DYNAMIC RECORD KEY IS NUM1. DATA DIVISION. FILE SECTION. FD IND-FILE. 01 IND-REC. 02 NUM PIC X(3). 02 NAME PIC X(15). 02 ADDR PIC X(10). 02 FILLER PIC X(52). FD OUT-FILE. 01 OUT-REC. 02 NUM1 PIC X(3). 02 NAME1 PIC X(15). 02 ADDR1 PIC X(10). 02 FILLER PIC X(52). WORKING-STORAGE SECTION. PROCEDURE DIVISION. MAIN-PARA. OPEN INPUT IND-FILE I-O OUT-FILE. MOVE '222' TO NUM. READ IND-FILE RECORD INTO OUT-REC KEY IS NUM INVALID KEY GO TO ERR-PARA. WRITE OUT-REC. PERFORM EXIT-PARA. ERR-PARA. DISPLAY 'KEY NOT FOUND'. PERFORM EXIT-PARA. EXIT-PARA. CLOSE IND-FILE OUT-FILE. STOP RUN.
EXAMPLE: INDEXED FILE
Relative Files
FILE CONTROL
SELECT file-name ASSIGN TO Disk
ORGANIZATION IS RELATIVE
RELATIVE KEY data-name-1
RRN indicates the offset of a record from the first record of the file.
Notes:
In relative file Relative Record Number identifies the records of the file. Select clause should specify “RELATIVE KEY”.
Value of data-name-1 indicates RRN.
Usage of READ/WRITE/ REWRITE/ DELETE statements, ACCESS modes, OPEN modes and START verb, are exactly similar to that for sequential files.
OPERATIONS
I O I-O E I O I-O I O I-O
READ X X X X X X
WRITE X X X X
REWRITE X X X
START X X X X
DELETE X X
READ X X X X
WRITE X X X X
REWRITE X X
START
DELETE X X
READ X X X X
WRITE X X X X
REWRITE X X
START X X X X
DELETE X X
ACCESS
MODE
SEQUENTIAL
RANDOM
DYNAMIC
Open modes
File Organization
Sequential Relative Indexed
TABLE HANDLING
Unit 5
Introduction : Table Handling
Consider a situation of accepting 100 numbers from the user , display all The numbers in sorted order. Types of tables One dimensional table Two dimensional table Multidimensional table Table is a list of logically similar items.
Notes: Obviously declaring 100 data items in W-S section and sorting them becomes practically impossible. Tables or Arrays provide the solution to handle situations discussed above. If volume of data to be processed is large and if they are not stored in files,then tables are used.
OCCURS Clause
Specifies number of occurrences or elements of the table.
WORKING-STORAGE SECTION01 Marks.
02 Mark – Table1 OCCURS 10 TIMES PIC 9(2). Valid
02 Mark – Table2 PIC 9(2) OCCURS 10 TIMES Valid
02 Mark – Table3 PIC 9(2) OCCURS 10TIMES VALUE 10 valid
Notes:
OCCURS clause causes setting up of area for holding the table elements.
Following rules must be followed with the usage of ‘OCCURS’ clause.1. The Integer must be positive.2. Clause cannot be specified for an item whose level is 01, 66, 77, 88.3. Value clause should not be specified with occurs clause.4. OCCURS clause can be specified for file-section entries for both group items as well as elementary items.
Subscript
Indicates the position of an element in the table. PROCEDURE DIVISION Marks – Table (Subscript) Parentheses required Marks Table (I) Valid provided I declared in data division.Marks – Table (5) Valid.Marks – Table (12) Invalid. Notes: Subscript can be a COBOL variable or a literal. Value of subscript must not exceed the range of no. of occurrences specified by ‘OCCURS’ clause. If OCCURS clause is specified for a group items subscript should be specified for all elementary items of that group. Subscript should be specified for only data items defined with OCCURS clause, whenever used in procedure division.
INDEXING
An “index-name” is an identifier that becomes associated with a particular table. The value in an index is the displacement from the beginning of the table based upon the length of the table element.
An “index-name” may appear on an OCCURS clause, e.g.
01 TABLE-OF-MONTHS.
02 MONTHS OCCURS 12 TIMES.
PIC X(10) INDEXED BY NDX.
The “index-name” is created by the compiler; it does not have to be defined
elsewhere in the program.
The contents of an index may be changed by the SET TO statement
An index may not be used in a MOVE statement or an INITIALIZE statement.
Notes:
Indexing allows such operations as table searching and manipulating specific items.
To use indexing you associate one or more index-names with an item whose data
description entry contains an OCCURS clause. An index associated with an index-name
acts as a subscript, and its value corresponds to an occurrence number for the item to
which the index-name is associated.
The INDEXED BY phrase, by which the index-name is identified and associated
with its table, is an optional part of the OCCURS clause. There is no separate
entry to describe the index associated with index-name. At run time, the contents of the
index corresponds to an occurrence number for that specific dimension of the table
with which the index is associated.
One Dimensional Tables
Specified by one subscript or index
Example:
01 ABC.
02 XYZ PIC X(10) OCCURS 10 TIMES.
XYZ(1) WHERE 1 Specifies the first element of XYZ.
Two Dimensional Tables
Specified by two subscripts or indexes.
Student (3 5) =5th Subject of 3rd Student.
Marks (3 5) =5th Marks of 3rd Student.
If it requires storing the Marks of N subject for M students then we require two ‘OCCURS’ clauses.
Notes:
Two dimension tables are used most frequently in applications. Consider for examples, 10 Students of a class appeared for 8 subjects in their annual exams and you need to code a program to store and retrieve the data.
Data includes names of all the students, marks and names of corresponding subjects.
To store the marks of ‘n’ subjects of one student, one dimension table serves the purpose. If number of students is more than one than for each student there OCCURS ‘n’ subjects and marks. Next foil shows the W-S
declarations for this example.
Multidimensional Table
Each OCCURS clause adds a dimension in nested occurs.
Ex:
01 Multidimensional.
02 First-dim OCCURS 10 TIMES PIC X.
02 Second-dim OCCURS 5 TIMES.
05Second PIC A.
05Third-dim OCCURS 10 TIMES
10Third PIC 5.
Notes:
COBOL supports multidimensional tables up to 7 levels.
Table-Sorting
Use Sorting techniques to sort a table.
e.g Bubble sort
PERFORM VARYING I FROM 1 BY 1 UNTIL I = N
PERFORM J FROM I BY 1 UNTIL J > N
IF A[I] > A[J]
MOVE A[I] TO TEMP
MOVE A[J] TO A[I]
MOVE TEMP TO A[J]
END-IF
END-PERFORM
END-PERFORM.
I and J are used as subscripts for comparing elements of the table.
Notes:
Sorting is the process of arranging the elements of table in order. Searching for a particular element of the
sorted table, requires less time when compared to searching from an unsorted table.
‘SORT’ verb available in COBOL is limited to File sorting.
SET Verb
SET verb initializes and / or changes the value of index.
E.g. :
SET K To 1 K is initialized to 1
SET K UP BY 2 Value increment by step of 2.
SET K DOWN BY 2 Decrements by step of 2
MOVE verb cannot be used for index.
E.g. : SET data-name-1, data-name-2 TO K
SET verb moves of value of K to data-name-1 and data-name-2.Notes:
Even though indexes assume the displacement values for table elements internally, programmer sets the value of an index by specifying the position of an element.
This means an index indicates the position of an element in the table similar to subscript, but internally it is processed in a different manner, but more efficient
SEARCH Verb
Searches for a particular value in the table, which has an index.
SEARCH Table – name AT END statement
WHEN condition statement
Ex : SET K TO 1
SEARCH table-name AT END DISPLAY ‘not found’.
WHEN field-1 = element (K) DISPLAY element (K).
Notes:
In the above example, field-1 contains the required value to be searched for in the table,
More than one ‘condition’ can be checked, with more than one ‘WHEN’ clause.
All valid arithmetic operators can be used.
This form of search statement is called serial search.
Binary Search
Searches the table previously sorted, by splitting the table.
Faster than serial search
Only one ‘WHEN’ clause is allowed.
SEARCH ALL Table-Name other clauses
………. remain same.
WHEN…….…
Notes:
Before applying ‘SEARCH ALL’ clause the table must be sorted.
SEARCH ALL causes the table to split into two halves. Then it determines which half of the table contains
the required value by comparing it to the last element of the first half and first element of the second half.
Again the selected half-table splits and continues and so on until the value is located .
ILLUSTRATES ONE-DIMENSIONAL ARRAYS
DATA DIVISION.
WORKING STORAGE SECTION.77 CT PIC 99 VALUE 0.01 TAX-RATE.
05 RATE PIC 999 OCCURS 5 TIMES. * There should be a space before and after the braces.
01 MONTH-TABLE.02 FILLER PIC X(9) VALUE “January”.02 FILLER PIC X(9) VALUE “February”.02 FILLER PIC X(9) VALUE “March:”02 FILLER PIC X(9) VALUE “April”.02 FILLER PIC X(9) VALUE “May”.02 FILLER PIC X(9) VALUE “June”.02 FILLER PIC X(9) VALUE “July”.02 FILLER PIC X(9) VALUE “August”.02 FILLER PIC X(9) VALUE “September”.02 FILLER PIC X(9) VALUE “October”.02 FILLER PIC X(9) VALUE “November”.02 FILLER PIC X(9) VALUE “December”.
01 MONTH-NAME REDEFINES MONTH-TABLE.02 MONTH PIC X(9) OCCURS 12 TIMES.
PROCEDURE DIVISION.
100-MAIN-PARA.
PERFORM 200-FILL-PARA VARYING CT FROM 1 BY 1.
UNTIL CT>5.
PERFORM 300-DISP-PARA VARYING CT FROM 1 BY 1.
UNTIL CT>5.
PERFORM 400-MNTH-PARA.
STOP RUN.
200-FILL-PARA.
COMPUTE RATE ( CT ) = CT*100.
300-DISP-PARA.
DISPLAY RATE ( CT ).
400-MNTH-PARA.
DISPLAY “Month as a number ?”
ACCEPT CT.
IF CT< 1 OR > 12 DISPLAY “Error in number”
ELSE DISPLAY MONTH ( CT ).
ILLUSTRATES SEARCH VERB
DATA DIVISION.
01 MONTH-TABLE.
02 FILLER PIC X(9) VALUE “January”.
02 FILLER PIC X(9) VALUE “February”.
02 FILLER PIC X(9) VALUE “March:”
02 FILLER PIC X(9) VALUE “April”.
02 FILLER PIC X(9) VALUE “May”.
02 FILLER PIC X(9) VALUE “June”.
02 FILLER PIC X(9) VALUE “July”.
02 FILLER PIC X(9) VALUE “August”.
02 FILLER PIC X(9) VALUE “September”.
02 FILLER PIC X(9) VALUE “October”.
02 FILLER PIC X(9) VALUE “November”.
02 FILLER PIC X(9) VALUE “December”.
01 MONTH-NAME REDEFINES MONTH-TABLE.
02 MONTH OCCURS 12 TIMES INDEXED BY CT.
05 FIRST-THREE PIC X (3).
05 BALANCE-REST PIC X (6).
77 M-NAME PIC X (9) VALUE SPACES.
PROCEDURE DIVISION.
MAIN PARA.
DISPLAY “Month’s Name please”.
ACCEPT M-NAME.
SET CT TO 1.
SEARCH MONTH AT END DISPLAY “Not Found”.
WHEN M-NAME = MONTH ( CT ).
DISPLAY FIRST-THREE ( CT ).
STOP RUN.
ILLUSTRATE TWO-DIMENSIONAL ARRAYS
DATA DIVISION
WORKING-STORAGE SECTION.
01 WORK-AREA
05 MORE DATA PIC A VALUE “Y”.
88 NO-MORE-DATA VALUE “N”.
01 TEMPERATURE-ARRAY.
05 DAY-IN-THE-WEEK OCCURS 24 TIMES.
10 HOURS-IN-THE-DAY OCCURS 24 TIMES.
15 DEGREE-TEMP PIC S9(3).
77 DAY-OF-THE-WEEK PIC 9.
77 TIME-OF-THE-DAY PIC 99.
77 HOUR-COUNT PIC 99.
77 DAY-COUNT PIC 9.
77 TOT-TEMP PIC S999.
77 AVERAGE-TEMP PIC S999.
PROCEDURE DIVISION.
100-MAIN-PARA.
PERFORM 200-DATA-ACCP-RTN UNTIL NO-MORE-DATA.
PERFORM 300-DATA-DISP-RTN.
STOP RUN.
200-DATA-ACCP-RTN.
DISPLAY “Day of the Week : 1-Sunday….7-Saturday :”ACCEPT DAY-OF-THE-WEEK.DISPLAY “Time of the Day during Data Collection :”ACCEPT TIME-OF-THE- WEEK.DISPLAY “Temperature”ACCEPT DEGREE-TEMP (DAY-OF-THE-WEEK, TIME-OF-THE-DAY).DISPLAY “Anymore (Y/N):”ACCEPT MORE-DATA.
300-DATA-DISP-RTN.
PERFORM VARYING DAY-COUNT FROM 1 BY 1 UNTIL DAY-COUNT > 7.
PERFORM VARYING DAY-COUNT FROM 1 BY 1 UNTIL HOUR-COUNT > 24.DISPLAY “ DAY : “, DAY-COUNT, “ HOUR: “,HOUR-COUNT, “TEMP : “ ,DEGREE-TEMP ( DAY-COUNT, HOUR-COUNT )ADD DEGREE-TEMP ( DAY-COUNT, HOUR-COUNT )
TO TOT-TEMP.COMPUTE AVERAGE-TEMP = TOT-TEMP / 168.DISPLAY “ Week’s Average Temperature Is : “, AVERAGE-TEMP”.
ILLUSTRATES MULTIPLE INDEXES AND 3D ARRAYS
DATA DIVISION. WORKING-STORAGE SECTION.
01 ENROLL-TABLE. 02 FACULTY OCCURS 3 TIMES INDEXED BY F1, F2.
03 DEPARTMENT OCCURS 6 TIMES INDEXED BY D1, D2.04 YEAR OCCURS 5 TIMES INDEXED BY Y1, Y2.
05 FAC PIC X (15).05 DEPT PIC X (10).05 YY PIC 9 (4).
77 ANYMORE PIC A VALUE “Y”. PROCEDURE DIVISION. 100-MAIN-PARA.
SET F1, D1, F2, D2, Y2 TO 1.PERFORM 200-ACC-PARA UNTIL SNYMORE = ‘N’.
DISPLAY “THE CONTENTS OF 3 DIMENSIONSAL ARRAY ARE :” PERFORM VARYING R2 FROM 1 BY 1 UNTIL F2 > F1 AFTER D2 FROM 1 BY 1 UNTIL D2 > D1. AFTER Y2 FROM 1 BY 1 UNTIL Y2 > Y1 DISPLAY RAC (F2, D2, Y2) DISPLAY DEPT (F2, D2, Y2) DISPLAY YY (F2, D2, Y2). STOP RUN.
200-ACC-PARA.
DISPLAY “ENTER FACULTY NAME”.
ACCEPT FAC (F1, D1, Y1).
DISPLAY “ENTER DEPARTMENT NAME:.
ACCEPT DEPT (F1, D1, Y1).
DISPLAY “ENTER YEAR”.
ACCEPT YY (F1, D1, Y1).
IF Y1 = 5
IF D1 = 6
IF F1 = 3
MOVE “N” TO ANYMORE
ELSE
SET F1 UP BY 1
END-IF
ELSE
SET D1 UP BY 1
END-IF
ELSE
SET Y1 UP BY 1.
DISPLAY “ANYMORE”.
ACCEPT ANYMORE
UNIT 6
Library Services
COPY Statement
The COPY statement is a library statement that places prewritten text in
a COBOL program
Each COPY must be terminated by a period
If ‘library-name’ is omitted, then SYSLIB is assumed
Format:
>>____COPY____ _____text-name___ _____ _____________________________________>
| _ literal __| |_ _OF _ ____ library-name_ ___|
|_IN_| |_ literal –2_______|
>____ ____________ _____ _________________________________________ ___ ______><
|_SUPPRESS__| | <______________________________ _|
|__REPLACING_______operand-1___BY__operand-2___|_|
Notes:
SUPRRESS means that the imbedded text will not be printed in the source program listing
COPY requires the LIB compiler option to be in effect
The COPY statement is a library statement that places prewritten text in a COBOL program.
Prewritten source program entries can be included in a source program at compile time. Thus, an installation
can use standard file descriptions, record descriptions, or procedures without recording them. These entries
and procedures can then be saved in user-created libraries; they can then be included in the source program
by means of the COPY statement.
Compilation of the source program containing COPY statements is logically equivalent to processing
all COPY statements before processing the resulting source program.
The effect of processing a COPY statement is that the library text associated with text-name is copied into
the source program, logically replacing the entire COPY statement, beginning with the word COPY and
ending with the period, inclusive. When the REPLACING phrase is not specified, the library text is copied
unchanged
Each COPY statement must be preceded by a space and ended with a separator period.
Debugging lines are permitted within library text and pseudo-text.
Comment lines or blank lines can occur in library text. Comment lines or blank lines appearing in library text
are copied into the resultant source program unchanged with the following exception: a command line or blank
line in library text is not copied if that comment line or blank line appears within the sequence of text
words that match operand-1
A COPY statement can appear in the source program anywhere a character string or a separator can appear;
however, a COPY statement must not be specified within a COPY statement. The resulting copied text
must not contain a COPY statement.
Nested COPY
COPY FILEA.
FILEA contains: ADDRESS contains:
01 FILEA. 05 STREET PIC X(40).
05 NAME PIC X(40). 05 CITY PIC X(20).
COPY ADDRESS. 05 STATE PIC X(02).
05 DATA PIC X(100). 05 ZIP PIC X(09).
Compile produces:
01 FILEA.
05 NAME PIC X(40).
05 STREET PIC X(40).
05 CITY PIC X(20).
05 STATE PIC X(02).
05 ZIP PIC X(09).
05 DATA PIC X(100).
Notes:
COBOL allows nested COPY statements.
Nested COPY statements cannot contain the REPLACING phrase.
A COPY statement can appear in the source program anywhere a character string or a separator can appear.
As an IBM extension, COPY statements can be nested. However, nested COPY statements cannot
contain the REPLACING phrase, and a COPY statement with the REPLACING phrase cannot contain
nested COPY statements.
A COPY statement cannot cause recursion. That is, a COPY member can be named only once
in a set of nested COPY statements until the end-of-file for that COPY member is reached.
COPY REPLACING
To change some, or all, of the names in the library (COPY’ed) text, the programmer
can use the REPLACING option.
The text in the library is unchanged.
COPY PAYLIB REPLACING
FLDA BY PAY-RECORD
FLDA BY HRLY-RATE
FLDA BY HRS-WORKD.
LIBRARY TEXT SOURCE PROGRAM
01 FLDA. 01 PAY-RECORD.
02 FLDB PIC 999V99. 02 HRLY-RATE PIC 999V99.
02 FLDC PIC 999V99. 02 HRS-WORKD PIC 999V99.
In the discussion that follows, each operand can consist of one of the following:
Pseudo-text
An identifier
A literal
A COBOL word
Function identifier
COPY Pseudo-Text
To change only part of the data-name(s) in the library text, the programmer can
use the REPLACING option with the standard pseudo-text delimiters (==)
COPY PAYLIB REPLACING
= = : PFFX: = = BY = = PAY = =.
LIBRAR TEXT SOURCE PROGRAM
01 :PFFX:. 01 PAY.
02 :PFFX:-RTE 02 PAY-RTE
PIC 999V99. PIC 999V99.
02 :PFFX: - HRS 02 PAY-HRS
PIC 999V99. PIC 999V99.
Notes :
Pseudo-text A sequence of character-strings and/or separators bounded by, but not including, pseudo-text-1
delimiters (= =). Both characters of each pseudo-text-1 delimiter must appear on one line; however,
character-strings within pseudo-text-1 can be continued.
Any individual character-string within pseudo-text-1 can be up to 322 characters long.
Pseudo-text-1 cannot be null, nor can it consist solely of the space character, separator comma, separator
semicolon, and/or of comment lines. Beginning and ending blanks are not included in the text
comparison process. Embedded blanks are used in the text comparison process to indicate multiple text words.
Pseudo-text must not contain the word COPY.
REPLACE Pseudo-test
Replace can be applied to the entire program, including text introduced through COPY members
Replace action starts at a the REPLACE statement and continues until:
- Another REPLACE statement
- REPLACE OFF statement
- End of source program
REPLACE statements are processed by the compiler after any COPY statements
are processed
UNIT 7
CHARACTER HANDLING
STRING
Two or more fields can be concatenated or ‘string’ in to single-field.
STRING (id- 1 | literal ), (id-2 | literal )DELIMITED BY (id- 3 | literal | size |space),……..
(id- 4 | literal )DELIMITED BY (id- 4 | literal ), (id 5 | literal )……INTO id – 7 (with pointer id- 6 ).
(ON OVERFLOW statement)
Notes:
‘Delimited by’ clause specifies how the fields are concatenated, Its usage is described in
following foils.
‘With pointer’ option if used gives the total no. of characters in the concatenated field (id-7)
If the length of id-7 is not enough to hold the transferred characters, the statement after ‘on
overflow’ option is executed.
One STRING statement can be written instead of a series of MOVE statements.
The following rules should be followed when this verb is used.
(i). This statement is used to concatenate one or more strings into one by placing them
side by side.
(ii). Sending strings may be alphanumeric literals, figurative constants or identifiers
with usage DISPLAY.
(iii). The receiving string, i.e., identifier- 7 must also be with usage DISPLAY.
STRING example :
DATA DIVISION. WORKING-STORAGE SECTION. 77 ID-1 PIC X(7) VALUE 'CON,CON'. 77 ID-2 PIC X(7) VALUE 'CAT,CAT'. 77 ID-3 PIC X(6) VALUE 'ENATED'. 77 ID-4 PIC X(12). 77 COUNTER PIC 9(3) VALUE ZEROS. PROCEDURE DIVISION. STRING ID-1, ID-2, ID-3 DELIMITED BY ',' INTO ID-4
RESULT
Content if id-4: CONCATENATED.
The following example shows usage of ‘size’ option.
77 F – 1 PIC X(7) VALUE ‘HIGHTEC”77 F – 2 PIC X(7) VALUE SPACES.STRING ‘MAIN’ DELIMITED BY SIZE F – 1 INTO F – 2.
ILLUSTRATES STRING VERB
DATA DIVISION.
WORKING STORAGE-SECTION.01 FULL-NAME PIC X(30).01 FIRST-NAME PIC X(10) VALUE SPACES.01 MIDDLE-NAME PIC X (10) VALUE SPACES.01 LAST-NAME PIC X (10) VALUE SPACES.
PROCEDURE DIVISION.
100-MAIN-PARA.
MOVE ‘RAJA’ TO FIRST-NAME.MOVE ‘ROMOHAN’ TO MIDDLE-NAME.MOVE ‘ROY’ TO LAST-NAME.STRING FIRST-NAME,MIDDLE-NAME,LAST-NAME DELIMITTED BY
SPACE INTO FULL-NAME.
UNSTRING Statement The UNSTRING statement is used to split a single data item into several data items Format:
>>__UNSTRING___identifier-1__________________________________________________________> >__ _____________________________________________________________________________ ___> |_DELIMITED___ _____ ___ _____ ___ __identifier-2__ ____ __________________________| |_BY_| |_ALL_| |_literal-1______| | <_____________________ |
|__OR_ ___ __ identifier-3_ _| |
|_ALL_| |_literal-2__|
>___INTO____________________________________________________________________________> >____identifier-4__ _____________________________ ____ ___________________________ __| __> |_DELIMITER__ ___ identifier-5 _| |_COUNT__ ____ identifier-6___| |_IN_| |_IN__|
>___ ___________________________ ____ _______________________________ ______________> |_ ____ _POINTER__identifier-7_| |_TALLYING___ ____ __identifier-8_| |_WITH_| |_IN_| >__ _____________________________________________ _________________________________> |_ _____ ___OVERFLOW__imperative-statement-1___| |_WITH_| >___ __________________________________________________ ___ _________________ _______> |_ NOT__ _____ __OVERFLOW__imperative-statement_2_| |_END-UNSTRING_| |_ON_|
Notes:
The UNSTRING statement causes contiguous data in a sending field to be separated and placed into multiple receiving fields.
One UNSTRING statement can take the place of a series of MOVE statements, except that evaluation or calculation of certain elements is performed only once, at the beginning of the execution of the
UNSTRING statement.
When the TALLYING phrase is specified, the field-count field contains a value equal to the initial value, plus the number of data receiving areas acted upon.
ILLUSTRATES UNSTRING VERB
DATA DIVISION.
WORKING STORAGE-SECTION.01 FULL-NAME PIC X(30).01 FIRST-NAME PIC X(10) VALUE SPACES.01 MIDDLE-NAME PIC X (10) VALUE SPACES.01 LAST-NAME PIC X (10) VALUE SPACES.
PROCEDURE DIVISION.
100-MAIN-PARA.
MOVE ‘RAJA ROMOHAN ROY’ TO FULL-NAME.UNSTRING FULL-NAME DELIMITTED BY SPACE INTO FIRST-NAME,
MIDDLE-NAME,LAST-NAME.
EXAMINE Statement
ALLEXAMINE Identifier TALLYINY LEADING Literal - 1
UNTIL FIRST
ALLEXAMINE Identifier REPLACING LEADING Literal - 2 BY Literal - 3
UNTIL FIRST
ALLEXAMINE Identifier TALLYINY LEADING Literal - 4
UNTIL FIRST
REPLACING BY Literal - 5
Notes:
This verb is used to scan a string to find the number of occurrences of a given character in it.
In addition, the Verb can also be use to replace some or all occurrences of the said character
by another character.
Eg :
Let us consider the following DATA DIVISION entry
77 A PIC X(5) VALUE IS “PPRIP”.
Now the statement
EXAMINE A TALLYING ALL “P”.
Will store 3 in the TALLY register as there are altogether three P’s in the string.
However the statement
EXAMINE A TALLYING LEADING “P”
Will store 2 in the TALLY , Since there are only Two leading P’s.
The statement
EXAMINE A TALLYING UNTIL FIRST “I”.
Will store 3 in the TALLY as there are only Three characters before the character I.
It may be noted here that if a particular character is not found, TALLY is set to
Zero, When the ALL or LEADING phrase is used. For e.g.. In the statement
EXAMINE A TALLYING LEADING “R”
Will set TALLY to zero, Since the leading character is not R.
If the UNTIL FIRST phrase is used and the specified character is not found, the TALLY will
contain the size of the string
EXAMINE---REPLACING.
EXAMINE A TALLYING ALL “P” REPLACING BY “Q”
Will store 3 in the TALLY register and will change the content of A to “QQRIQ”.
EXAMINE A REPLACING FIRST “I” BY “M”
Will change the content of A to “PPRMP”.
EXAMINE A REPLACING UNTIL FIRST “I” BY “Y”
Will change the content of A to “YYYIP”.
In each of the cases A is assumed to be defined as before.
INSPECT TALLYING Statement
The INSPECT statement specifies that characters, or groups of characters, in a data item are to be counted (tallied) or replaced or both.
° It will count the occurrence of a specific character (alphabetic,
numeric, or special character) in a data item.
° It will fill all or portions of a data item with specified characters,
such as spaces or zeros.
° It will convert all occurrences of specific characters in a data item
to user-supplied replacement characters.
Format:
>>___INSPECT___identifier-1______TALLYING____________________________________________________> <___________________________________________________________________________________ <_______________________________________________________ |
>____identifier-2___FOR____ __CHARACTERS____ ____________ _| _____________________ __ | __|_____>
| |_|phrase 1 |__| | | < _____________________________________ | | <_______________________ | | |__ __ALL _________ ___ __identifier-3___ __ ___________ _| _| _| |_LEADING______| |_literal________| |_ | phrase 1 _|
>_____REPLACING____________________________________________________________________________> <_______________________________________________________________________________
>_______ __CHARACTER BY____ _identifier-5__ ______ _______________ __|__________________ __|____> | |_literal-3____| |__| phrase |_| | | <_______________________________________________________ | | <________________ | | |__ ALL_____ ______ ___identifier-3___ ___BY__ _identifier-5__ ____ ______________| _| _| |_LEADING_| |_literal-1________| |_literal-3____| |_| phrase 1 |__|
phrase 1:|__ __BEFORE__ __ _____________ __ _identifier-4__________________________________________________| |_AFTER___| |_INITIAL_____| |_literal-2__|
Notes:
TALLING Phrase counts the occurrence of a specific character (alphabetic, numeric, or special character) in a data item.
Identifier-1: Identifier-1 is the inspected item and can be any of the following: An alphanumeric data item An numeric data item with USAGE DISPLAY An external floating point item
Identifier-2 Is the count field, and must be an elementary integer item defined without the symbol P in
its PICTURE character-string
You must initialize identifier-2 before execution of the INSPECT statement begins.
Identifier-3 or literal-1
Is the tallying field (the item whose occurrences will be tallied).
Eg:
PROCEDURE DIVISION.
INSPECT HELLO TALLYING TALLY-COUNT FOR ALL “A”
Let the picture of HELLO be X(20) and suppose its content before the execution of the
above statement is as follows :
APARNAbKUMARIbAMMAbb
If picture of TALLY-COUNT is 9(2) and originally contains 08, then after the execution
of the statement, TALLY-COUNT will contain 14, as there are a total of 6 A’s in HELLO.
If ALL in the statement is changed to LEADING , TALLY-COUNT will be increased to 9, as there is only one leading A. if CHARACTERS is specified instead of ALL
“A”, TALLY-COUNT will be increased to 28 as there are a total of 20 characters in HE LLO.
INSPECT REPLACING Statement
This phrase fills all or portions of a data item with specified characters, such as spaces or Zeros. When REPLACING CHARACTERS is used the identifier-5 must be 1 character in length
Format:
>>___INSPECT___identifier-1___REPLACING______________________________________________> <___________________________________________________________________________
>_______ __CHARACTERS BY___ __identifier-5__ ____ ___________ ___ | ____________ __| ___> | |_literal-3______| |_| phrase 2 |_| | | <__________________________________________________ | | <_____________ | | |_ ALL_____ _______ identifier-3_ ___BY__ __identifier-5__ _ _________ _| _| _| |_LEADING_| |_literal-1___| |_literal-3______| |_| phrase 1 |_|
phrase 1:|___ BEFORE_ __ ________ __ identifier-4_ ________________________________________________|
|_AFTER_| |_INITIAL_| |_literal-2___| INSPECT DATA1 REPLACING ALL “ “ BY “0”
INSPECT DATA2 REPLACING FIRST ZERO BY SPACEINSPECT DATA3 REPLACING CHARACTER ZERO BY “X”INSPECT DATA4 REPLACING LEADING “0” BY SPACE
REPLACING Phrase
-identifier-3 or literal-1
Is the subject field (the item whose occurrences are replaced).
Identifier-3 can be: An elementary alphanumeric data item A numeric data item with USAGE DISPLAY An external floating point item
Literal-1 must be non-numeric, and can be any figurative constant that does not begin with the word ALL. If literal-1 is a figurative constant, it is considered to be a 1-character nonnumeric literal.
Identifier-5 or literal-3
Is the substitution field
Identifier-5 can be:
. An elementary alphanumeric data item
A numeric data item with USAGE DISPLAY An external floating point item Literal-3 must be nonnumeric, and can be any figurative constant that does not begin with the word ALL.
The following replacement rules apply:
When the subject field is a figurative constant, the single-character substitution field(which
must be 1 character in length) replaces each character in the inspected item equivalent
to the figurative constant.
When the substitution field is a figurative constant, the substitution field replaces each
non-overlapping occurrence of the subject field in the inspected item.
When the subject and substitution fields are character-strings, the character-string specified
in the substitution field replaces each non-overlapping occurrence of the subject field in the
inspected item
UNIT 8
SORT / MERGE
SORT/MERGE
SORT Statement
MERGE Statement
SORT PROCEDURES
RELEASE/RETURN Statements
SORT Statement
The SORT statement accepts records, sorts them according to specified keys, and makes the sorted results available for further processing.
Format 1:
SORT file-name-1 ON ASCENDING/DESCENDING KEY data-name-1 USING file-name-2 GIVING file-name-3.
Format 2:
SORT file-name-1 ON ASCENDING/DESCENDING KEY data-name-1 INPUT PROCEDURE IS Procedure-name-1[THRU Procedure-name-2] USING file-name-2 GIVING file-name-3.
Format 3:
SORT file-name-1 ON ASCENDING/DESCENDING KEY data-name-1 INPUT PROCEDURE IS Procedure-name-1[THRU Procedure-name-2] USING file-name-2 OUTPUT PROCEDURE IS Procedure-name-3[THRU Procedure-name-4]GIVING file-name-3.
Notes:
The SORT Statement accepts records from one or more files. Sorts them according to the specified key(s), and makes the sorted records available either through an OUTPUT PROCEDURE or in an output file. The SORT Statement can appear any where in the procedure division except in the declarative portion.
File-name-1
The name given in the SD entry that describes the records to be sorted.
No pair of file-names in a SORT statement can be specified in the same SAME SORT AREA , or Same SORT-MERGE AREA clause. File-names associated with the giving clause (file-name-3…) cannot be specified in the SAME AREA clause.
File-names associated with the giving clause (file-name-3…) can be specified in the SAME AREA clause.
ASCENDING / DESCENDING KEY phrase
This Phrase specifies that records be to be processed in ascending or descending sequence (depending on the phrase specified), based on the specified sort keys.
When the GIVING phrase is specified , all the sorted records I the file-name-1 are automatically transferred to the output files ( file-name-3…).
MERGE Statement
The MERGE statement combines two or more identically sequenced files(that is, files that have already
been sorted according to an identical set of ascending/descending keys) on one or more keys and makes
records available in merged order to an output procedure or output file.
Format:
>>___MERGE__file-name-1____ _____ ___ __ASCENDING__ ___ _______ __data-name-1__| __|_>
>___ _____________________________________________________ __USING__file-name-2_______>
|__ ________________ __SEQUENCE__ ____ _alphabet-name-1_|
|_COLLATING____| |_IS_|
<__________________
>_____file-name-3__|___________________________________________________________________>
>___ __OUTPUT PROCEDURE___ ___ __procedure-name-1__ __________________________ _ _><
|_ |_IS_| |_ _ THROUGH_ procedure-name-2_| _|
| |_THRU____| |
| <________________ |
|_ GIVING___file-name-4__| _________________________________________________________|
Notes:
The MERGE statement combines two or more identically sequenced files(that is, files that have already
been sorted according to an identical set of ascending/descending keys) on one or more keys and makes
records available in merged order to an output procedure or output file.
A MERGE statement can appear anywhere in the Procedure Division except in a Declarative Section.
The file names given must be in the SD entry.
When the MERGE statement is executed, all records contained in file-name-2, file-name-3,…., are
accepted by the merge program and then merged according to the key(s) specified.
SORT PROCEDURES
Procedures can add, delete, alter or edit the records
With SORT ….INPUT PROCEDURE you can specify processing to be
performed on the records before they are sorted
With SORT …..OUTPUT PROCEDURE you can specify processing to be
performed on the records after they are sorted
In an input procedure the RELEASE statement is used to place a record into the
file to be sorted
In an output procedure the RETURN statement is used to extract a record from
the sorted file
Notes:
INPUT PROCEDURE Phrase
This phrase specifies the name of a procedure that is to select or modify input records before the sorting operation begins.
The input procedure can consist of any procedure needed to select, modify or copy the records that are made available one at a time by the RELEASE statement to the file referenced by file-name-1. The range includes all statements that are executed as the result of a transfer of control by CALL, EXIT, GO TO, and PERFORM statements in the range of the input procedure, as well as all statements in declarative procedures that Sare executed as a result of the execution of statements in the range of the input procedure. The range of the input procedure must not cause the execution of any MERGE, RETURN, or SORT statement.
If an input procedure is specified, control is passed to the input procedure before the file referenced by file-name-1 is sequenced by the SORT statement. The compiler inserts a return mechanism at the end of the last statement in the input procedure. When control passes the last statement in the input procedure, the records that have released to the file referenced by file-name-1 are sorted.
OUTPUT PROCEDURE Phrase
This phrase specifies the name of a procedure that is to select or modify output records
from the sorting operation.
The output procedure can consist of any procedure needed to select, modify, or copy the records that are made available one at a time by the RETURN statement in sorted order from the file referenced by file-name-1. The range includes all statements that are executed as the result of a transfer of control by CALL, EXIT, GO TO, and PERFORM statements in the range of the output procedure. The range also includes all statements in declarative procedures that are executed as a result of the execution of statements in the range of the output procedure. The range of the output procedure must not cause the execution of any MERGE, RELEASE, or SORT statement.
If an output procedure is specified, control passes to it after the file referenced by file-name-1 has been sequenced by the SORT statement. The compiler inserts a return mechanism at the end of the last statement in the output procedure and when control passes the last statement in the output procedure, the return mechanism provides the termination of the sort and then passes control to the next executable statement after the SORT statement. Before entering the output procedure, the sort procedure reaches a point at which it can select the next record in sorted order when requested. The RETURN statements in the output procedure are the requests for the next record.
RELEASE Statement
The RELEASE statement is only used within the INPUT PROCEDURE of a SORT The RELEASE statement makes the contents of record-name-1 available to the initial phase of the SORT process Upon completion of the INPUT PROCEDURE, the sort file consists of all records placed there by the RELEASE statement
Format:
____RELEASE____record-name-1____ _____________________________ ____________________>< |_FROM___identifier-1___________|
Figure 8-5 RELEASE Statement
Notes:
The RELEASE statement transfers records from an input/output area to the initial phase of a sorting operation.
The RELEASE statement can only be used within the range of an INPUT PROCEDURE associated with a SORT statement.
Within an INPUT PROCEDURE, at least one RELEASE statement must be specified.
RETURN Statement
The RETURN statement is used only within the OUTPUT PROCEDURE of a
SORT or MERGE The RETURN statement acts like a “READ” and makes the next record from the sort/merge processing available to the application The AT END clause must be specified Format:
>>___RETURN___file-name-1___ ______________ ____ _____________________________ _______> |_ RECORD __| |_INTO___identifier-1___________| >___ _____ ____END___imperative-statement-1____________________________________________> |_ AT _| >___ _____________________________________________________ ___ ______________ _____> |_NOT____ _____ __END______imperative-statement-2______| |_ END-RETURN_| |_AT__|
Notes: The RETURN statement transfers records from the final phase of a sorting or merging operation to an
OUTPUT PROCEDURE.
The RETURN statement can be used only within the range of an OUTPUT PROCEDURE associated with a SORT or MERGE statement.
EXAMPLE : SORT
IDENTIFICATION DIVISION.PROGRAM-ID. SORTING.ENVIRONMENT DIVISION.INPUT-OUTPUT SECTION.FILE-CONTROL. SELECT IN-FILE ASSIGN TO ‘DD1’ ORGANIZATION IS SEQUENTIAL. SELECT WORK-FILE ASSIGN TO ‘DD2’ SELECT OUT-FILE ASSIGN TO ‘DD3’ ORGANIZATION IS SEQUENTIAL.DATA DIVISION.FILE SECTION.FD IN-FILE.01 IN-REC. 02 NUMPICX(2). 02 NAMEPICX(10). 02 ADDR PICX(10). 02 FILLERPICX(58).SD WORK-FILE.01 WORK-REC. 02 WNUMPICX(2). 02 WNAMEPICX(10). 02 WADDR PICX(10). 02 FILLERPICX(58).FD OUT-FILE.01 OUT-REC PICX(80).WORKING-STORAGE SECTION.PROCEDURRE DIVISION.SORT WORK-FILE ON ASCENDING KEY WNUM USING IN-FILE GIVING OUT-FILE. STOP RUN.
UNIT 9
CALL Statement
CALL Statement
The CALL statement transfers control from one object program to another within the run unit
CALL identifier-1 USING [BY CONTENT/BY REFEERENCE] data-
name-1 [, data-name-2] …
Literal-1
[ ; ON OVERFLOW imperative-statement ]
Notes:
The CALL statement transfers control from one object program to another within the run unit.
The program containing the CALL statement is the calling program; the program identified in the CALL statement is the called subprogram. Called programs can contain CALL statements; however, a called
program must not execute a CALL statement that directly or indirectly calls the calling program unless it has the RECURSIVE attribute.
CALL BY CONTENT/REFERENCE
The CALL….BY REFERENCE technique allows the sub-program to access and process the data- items in the caller’s storage.
The CALL….BY CONTENT technique allows the sub-program to access and process a copy of the
data-items from the caller’s storage. The sub-program cannot change the original data values in the caller’s storage.
A single CALL statement may have both data passing techniques.
WORKING-STORAGE SECTION.01 RECORD-A.
05 FIELD1 PIC …… 05 FILLER …… ………….
PROCEDURE DIVISION. …………. CALL “xxxxxxxx” USING BY REFERENCE RECORD-A
BY CONTENT LENGTH OF RECORD-A Notes:
BY REFERENCE Phrase
If the BY REFERENCE phrase is either specified or implied for a parameter, the corresponding data item in the calling program occupies the same storage area as the data item in the called program.
BY CONTENT Phrase
If the BY CONTENT phrase is specified or implied for a parameter, the called program cannot change the value of this parameter as referenced in the CALL statement’s USING phrase, though the called program can change the value of the data item referenced by the corresponding data-name in the called program’s Procedure Division header. Changes to the parameter in the called program do not affect the corresponding argument in the called program.
BY VALUE Phrase
The BY VALUE phrase applies to all arguments that follow until overridden by another BY REFERENCE or BY CONTENT phrase.
If the BY VALUE phrase is specified or implied for an argument, the value of the argument is passed, not a reference to the sending data item. The called program can modify the formal parameter corresponding to the BY VALUE argument, but any such changes do not affect the argument since the called program has access to a temporary copy of the sending data item.
These options are Compiler dependent.
LINKAGE SECTION
The LINKAGE SECTION of the DATA DIVISION describes data made available from another program Storage is NOT reserved The VALUE clause may not be specified (except for level-88 items)
Notes:
The Linkage Section describes data made available from another program or method. The Linkage Section may be composed of two entry types:
Record-description-entry Data-item-description-entry
GLOBAL DATA
The GLOBAL clause specifies that a data-name is available to every program contained
within the program that declares it, as long as the contained program does not itself have a
declaration for that name. All data-names subordinate to or condition-names or indexes
associated with a global name are global names.
The GLOBAL clause can be specified in the Working-Storage Section, the File Section,
the Linkage section, and the Local-Storage Section, but only in data description entries
whose level-number is 01 or FD.
An item may have both GLOBAL and EXTERNAL clauses.
GLOBAL only applies to Nested Programs.
NotesGLOBAL in FILE SECTION.The GLOBAL clause specifies that the file connecter named by a file-name is a global name. A global file-name is available to the program that declares it and to every program that is contained directly or indirectly in that program. A file name is global if the GLOBAL clause is specified in the file description entry for that file-name. A record – name is global if the GLOBAL clause is specified in the record description entry by which the record-name is declared or, in the cause of record descreiption entries in the File Section, if the GLOBAL clause is specified in the file description entry for the file-name associated with the record description entry
GLOBAL in Data Descriptions
The GLOBAL clause specifies that a data-name is available to every program contained within the program that declares it, aslong as the contained program does not itself have a declaration for that name. All data-names subordinates to or condition-names or indexes associated with a global name are global names.
A data-name is global if the GLOBAL clause is specified either in the data description entry by which the data-name is declared or in another entry to which that data description entry is subordinate.
A statement in a program contained directly or indirectly within a program which describes a global name reference that name without describing it again.
Two programs in a run unit can reference common data in the following circumstances:
1. The data content of an external data record can be referenced from any program provided that program has described that data record.
2. If a program is contained within another program, both programs can refer to data possessing the global attribute either in the containing program or in any program that directly or indirectly contains the containing program.
Sample Program
ID DIVISION.PROGRAM-ID. MPGM.…………..DATA DIVISION.WORKING-STORAGE SECTION.01 MNTEC PIC X(32) GLOBAL.PROCEDURE DIVISION.
MOVE “BEGINNING CONTENTS” TO MNTECCALL “SUBPGM”DISPLAY MNTEC.STOP RUN.
IDENTIFICATION DIVISION.PROGRAM-ID. SUBPGM.DATA DIVISION.WORKING-STORAGE SECTION.PROCEDURE DIVISION.
DISPLAY “ENTERING SUBPROGRAM”.DISPLAY MNTEC.MOVE “ENDING CONTENTS” TO MNTEC.DISPLAY “LEAVING SUBPGM”.EXIT PROGRAM.
END PROGRAM SUBPGM.END PROGRAM MPGM.
UNIT 10 PROGRAM EXECUTION PROCESS
PROGRAM EXECUTION PROCESS
COMPILATION
LINK-EDITING
LOAD MODULE EXECUTION
FLOW CHART OF EXECUTION PROCESS USING JCL
Three steps are needed to process a COBOL program:
• Compilation
• Link-editing
• Load module execution
SOURCE PROGRAM
MESSAGES AND LISTINGS
COMPILATION
LINKEDITING
OBJECT MODULE MESSAGES AND
LISTING
OUTPUT
LOAD MODULE
EXECUTION
LOAD MODULE
Notes:
The source program is the input to the compilation step. The output from the compilation step is
called an object module.
The object module is the input to the link-edit step. The output of the link-edit step is the load module,
which must be saved as a member of a partitioned dataset.
The load module created from the source program is executed in execution step.
THREE STEPS JCL USED TO EXECUTE A COBOL SOURCE CODE.
The following listing shows the general format of JCL used to process a COBOL program.
//JOBNAME JOB,, // CLASS=A,MSGCLASS=H,MSGLEVEL=(1,1), // NOTIFY=&SYSUID 1 //STEP1 EXEC PGM=IGYCRCTL //STEPLIB DD DSNAME=IGY310.SIGYCOMP,DISP=SHR //SYSPRINT DD SYSOUT=* //SYSLIN DD DSNAME=MTPLB00.COBOL.OBJLIB,DISP=(MOD,PASS), // SPACE=(TRK,(10,10)) //SYSUT1 DD UNIT=SYSDA,SPACE=(CYL,(1,1)) //SYSUT2 DD UNIT=SYSDA,SPACE=(CYL,(1,1)) //SYSUT3 DD UNIT=SYSDA,SPACE=(CYL,(1,1)) //SYSUT4 DD UNIT=SYSDA,SPACE=(CYL,(1,1)) //SYSUT5 DD UNIT=SYSDA,SPACE=(CYL,(1,1)) //SYSUT6 DD UNIT=SYSDA,SPACE=(CYL,(1,1)) //SYSUT7 DD UNIT=SYSDA,SPACE=(CYL,(1,1)) //SYSIN DD DSN=MTPLB00.COB.PGM(PGM1),DISP=SHR
2 //STEP2 EXEC PGM=HEWL
//SYSLIB DD DSNAME=CEE.SCEELKED,DISP=SHR
//SYSPRINT DD SYSOUT=*
//SYSLIN DD DSNAME=MTPLB00.COBOL.OBJLIB,DISP=(OLD,DELETE)
//SYSLMOD DD DSNAME=MTPLB00.COBOL.LOADLIB(PGM1),
// DISP=(MOD,PASS),
// SPACE=(TRK,(10,10,1))
3 //STEP3 EXEC PGM=PGM1
//STEPLIB DD DSN=MTPLB00.COBOL.LOADLIB,DISP=SHR
Notes:
Each job step can be executed alone or in combination as a job.In the first step, the COBOL compiler is IGYCRCTL and the input source code to thisIs specified in the SYSIN DD statement. The output created from this step is the object code, as storedin the SYSLIN DD statement.In the second step, the link-edit program is HEWL. The object code created from the previous step is the input to this step, as specified in the SYSLIN DD statement. A load module is created which is saved asa member of a PDS, as specified in the SYSLMOD DD statement.The load module created from the previous step is now executed on the EXEC statement
COMPILATION PROCESS
A specific computer has a specific set of instruction that is fixed during the design
of the machine. This set of instructions constitutes what is commonly called
he machine language.
A program written in language other than the machine language is called a source
program. Whether it is a high-level language program or an assembly-language
program, the program cannot be executed directly.
The source language program should be translated to a machine language
program known as the object program.
If the source is a high level language, the corresponding translator program
is called a compiler.
Compiler is used to translate COBOL program into language that the computer
can process i.e. object code.
GENERAL COMPILER
The following statements show general JCL for a compilation job step. //JOBNAME JOB ,, // CLASS=A,MSGCLASS=H,MSGLEVEL=(1,1), // NOTIFY=&SYSUID //STEP1 EXEC PGM=IGYCRCTL //STEPLIB DD DSNAME=IGY310.SIGYCOMP,DISP=SHR //SYSPRINT DD SYSOUT=* //SYSLIN DD DSNAME=MTPLB00.COBOL.OBJLIB,DISP=(MOD,PASS), // SPACE=(TRK,(10,10)) //SYSUT1 DD UNIT=SYSDA,SPACE=(CYL,(1,1)) //SYSUT2 DD UNIT=SYSDA,SPACE=(CYL,(1,1)) //SYSUT3 DD UNIT=SYSDA,SPACE=(CYL,(1,1)) //SYSUT4 DD UNIT=SYSDA,SPACE=(CYL,(1,1)) //SYSUT5 DD UNIT=SYSDA,SPACE=(CYL,(1,1)) //SYSUT6 DD UNIT=SYSDA,SPACE=(CYL,(1,1)) //SYSUT7 DD UNIT=SYSDA,SPACE=(CYL,(1,1)) //SYSIN DD DSN=MTPLB00.COB.PGM(PGM1),DISP=SHR
JCL KEYWORDS
STEP1 - The name of the job step. The exec statements specify that the COBOL
compiler (IGYCRCTL) is to be invoked.
STEPLIB - Definition of the data set where the COBOL compiler resides.
SYSLIN – Definition of the data set that receives output.
SYSUT1 TO SYSUT7 – Definitions of utility data sets used by the compiler
to process the source program. All SYSUT files must be on direct-access storage devices.
SYSIN – Definition of the data set to be used as input to the job step.
CONTROL ON COMPILATION
The compiler lists errors in COBOL program statements and provides information to
help you debug program. You can direct and control compilation with the following:
Compiler-directing statements
Compiler options
COMPILER-DIRECTING STATEMENTS
Basis statement – basis statement provides a complete program as the
source for a compilation.
*CONTROL or *CBL statement – this statement suppresses or allows output to be produced.
Copy statement – This statements place prewritten text in a COBOL program.
Delete statement – This statement removes COBOL statements from the basis source program.
Eject statement – This statement specifies that the next source statement is to be printed
at the next page.
Enter statement - The compiler treats this statement as a comment.
Insert statement – This statement adds COBOL statements to the basis source program.
Replace statement – This statement is used to replace source program text.
Skip1/2/3 statement – These statements specify lines to be skipped in the source listing.
Title statement – This statement specifies that a title be printed at the top of each page
of the source listing.
Use statement – The use statement provides declaratives to specify the following:
• Error handling procedures – exception/error
• User label-handling procedures – label• Debugging lines and sections – debugging
COMPILER OPTIONS
Compiler options help to control the compilation of program. Specify these options
in the PARM field of the JCL or on the process statement in program before
IDENTIFICATION DIVISION.
Syntax:
//STEP1 EXEC PGM=IGYCRCTL, PARM=’SSRANGE,LIB,DYNAM,LIST’
COMPILER OPTIONS DESCRIPTIONS
A] Diagnostic options
SSRANGE: SSRANGE is use to generate code that checks if subscripts or indexes
attempt to reference an area outside the region of the table. Variable-length items also
checked to confirm that their current length is within their maximum defined length.
Default is NOSSRANGE.
DUMP: Default is NODUMP. The dump option is use to produce a system dump at compile time.
FLAG: Default is FLAG (I). The syntax is FLAG (x, y), where x and y can be I, W, E, S, U.
To produce diagnostic messages for errors o a severity level x or above at the
end of the source listing using FLAG (x).
TEST: Default is NOTEST. Test is use to produce object code that can be executed
with batch or interactive debug.
B] VIRTUAL STORAGE OPTIONS
DYNAM: Default is NODYNAM. Use DYNAM to cause separately compiled programs invoked through the call literal statement to be loaded dynamically at run time. RENT: Default is NORENT. If program compiled using rent, then it generated as a reentrant object module. BUFSIZE: BUFSIZE option is use to allocate an amount of main storage to the buffer for each compiler work data set. Syntax is BUFSIZE (nnnnn/nnnK) where nnnnn denotes a decimal number that must be at least 256. nnnK specifies a decimal number in 1K increments. SIZE: Syntax is SIZE (nnnnn/nnnK/MAX).
nnnnnn specifies a decimal number that must be 778240. nnnK specifies a decimal number in 1K increments. The minimum acceptable value is 760K.
MAX requests the largest available block of storage in the user region for use during compilation. Use SIZE to indicate the amount of main storage available for compilation. Where 1K = 1024 bytes decimal.
DATA: Default is data (31). Specify the DATA(24) compiler option for programs running in 31-bit addressing mode that are passing data parameters to programs in 24-bit addressing mode.
C] SOURCE LANGUAGE OPTIONS
LIB: Default is NOLIB. COPY, BASIS, or REPLACE statements are use in a program that time specify the lib option. APOST/QUOTE: Default is QUOTE. Specify QUOTE when you want the quotation mark (“) to be the delimiter character for literals. APOST use when you want the apostrophe (‘) to be the delimiter character for literals. WORD: Use WORD(xxxx) to specify that an alternate reserved-word table is to be used during compilation.Default is NOWD. WORD(xxxx) specifies the ending characters of the name of the reserved-word table (IGYCxxxx) to be used in compilation. IGYC are the first four standard characters of the name, and xxxx can be 1 to 4 characters in length. NUMBER: Use number if you want program line numbers to be used in error messages line number. Default is NONUM. SEQUENCE: Default is sequence. If you specify sequence the compiler examines column 1 to 6 of source statements to check that the statements are arranged in ascending order according to their EBCDIC collating sequence. CURRENCY: Default is NOCURR. The CURRENCY option to provide an alternate default currency symbol to be used for the COBOL program. The default is NOCURR. NOCURRENCY specifies that no alternate default currency symbol will be used.
D] MAPS AND LISTINGS OPTIONS
XREF: Default is NOXREF. You can specify XREF, XREF (FULL) or XREF (SHORT). Use XREF to get a sorted cross-reference listing. EBCDIC data-names and procedure names listed in alphanumeric order. DBCS data-names and procedure-names listed based on their physical order in the program.
LANGUAGE: Default is LANGUAGE (ENGLISH). To select the language in which compiler output will be printed use language option. LINECOUNT: Use LINECOUNT (nnn) to specify the number of lines to be printed on each page of the compilation
listing, or use LINECOUNT (o) to suppress pagination. Default is LINECOUNT (60). LIST: Use list as a compiler option to produce listing of the assembler-language expansion of source code. Default is
NOLIST. MAP: Use map to produce a listing of the items defined in the data division. Default is NOMAP. OFFSET: Use offset to produce a line numbers, statement references listings. Default is NOOFFSET. SOURCE: To get a listing of source program using source compiler option. Default is SOURCE. SPACE: Use space option to select single, double or triple spacing in source code listing. SPACE is meaningful only when
source is in effect. Default is SPACE (1). VBREF: Default is NOVBREF. To get a cross-reference among all verb types used in the source program and line numbers
in which they are used. TERMINAL: To send progress and diagnostic messages to the SYSTERM data set use TERMINAL option. Default is
NOTERMINAL.
E] OBJECT DECK OPTIONS
COMPILE: Use the COMPILE option if you want to force full compilation even in the presence
of serious errors. Default is NOCOMPILE(s).
DECK: To produce object code in the form of 80-column card image using DECK option.
Default is NODECK. For DECK option you define SYSPUNCH in JCL for compilation.
NAME: To generate a link-edit NAME card for each object module. NAME is also used to
generate names for each load module. Default is NONAME or NAME(NOALIAS).
OBJECT: To place the generated object code on disk or tape to be later used as input for
the linkage editor. Default is OBJECT.
PGMNAME: Syntax is PGMN(CO/LU/LM). Default is PGMNAME (COMPAT).
CO – COMPAT
LU – LONGUPPER
LM – LONGMIXED
The PGMNAME option controls the handling of names used in the following:
Program names defined in the PROGRAM-ID paragraph.
Program entry point names on the entry statements.
F] OBJECT CODE OPTIONS
ADV: Default is ADV. ADV is meaningful only if you use WRITE…ADVANCING in source code. With ADV in effect, the compiler adds 1 byte to the record length to account for the printer control character. Use NOADV if you have already adjusted record length to include 1 byte for the printer control character.
AWO: Default is NOAWO. With AWO specified, the apply WRITE-ONLY clause will be in effect if any file within the program is physical sequential with blocked V-mode records. The clause will be in effect even if it was not specified within the program.
FASTSRT: FASTSRT allows IBM DFSORT or its equivalent, to perform the input and output instead COBOL. Default is NOFASTSRT.
NUMPROC: Default is NUMPROC (NOPFD). Use NUMPROC(NOPFD) if you want the compiler perform invalid sign processing. NUMPROC (PFD) is a performance option that can be used to bypass invalid sign processing.
OPTIMIZE: Default is NOOPTIMIZE. Use OPTIMIZE to reduce the run time of object program.
OUTDD: Default is OUTDD (SYSOUT). Use OUTDD if you want to run-time display output on the data set other than SYSOUT.
TRUNC: Default is TRUNC (STD). TRUNC (STD) to control the way arithmetic fields are truncated during MOVE and arithmetic operation.
ZWB: Default is ZWB. With ZWB, the compiler removes the sign from a sign external decimal field when comparing this field to an alphanumeric elementary field during execution.
G] OTHER OPTIONS:
EXIT: DEFAULT is NOEXIT. If you specify the EXIT option without providing a least
one sub option, NOEXIT will be in effect. The sub options can be specified
in any order, separated by either commas or spaces
COMPILER ERROR MESSAGES
The messages for compilation errors found in program are displayed at the end of
the listing for each program. A summary of all errors found during compilation
is displayed at the bottom of listing. Each message issued by the compiler is of the
following form:
LineID Mwssage code Message text
[nnnnnn] IGYppxxxx-L Text of Message
nnnnnn – The number of the source statement of the last line the compiler was processing.
IGY – The Prefix that identifies this message as coming from COBOL compiler.
pp - Two characters that identify which phase of the compiler discover the error.
xxxx – A 4-digit number that identifies the error message.
L – A character that indicates the severity level of the error – I, W,E,S or U
COMPILER ERROR MESSAGES CODES Errors the compiler can fall into five categories of severity. I (Informational, Return code=0) – An informational-level message is an aid to the user. No action is required from the user and the program will execute correctly. W (Warning, Return Code=4) – A warning-level massage calls attention to the possible error. It is probable that the program will execute correctly as written. E (Error, Return Code=8) – An error-level message indicates the condition that is definitely an error. The compiler has attempted to correct the error but results of the program execution may not be what the user expects. The user should correct the error. S (Severe, Return Code=12) – A severe-level massage indicates a condition that is serious error. The compiler was unable to correct the error. The program will not execute correctly and execution should not be attempted. U (Unrecoverable, Return Code=16) – An unrecoverable message indicates an error condition of such magnitude that the compilation was terminated.
LINK-EDITING
Creating a Load Module
Large program may be developed in parts so that the program is in the form of a number of routines. Each of these routines is separately translated. The object routines or object module must then be combined together to form a load module or run unit, which is finally executed. The step that accomplishes the job of linking the object routines or load modules into one load module is called linkage editor.
The linkage editor converts an object module into a load module, and stores it in a partitioned data set. Linkage editor //STEP2 EXEC PGM=HEWL //SYSLIB DD DSNAME=CEE.SCEELKED,DISP=SHR //SYSPRINT DD SYSOUT=* //SYSLIN DD DSNAME=MTPLB00.COBOL.OBJLIB,DISP=(OLD,DELETE) //SYSLMOD DD DSNAME=MTPLB00.COBOL.LOADLIB(PGM1), // DISP=(MOD,PASS), // SPACE=(TRK,(10,10,1)) SYSLMOD and SYSPRINT are the data sets used for linkage editor output.
LINK-EDIT OPTIONS
Syntax:
//STEP2 EXEC PGM=HEWL, PARM=’CALL,PRINT,AMODE’
Figure: Link-edit Options
Notes:
CALL: Use CALL if your program calls external routines, in which case you want external references to
be resolved by automatic library call.
PRINT: When you use the print option, link-edit messages and the module map are written on the data set
defined by the SYSLOUT DD statement.
AMODE: AMODE use to override the default RMODE attribute established by the compiler.
RENT: RENT option is use to have the linkage editor mark the load module as being reentrant and reusable.
REUS: REUS option is use to have the linkage editor mark the load module as being reusable.
LOAD MODULE EXECUTION
Executing compiled program
The program is ready for execution that has completed the compiling and link editing successfully.
Syntax:
//STEP3 EXEC PGM=PGM1
//STEPLIB DD DSN=MTPLB00.COBOL.LOADLIB,DISP=SHR
EXECUTION TIME OPTIONS
Specify run-time options in the PARM parameter of the EXEC statement that starts execution. Syntax: //STEP3 EXEC PGM=A,PARM=’[user-parameter] [/execution-options]’
Figure 10.7 Execution time options Notes: Where user-parameter is the parameter to be passed to the program being executed. The execution-options are list of run-time options. A slash must immediately precede the first run time option. NOSSRANGE & SSRANGEL: NOSSRANGE suppresses run-time checking of index, subscript, reference modification and variable length group ranges. NOSSRANGE turns off run-time checking if compiled with SSRANGE. LANGUAGE: LANGUAGE option is use to specify the language and character set for those run-time messages generated prior to the full initialization. DEBUG & NODEBUG: NODEBUG suppresses the batch debugging features specified by the use for DEBUGGING declaratives. NOSTAE & STAE: NOSTAE prevents the run-time environment from intercepting an ABEND.
UNIT 10
COBOL Intrinsic Functions
Intrinsic Functions
Intrinsic functions allow you to access certain values that are derived at run time Examples Current-date Length Lower-case Date-of-integer Coded as part of statements in the Procedure Division FUNCTION is now a reserved word
Notes:
Intrinsic functions are coded in statements in the procedure division. The function is evaluated and the value participates in the statement execution. Functions may not stand alone they must be coded as part of another statement.
Notice that the word FUNCTION is now a reserved word in COBOL. But the names of the functions are not reserved.
Instrinsic Functions – Syntax
Specify the reserve word “FUNCTION” followed by the name
of the function
Instrinsic Functions may not be used as a receiving operand
Examples
Move function current-date to d-string
If function date-of-integer(base-date)……
When function day-of-integer(base-date)……
Intrinsic Functions – Arguments and Values
The number and format of the arguments depend on the function The resulting value is an elementary data item implicitly defined by COBOL Numeric and integer functions may only be used where arithmetic expressions may be
used If function value is a character(alphanumeric) string, the reference may be followed by a reference modification
Notes: The number and format of the arguments depend on the function The resulting value is an elementary data item implicitly defined by COBOL The value is a character string, a numeric value, or an integer The length of the result depends on the function and the length of the argument(s)
Move function current-date (1:8) to rpt-string
COBOL Intrinsic Functions – Date Formats
Range: January 1, 1601 to December 31, 9999
Gregorian Date – YYYYMMDD Integer Date - 1 to 3,067,671 number of days since December 31, 1600
Julian Date – YYYYDDD
Notes:
Before we examine date type intrinsic functions, we need to define threee basic date formats that COBOL can work with
Gregorian date, or Standard date
An eight digit date of the form YYYYMMDD In the range of January 1, 1601 throug December 31, 9999 With MM being from 01 through 12 and DD being from 01 through 31, dependent
upon the month
Integer date
An integer in the range 1 to 3,067,671
Represents the number of days since December 31, 1600
For example, January 1, 1994 is 143908 as an integer date
Julian date
A seven digit integer of the form YYYYDD
DDD is between 1 and 366, must be valid for the year(that is, leap year are taken into account)
COBOL Instrinsic Functions- CURRENT-DATE
MOVE FUNCTION CURRENT-DATE(1:8) TO DATE-ON-FILE
Returns a character string – length 21YYYYMMDDHHmmsshhShhmm
System Gregorian date Current time in 24 hour clock Difference from GMT
Notes:
Current-date returns a character string of length 21, as follows: YYYYMMDDHHmmsshhShhmm
Representing
A Gregorian date(YYYYMMDD) Current time in hours (24-hour clock), minutes, seconds, and hundredths of a
second(HHmmsshh) Difference of local time zone from Greenwich Mean Time as a ‘+’ or ‘-‘ followed by
the hours and minutes difference (Shhmm)
COBOL Intrinsic Functions – DATE-OF-INTEGER
COMPUTE RPT-DATE = FUNCTION DATE-OF-INTEGER(INT-DATE)
* If INT-DATE is integer 144337 then RPT-DATE is integer 19960317
Returns a Gregorian date using an inputted integer date
* Based on number of days since Dec. 31, 1600
* Integer could have been output of date intrinsic function modified by arithmetic
Notes:
Date-of-integer converts an integer date to a Gregorian date
Function date-of-integer(argument)
The argument must be a valid integer date
The function reference is an integer representing YYYYMMDD
COBOL Intrinsic Functions – INTEGER-OF-DAY
COMPUTE INT-DATE = FUNCTION INTEGER-OF-DAY(JUL-DATE) * If JUL-DATE is integer 1996107 then INT-DATE is integer 144337
Returns an integer using an inputeed Julian date
* Number of days since Dec. 31, 1600* Integer can be used for date arithmetic or date comparisons.
Notes:
Integer-of-day converts a Julian date to an integer date
Function integer-of-day(argument)
The argument must be a valid Julian date(YYYYDDD)
The function reference is an integer date
COBOL Intrinsic Functions – DAY-OF-INTEGER
COMPUTE JUL-DATE = FUNCTION DAY-OF-INTEGER(INT-DATE)
* If INT-DATE is integer 144337 then JUL-DATE is integer 1996107
Returns an Julian date using an inputeed Julian date
Based on number of days since Dec. 31, 1600 Integer could have been output of date intrinsic function of Gregorian date
Notes: Day-of-integer converts a Integer date to an Julian date Function integer-of-day(argument) The argument must be a valid integer date The function reference is an integer representing YYYYDDD
New Intrinsic Functions Overview
New Intrinsic Functions
DATE-To-YYYYMMDD
DAY-TO-YYYYDDD
YEAR-TO-YYYY
First function argument is date with two position year (yymmdd, yyddd, or yy)
Second function argument is an optional integer that is used in determination of 100-year range used in YY to YYYY conversion. Default is 50
Returned value is a date of the same type as the first argument but with a four digit year
Notes:
New Intrinsic Functions The second argument to these three functions is called the sliding window, and it works this way: Add the second argument to the current (run-time) year ( as a four digit year), giving an ending
year. For example, if a program is running in 1998 and the sliding window is 20, then the
result of the add is 2018. Subtract 99 from the ending year to get a 100-year range. For example, 1919-2018 For two digit years in the range of 00 to last-two-digits-of-end, assign the century from the
ending date; for two digit years in the range of last-two-digts-of-start to 99, assign the century from the starting date.
For example, the ranges are 00-18 and 19-99, so given a year of 82, assign a century of 19; given a year of 17, assign a century of 20.
RUN-TIME YEAR
INPUT VALUE SW Argument FUNCTION VALUE
1998 890315 -10 18890315
1998 770122 -10 19770122
1998 890315 -1 19890315
1998 770122 -1 19770122
1998 890315 0 19890315
1998 770122 0 19770122
1998 890315 85 19890315
1998 770315 85 20770315
1998 890315 -120
1998 890315 120
Intrinsic Function: DATE-TO-YYYYMMDD
Syntax
FUNCTION DATE-TO-YYYYMMDD (YYMMDD[SW]) Examples COMPUTE FUNCTION DATE-TO-YYYYMMDD (IN-HIRE-DATE) TO OUT-HIRE-DATE IF FUNCTION DATE-TO-YYYYMMDD (BIRTH-DATE-20) > QUERY-DATE THEN …. VALUE EXAMPLES:
Intrinsic Function: DATE-TO-YYYYDD
Syntax FUNCTION DATE-TO-YYYYDD (YYDD[SW]) Examples COMPUTE FUNCTION DATE-TO-YYYYDD (IST-LOGON-DAY) TO OUT-LOGON-DATE IF FUNCTION DATE-TO-YYYYDD(ID-DATE-20) > QUERY-DATE THEN …. VALUE EXAMPLES:
RUN-TIME YEAR
INPUT VALUE SW Argument FUNCTION VALUE
1998 89315 -10 1889315
1998 77122 -10 1977122
1998 89315 -1 1989315
1998 77122 -1 1977122
1998 89315 0 1989315
1998 77122 0 1977122
1998 89315 85 1989315
1998 77315 85 2077315
1998 89315 -120
1998 890315 120
Intrinsic Function: YEAR-TO-YYYY
Syntax FUNCTION YEAR-TO-YYYY (YY[SW]) Examples: MOVE FUNCTION YEAR-TO-YYYY(START-YEAR) TO OUT-START-YEAR IF FUNCTION DATE-TO-YYYYMMDD(B-DATE-20) > QUERY-DATE THEN …. VALUE EXAMPLES:
RUN-TIME YEAR
INPUT VALUE SW Argument FUNCTION VALUE
1998 89 -10 1889
1998 77 -10 1977
1998 89 -1 1989
1998 77 -1 1977
1998 89 0 1989
1998 77 0 1977
1998 89 85 1989
1998 77 85 2077
1998 89 -120
1998 89 120
COBOL Intrinsic Functions- Nesting functions
COMPUTE NEW-DUE-DATE =
FUNCTION DATE-OF-INTEGER
(FUNCTION INTEGER-OF-DATE(DATE-OF-ORDER) + 30)
IF DATE-OF-ORDER IS 19960317 then
FUNCTION INTEGER-OF-DATE(DATE-OF-ORDER) +30 is 14337+30 = 144367
FUCNTION DATE-OF-INTEGER(144367) gives NEW-DUE-DATE of 19960416
After Converting a Gregorian due to an integer date, and adding 30 days to the integer date, the newly calculated Gregorian date is displayed
Length Intrinsic Functions
MOVE IN-REC(1:FUNCTION LENGTH(OUT-AREA)) TO OUT-AREA
* If the length of OUT-AREA is 10, only positions 1 to 10 of IN-REC are move to OUT-AREA
Returns a nine-digit integer specifying the number of bytes the argument takes in storage.
The LENGTH OF special register and LENGTH intrinsic function work similarly.
LENGTH intrinsic function is more robust because it can have a literal operand and it works with null-terminated strings.
The syntax is different.
Notes: The length intrinsic function takes a single argument (a non-numeric literal, a data element, a structure, or an array) and returns a nine-digit integer specifying the numbe of bytes the argument takes in storage. Move in-rec(1:function length (out-area) ) to out-area.
LOWER-CASE and UPPER-CASE Intrinsic Functions
MOVE FUNCTION UPPER-CASE(ANSWER) TO UPPER-ANSWER
* IF ANSWER contains ‘y’ then UPPER-ANSWER contains ‘Y’
Returns a string that is either all upper case or lower case.
Alphanumeric data items of same length all in required case returned
Very useful in comparing two strings
Notes:
These two intrinsic functions return a character string that contains all lower-case or all upper-case characters
Function lower-case(argument)
Function upper-case(argument)
The argument is an alphanumeric data item
The function reference is a string of the same length as the argument but with all letters forced to
lower-case or upper-case, respectively
REVERSE Intrinsic Functions
IF FUNCTIO REVERSE(ASTRING) = ASTRING
PERFORM FOUND-PALINDROME
* If ASTRING contained ‘OTTO’ the paragraph FOUND-PALINDROME would be performed
Returns a string containing the characters of the argument in reverse order
Could be used to look for first non-blank character
In languages that are written from right to left
CHAR and ORD Intrinsic Functions
IF FUNCTION ORD(‘1’) < FUNCTION ORD(‘A’) PERFORM FOUND-ASCII
* If this IF is true then system is running using ASCII character set
CHAR(n) returns the character that is the ‘n’ the character in coding sequence
ORD(char) returns the position that character belongs in the collating sequence
* Used where coding scheme, ASCII or EBCDIC are not know until compile time.
Arithmetic, Business, and Mathematical Intrinsic Functions
Trigonometric and Logarithmic Intrinsic Functions
Function name Value returned
ACOS Arc-cosine of numeric item
ASIN Arc-sine of numeric item
ATAN Arc-tangent of numeric item
COS Cosins of numeric item
LOG Natural logarithm of numeric item
LOG10 Logarithm to base 10 of numeric item
SIN Sine of numeric item
TAN Tangent of numeric item
Arithmetic, Business, and Mathematical Intrinsic Function 2
Statistical and other Mathematical Intrinsic Functions
Function name Value returned
FACTORIAL Factorial value of “integer”. Item
INTEGER Greates integer not greater than “numeric” item
INTEGER-PART Value of “numeric” item truncated at decimal point
MAX Largest value in a list of values; all items in the list are of the same type, one of: “alphabetic”, “integer”, “numeric”, or “alphanumeric”
MEAN Arithmetic mean of list of “numeric” items
MEDIAN Median of list of “numeric” items
MIDRANGE Mean of the minimum and maximu values in a list of “numeric” items
MIN Smallest value in a list of values; see MAX
Arithmetic, Business, and Mathematical Intrinsic Function 3
Statistical and other Mathematical Intrinsic Functions, 2
Function name Value returned
MOD Modulo value of “integer” item to “integer” base
ORD-MAX Position of maximum item in a list
ORD-MIN Position of miniumum item in a list
RANDOM Random number based on supplied or default “integer” seed number
RANGE Value of maximum argument minus value of miniumum argument; all arguments either “integer” or all “numeric”
REM Remainder of dividing one “numeric” item by another “numeric” item
SQRT Square root of a “numeric” item
SUM Sum of list of items, all items are “numeric” or all are “integer”
Arithmetic, Business, and Mathematical Intrinsic Function, 4
Conversion Type Intrinsic Functions
Function name Value returned
NUMVAL Numeric value of numeric edited item
NUMVAL-C Numeric value of numeric edited item with currency symbol
Investment / Depreciation Statistical Type Intrinsic Functions
Function name Value returned
ANUITY Ratio of annuity paid for “integer” periods at “numeric” interest, on initial investment of 1
PRESENT-VALUE
Present value using “numeric” discount rate for 1 or more periods, the value in each period specified as a “numeric” item
STANDARD-DEVIATION
Standard deviatio of list of “numeric” items
VARIANCE Variance of list of “numeric” items
MIN and MAX Intrinsic Functions
COMPUTE MAX-HOLD = FUNCTION MAX(EMP1SALES, EMP2SALES,
EMP3SALES, EMP4SALES,EMP5SALES)
MAX-HOLD would contain the highest value of all elements in the list.
The MAX function returns the value of the largest item in a list of items, the MIN function returns
the value of the smallest item.
The argument in example are assumed to be numeric so compute had to be used
The ALL Subscript
COMPUTE TOTAL-IN = FUNCTION SUM(STORE-SALES(ALL)
TOTAL-IN will be equal to the summation of all elements of the STORE-SALES table array
When an intrinsic function may have a variable number of arguments, you may reference a table
as one or more of the arguments.
* If a multidimensional table, ALL may be used in place of one or more of the subscripts