Pro*COBOL Precompiler Programmer's Guide
Release 8.0

A58232-01

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12
Using Dynamic SQL: Advanced Concepts

This chapter shows you how to implement dynamic SQL Method 4, which lets your program accept or build dynamic SQL statements that contain a varying number of host variables. Subjects discussed include the following:

Meeting the Special Requirements of Method 4

Before looking into the requirements of Method 4, you should feel comfortable with the terms select-list item and place-holder. Select-list items are the columns or expressions following the keyword SELECT in a query. For example, the following dynamic query contains three select-list items:

SELECT ENAME, JOB, SAL + COMM FROM EMP WHERE DEPTNO = 20

Place-holders are dummy bind (input) variables that hold places in a SQL statement for actual bind variables. You do not declare place-holders and can name them anything you like. place-holders for bind variables are most often used in the SET, VALUES, and WHERE clauses. For example, the following dynamic SQL statements each contain two place-holders.

INSERT INTO EMP (EMPNO, DEPTNO) VALUES (:E, :D)
DELETE FROM DEPT WHERE DEPTNO = :DNUM AND LOC = :DLOC

place-holders cannot reference table or column names.

What Makes Method 4 Special?

Unlike Methods 1, 2, and 3, dynamic SQL Method 4 lets your program

To add this flexibility to your program, you must give the Oracle8 runtime library additional information.

What Information Does Oracle8 Need?

The Pro*COBOL Precompiler generates calls to Oracle8 for all executable dynamic SQL statements. If a dynamic SQL statement contains no select-list items or place-holders, Oracle8 needs no additional information to execute the statement. The following DELETE statement falls into this category:

*    Dynamic SQL statement...
     MOVE 'DELETE FROM EMP WHERE DEPTNO = 30' TO STMT.

However, most dynamic SQL statements contain select-list items or place-holders for bind variables, as shown in the following UPDATE statement:

*    Dynamic SQL statement with place-holders...
     MOVE 'UPDATE EMP SET COMM = :C WHERE EMPNO = :E' TO STMT.

To execute a dynamic SQL statement that contains select-list items and/or place-holders for bind variables, Oracle8 needs information about the program variables that will hold output or input values. Specifically, Oracle8 needs the following information:

For example, to write the value of a select-list item, Oracle8 needs the address of the corresponding output variable.

Where Is the Information Stored?

All the information Oracle8 needs about select-list items or place-holders for bind variables, except their values, is stored in a program data structure called the SQL Descriptor Area (SQLDA).

Descriptions of select-list items are stored in a select SQLDA, and descriptions of place-holders for bind variables are stored in a bind SQLDA.

The values of select-list items are stored in output buffers; the values of bind variables are stored in input buffers. You use the library routine SQLADR to store the addresses of these data buffers in a select or bind SQLDA, so that Oracle8 knows where to write output values and read input values.

How do values get stored in these data variables? Output values are FETCHed using a cursor, and input values are filled in by your program, typically from information entered interactively by the user.

How Is the Information Obtained?

You use the DESCRIBE statement to help get the information Oracle8 needs. The DESCRIBE SELECT LIST statement examines each select-list item to determine its name, datatype, constraints, length, scale, and precision, then stores this information in the select SQLDA for your use. For example, you might use select-list names as column headings in a printout. DESCRIBE also stores the total number of select-list items in the SQLDA.

The DESCRIBE BIND VARIABLES statement examines each place-holder to determine its name and length, then stores this information in an input buffer and bind SQLDA for your use. For example, you might use place-holder names to prompt the user for the values of bind variables.

Understanding the SQL Descriptor Area (SQLDA)

This section describes the SQLDA data structure in detail. You learn how to declare it, what variables it contains, how to initialize them, and how to use them in your program.

Purpose of the SQLDA

Method 4 is required for dynamic SQL statements that contain an unknown number of select-list items or place-holders for bind variables. To process this kind of dynamic SQL statement, your program must explicitly declare SQLDAs, also called descriptors. Each descriptor corresponds to a group item in your program.

A select descriptor stores descriptions of select-list items and the addresses of output buffers that hold the names and values of select-list items.

Note: The name of a select-list item can be a column name, a column alias, or the text of an expression such as SAL + COMM.

A bind descriptor stores descriptions of bind variables and indicator variables, and the addresses of input buffers where the names and values of bind variables and indicator variables are stored.

Remember, some descriptor variables contain addresses, not values. So, you must declare data buffers to hold the values. You decide the sizes of the required input and output buffers. Because COBOL does not support pointers, you must use the library subroutine SQLADR to get the addresses of input and output buffers. You learn how to call SQLADR in the section "Using SQLADR" on page 12-14.

Multiple SQLDAs

If your program has more than one active dynamic SQL statement, each statement must have its own SQLDA(s). You can declare any number of SQLDAs with different names. For example, you might declare three select SQLDAs named SELDSC1, SELDSC2, and SELDSC3, so that you can FETCH from three concurrently open cursors. However, non-concurrent cursors can reuse SQLDAs.

Declaring a SQLDA

To declare select and bind SQLDAs, you can hardcode them into your program using the sample select and bind SQLDAs shown in Figure 12-1. You can modify the table dimensions to suit your needs.

Note: For byte-swapped platforms, use COMP5 instead of COMP when declaring a SQLDA.

Figure 12-1 Sample Pro*COBOL SQLDA Descriptors and Data Buffers

You might want to store the SQLDAs in files (named SELDSC and BNDDSC, for example), then copy the files into your program with the INCLUDE statement as follows:

     EXEC SQL INCLUDE SELDSC END-EXEC.
     EXEC SQL INCLUDE BNDDSC END-EXEC.

Figure 12-2 shows whether variables are set by SQLADR calls, DESCRIBE commands, FETCH commands, or program assignments.

Figure 12-2 How Variables Are Set

The SQLDA Variables

This section explains the purpose and use of each variable in the SQLDA.

SQLDNUM

This variable specifies the maximum number of select-list items or place-holders that can be DESCRIBEd. Thus, SQLDNUM determines the number of elements in the descriptor tables.

Before issuing a DESCRIBE command, you must set this variable to the dimension of the descriptor tables. After the DESCRIBE, you must reset it to the actual number of variables DESCRIBEd, which is stored in SQLDFND.

SQLDFND

This is the actual number of select-list items or place-holders found by the DESCRIBE command.

SQLDFND is set by DESCRIBE. If SQLDFND is negative, the DESCRIBE command found too many select-list items or place-holders for the size of the descriptor. For example, if you set SQLDNUM to 10 but DESCRIBE finds 11 select-list items or place-holders, SQLDFND is set to -11. If this happens, you cannot process the SQL statement without reallocating the descriptor.

After the DESCRIBE, you must set SQLDNUM equal to SQLDFND.

SELDV|BNDDV

This is a table containing the addresses of data buffers that store select-list or bind-variable values.

You must set the elements of SELDV or BNDDV using SQLADR.

Select Descriptors

The following statement

     EXEC SQL FETCH ... USING DESCRIPTOR ...

directs Oracle8 to store FETCHed select-list values in the data buffers addressed by SELDV(1) through SELDV(SQLDNUM). Thus, Oracle8 stores the Jth select-list value in SEL-DV(J).

Bind Descriptors

You must set this table before issuing the OPEN command. The following statement

     EXEC SQL OPEN ... USING DESCRIPTOR ...

directs Oracle8 to execute the dynamic SQL statement using the bind-variable values addressed by BNDDV(1) through BNDDV(SQLDNUM). (Typically, the values are entered by the user.) Oracle8 finds the Jth bind-variable value in BND-DV(J).

SELDFMT|BNDDFMT

This is a table containing the addresses of data buffers that store select-list or bind-variable conversion format strings. Currently, you can use it only for COBOL packed decimals. The format for the conversion string is PP.+SS or PP.-SS where PP is the precision and SS is the scale. For definitions of precision and scale, see the section "Extracting Precision and Scale" on page 12-20.

The use of format strings is optional. If you want a conversion format for the Jth select-list item or bind variable, set SELDFMT(J) or BNDDFMT(J) using SQLADR, then store the packed-decimal format ("07.+02" for example) in SEL-DFMT or BND-DFMT. Otherwise, set SELDFMT(J) or BNDDFMT(J) to zero.

SELDVLN|BNDDVLN

This is a table containing the lengths of select-list or bind-variable values stored in the data buffers.

Select Descriptors

DESCRIBE SELECT LIST sets the table of lengths to the maximum expected for each select-list item. However, you might want to reset some lengths before issuing a FETCH command. FETCH returns at most n characters, where n is the value of SELDVLN(J) before the FETCH command.

The format of the length differs among Oracle8 datatypes. For CHAR select-list items, DESCRIBE SELECT LIST sets SELDVLN(J) to the maximum length in bytes of the select-list item. For NUMBER select-list items, scale and precision are returned respectively in the low and next-higher bytes of the variable. You can use the library routine SQLPRC to extract precision and scale values from SELDVLN. See the section "Extracting Precision and Scale" on page 12-20.

You must reset SELDVLN(J) to the required length of the data buffer before the FETCH. For example, when coercing a NUMBER to a COBOL character string, set SELDVLN(J) to the precision of the number plus two for the sign and decimal point. When coercing a NUMBER to a COBOL floating point number, set SELDVLN(J) to the length of the appropriate floating point type on your system. For more information about the lengths of coerced datatypes, see the section "Converting Data" on page 12-15.

Bind Descriptors

You must set the table of lengths before issuing the OPEN command. For example, you can use the following statements to set the lengths of bind-variable character strings entered by the user:

 PROCEDURE DIVISION. 
     ... 
     PERFORM GET-INPUT-VAR 
         VARYING J FROM 1 BY 1 UNTIL J > SQLDNUM IN BNDDSC. 
     ... 
 GET-INPUT-VAR. 
     DISPLAY "Enter value of ", BND-DH-VNAME(J). 
     ACCEPT INPUT-STRING. 
     UNSTRING INPUT-STRING DELIMITED BY "  " 
         INTO BND-DV(J) COUNT IN BNDDVLN(J). 

Because Oracle8 accesses a data buffer indirectly, using the address in SELDV(J) or BNDDV(J), it does not know the length of the value in that buffer. If you want to change the length Oracle8 uses for the Jth select-list or bind-variable value, reset SELDVLN(J) or BNDDVLN(J) to the length you need. Each input or output buffer can have a different length.

SELDFMTL | BNDDFMTL

This is a table containing the lengths of select-list or bind-variable conversion format strings. Currently, you can use it only for COBOL packed decimal.

The use of format strings is optional. If you want a conversion format for the Jth select-list item or bind variable, set SELDFMTL(J) before the FETCH or BNDDFMTL(J) before the OPEN to the length of the packed-decimal format stored in SEL-DFMT or BND-DFMT. Otherwise, set SELDFMTL(J) or BNDDFMTL(J) to zero.

If the value of SELDFMTL(J) or BNDDFMTL(J) is zero, SELDFMT(J) or BNDDFMT(J) is not used.

SELDVTYP|BNDDVTYP

This is a table containing the datatype codes of select-list or bind-variable values. These codes determine how Oracle8 data is converted when stored in the data buffers addressed by elements of SELDV. This topic is covered in "Converting Data" on page 12-15.

Select Descriptors

DESCRIBE SELECT LIST sets the table of datatype codes to the internal datatype (for example, VARCHAR2, CHAR, NUMBER, or DATE) of the items in the select list.

Before FETCHing, you might want to reset some datatypes because the internal format of Oracle8 datatypes can be difficult to handle. For display purposes, it is usually a good idea to coerce the datatype of select-list values to VARCHAR2. For calculations, you might want to coerce numbers from Oracle8 to COBOL format. See "Coercing Datatypes" on page 12-18.

The high bit of SELDVTYP(J) is set to indicate the null/not null status of the Jth select-list column. You must always clear this bit before issuing an OPEN or FETCH command. You use the library routine SQLNUL to retrieve the datatype code and clear the null/not null bit. For more information, see "Handling Null/Not Null Datatypes" on page 12-21.

You should change the Oracle8 NUMBER internal datatype to an external datatype compatible with that of the COBOL data buffer addressed by SELDV(J).

Bind Descriptors

DESCRIBE BIND VARIABLES sets the table of datatype codes to zeros. You must reset the table of datatypes before issuing the OPEN command. The code represents the external (COBOL) datatype of the buffer addressed by BNDDV(J). Often, bind-variable values are stored in character strings, so the datatype table elements are set to 1 (the VARCHAR2 datatype code).

To change the datatype of the Jth select-list or bind-variable value, reset SELDVTYP(J) or BNDDVTYP(J) to the datatype you want.

SELDI|BNDDI

This is a table containing the addresses of data buffers that store indicator-variable values. You must set the elements of SELDI or BNDDI using SQLADR.

Select Descriptors

You must set this table before issuing the FETCH command. When Oracle8 executes the statement

     EXEC SQL FETCH ... USING DESCRIPTOR ... 

if the Jth returned select-list value is null, the buffer addressed by SELDI(J) is set to -1. Otherwise, it is set to zero (the value is not null) or a positive integer (the value was truncated).

Bind Descriptors

You must initialize this table and set the associated indicator variables before issuing the OPEN command. When Oracle8 executes the statement

     EXEC SQL OPEN ... USING DESCRIPTOR ...

the buffer addressed by BNDDI(J) determines whether the Jth bind variable is null. If the value of an indicator variable is -1, its associated bind variable is null.

SELDH-VNAME|BNDDH-VNAME

This is a table containing the addresses of data buffers that store select-list or place-holder names as they appear in dynamic SQL statements. You must set the elements of SELDH-VNAME or BNDDH-VNAME using SQLADR before issuing the DESCRIBE command.

DESCRIBE directs Oracle8 to store the name of the Jth select-list item or place-holder in the data buffer addressed by SELDH-VNAME(J) or BNDDH-VNAME(J). Thus, Oracle8 stores the Jth select-list or place-holder name in SEL-DH-VNAME(J) or BND-DH-VNAME(J).

SELDH-MAX-VNAMEL|BNDDH-MAX-VNAMEL

This is a table containing the maximum lengths of the data buffers that store select-list or place-holder names. The buffers are addressed by the elements of SELDH-VNAME or BNDDH-VNAME.

You must set the elements of SELDH-MAX-VNAMEL or BNDDH-MAX-VNAMEL before issuing the DESCRIBE command. Each select-list or place-holder name buffer can have a different length.

SELDH-CUR-VNAMEL|BNDDH-CUR-VNAMEL

This is a table containing the actual lengths of the names of the select-list or place-holder. DESCRIBE sets the table of actual lengths to the number of characters in each select-list or place-holder name.

SELDI-VNAME|BNDDI-VNAME

This is a table containing the addresses of data buffers that store indicator-variable names.

You can associate indicator-variable values with select-list items and bind variables. However, you can associate indicator-variable names only with bind variables. So, you can use this table only with bind descriptors. You must set the elements of BNDDI-VNAME using SQLADR before issuing the DESCRIBE command.

DESCRIBE BIND VARIABLES directs Oracle8 to store any indicator-variable names in the data buffers addressed by BNDDI-VNAME(1) through BNDDI-VNAME(SQLDNUM). Thus, Oracle8 stores the Jth indicator-variable name in BND-DI-VNAME(J).

SELDI-MAX-VNAMEL|BNDDI-MAX-VNAMEL

This is a table containing the maximum lengths of the data buffers that store indicator-variable names. The buffers are addressed by the elements of SELDI-VNAME or BNDDI-VNAME.

You can associate indicator-variable names only with bind variables. So, you can use this table only with bind descriptors.

You must set the elements BNDDI-MAX-VNAMEL(1) through BNDDI-MAX-VNAMEL(SQLDNUM) before issuing the DESCRIBE command. Each indicator-variable name buffer can have a different length.

SELDI-CUR-VNAMEL|BNDDI-CUR-VNAMEL

This is a table containing the actual lengths of the names of the indicator variables. You can associate indicator-variable names only with bind variables. So, you can use this table only with bind descriptors.

DESCRIBE BIND VARIABLES sets the table of actual lengths to the number of characters in each indicator-variable name.

SELDFCLP|BNDDFCLP

This is a table reserved for future use. It must be present because Oracle8 expects the group item SELDSC or BNDDSC to be a certain size. You must set the elements of SELDFCLP or BNDDFCLP to zero.

SELDFCRCP|BNDDFCRCP

This is a table reserved for future use. It must be present because Oracle8 expects the group item SELDSC or BNDDSC to be a certain size. You must set the elements of SELDFCRCP or BNDDFCRCP to zero.

Some Preliminaries

You need a working knowledge of the following subjects to implement dynamic SQL Method 4:

Using SQLADR

You must call the library subroutine SQLADR to get the addresses of data buffers that store input and output values. You store the addresses in a bind or select SQLDA so that Oracle8 knows where to read bind-variable values or write select-list values.

Call SQLADR using the syntax

     CALL "SQLADR" USING BUFFER, ADDRESS.

where:

BUFFER

Is a data buffer that stores the value or name of a select-list item, bind variable, or indicator variable.

ADDRESS

Is an integer variable that returns the address of the data buffer.

A call to SQLADR stores the address of BUFFER in ADDRESS. In the next example, you use SQLADR to initialize the select descriptor tables SELDV, SELDH-VNAME, and SELDI. Their elements address data buffers for select-list values, select-list names, and indicator values.

 PROCEDURE DIVISION.
     ... 
     PERFORM INIT-SELDSC 
         VARYING J FROM 1 BY 1 UNTIL J > SQLDNUM IN SELDSC.
     ... 
 INIT-SELDSC.
     CALL "SQLADR" USING SEL-DV(J), SELDV(J).
     CALL "SQLADR" USING SEL-DH-VNAME(J), SELDH-VNAME(J).
     CALL "SQLADR" USING SEL-DI(J), SELDI(J).

Converting Data

This section provides more detail about the datatype descriptor table. In host programs that use neither datatype equivalencing nor dynamic SQL Method 4, the conversion between Oracle8 internal and external datatypes is determined at precompile time. By default, Pro*COBOL assigns a specific external datatype to each host variable. For example, Pro*COBOL assigns the INTEGER external datatype to host variables of type PIC S9(n) COMP.

However, Method 4 lets you control data conversion and formatting. You specify conversions by setting datatype codes in the datatype descriptor table.

Internal Datatypes

Internal datatypes specify the formats used by Oracle8 to store column values in database tables and the formats to represent pseudocolumn values.

When you issue a DESCRIBE SELECT LIST command, Oracle8 returns the internal datatype code for each select-list item to the SELDVTYP (datatype) descriptor table. For example, the datatype code for the Jth select-list item is returned to SELDVTYP(J).

Table 12-1 shows the Oracle8 internal datatypes and their codes.

Oracle8 Internal Datatype   Code  

VARCHAR2

NUMBER

LONG

ROWID

DATE

RAW

LONG RAW

CHAR

MLSLABEL

 

1

2

8

11

12

23

24

96

105

 

External Datatypes

External datatypes specify the formats used to store values in input and output host variables.

The DESCRIBE BIND VARIABLES command sets the BNDDVTYP table of datatype codes to zeros. So, you must reset the codes before issuing the OPEN command. The codes tell Oracle8 which external datatypes to expect for the various bind variables. For the Jth bind variable, reset BNDDVTYP(J) to the external datatype you want.

The following table shows the Oracle8 external datatypes and their codes, as well as the corresponding COBOL datatypes:

Name   Code   COBOL Datatype  

VARCHAR2

 

1

 

PIC X(n) when MODE != ANSI

 

NUMBER

 

2

 

PIC X(n)

 

INTEGER

 

3

 

PIC S9(n) COMP

PIC S9(n) COMP5

(COMP5 for byte-swapped platforms)

 

FLOAT

 

4

 

COMP-1

COMP-2

 

STRING (1)

 

5

 

PIC X(n)

 

VARNUM

 

6

 

PIC X(n)

 

DECIMAL

 

7

 

PIC S9(n)V9(n) COMP-3

 

LONG

 

8

 

PIC X(n)

 

VARCHAR (2)

 

9

 

PIC X(n) VARYING

PIC N(n) VARYING

 

ROWID

 

11

 

PIC X(n)

 

DATE

 

12

 

PIC X(n)

 

VARRAW (2)

 

15

 

PIC X(n)

 

RAW

 

23

 

PIC X(n)

 

LONG RAW

 

24

 

PIC X(n)

 

UNSIGNED

 

68

 

(not supported)

 

DISPLAY

 

91

 

PIC S9...9V9...9 DISPLAY SIGN LEADING SEPARATE

PIC S9(n)V9(n) DISPLAY SIGN

LEADING SEPARATE

 

LONG VARCHAR (2)

 

94

 

PIC X(n)

 

LONG VARRAW (2)

 

95

 

PIC X(n)

 

CHARF

 

96

 

PIC X(n) when MODE = ANSI

PIC N(n) when MODE = ANSI

 

CHARZ (1)

 

97

 

PIC X(n)

 

CURSOR

 

102

 

SQL-CURSOR

 

MLSLABEL

 

106

 

PIC X(n)

 

Notes:

  1. For use in an EXEC SQL VAR statement only.
  2. Include the n-byte length field.

For more information about the Oracle8 datatypes and their formats, see "The Oracle8 Datatypes" on page 4-2.

PL/SQL Datatypes

PL/SQL provides a variety of predefined scalar and composite datatypes. A scalar type has no internal components. A composite type has internal components that can be manipulated individually. Table 12-3 shows the predefined PL/SQL scalar datatypes and their Oracle8 internal datatype equivalences.

PL/SQL Datatype   Oracle8 Internal Datatype  

VARCHAR

VARCHAR2

 

VARCHAR2

 

BINARY_INTEGER

DEC

DECIMAL

DOUBLE PRECISION

FLOAT

INT

INTEGER

NATURAL

NUMBER

NUMERIC

POSITIVE

REAL

SMALLINT

 

NUMBER

 

LONG

 

LONG

 

ROWID

 

ROWID

 

DATE

 

DATE

 

RAW

 

RAW

 

LONG RAW

 

LONG RAW

 

CHAR

CHARACTER

STRING

 

CHAR

 

MLSLABEL

 

MLSLABEL

 

Coercing Datatypes

For a select descriptor, DESCRIBE SELECT LIST can return any of the Oracle8 internal datatypes. Often, as in the case of character data, the internal datatype corresponds exactly to the external datatype you want to use. However, a few internal datatypes map to external datatypes that can be difficult to handle. So, you might want to reset some elements in the SELDVTYP descriptor table.

For example, you might want to reset NUMBER values to FLOAT values, which correspond to PIC S9(n)V9(n) COMP-1 values in COBOL. Oracle8 does any necessary conversion between internal and external datatypes at FETCH time. So, be sure to reset the datatypes after the DESCRIBE SELECT LIST but before the FETCH.

For a bind descriptor, DESCRIBE BIND VARIABLES does not return the datatypes of bind variables, only their number and names. Therefore, you must explicitly set the BNDDVTYP table of datatype codes to tell Oracle8 the external datatype of each bind variable. Oracle8 does any necessary conversion between external and internal datatypes at OPEN time.

When you reset datatype codes in the SELDVTYP or BNDDVTYP descriptor table, you are "coercing datatypes." For example, to coerce the Jth select-list value to VARCHAR2, use the following statement:

*    Coerce select-list value to VARCHAR2. 
     MOVE 1 TO SELDVTYP(J). 

When coercing a NUMBER select-list value to VARCHAR2 for display purposes, you must also extract the precision and scale bytes of the value and use them to compute a maximum display length. Then, before the FETCH, you must reset the appropriate element of the SELDVLN (length) descriptor table to tell Oracle8 the buffer length to use. To specify the length of the Jth select-list value, set SELDVLN(J) to the length you need.

For example, if DESCRIBE SELECT LIST finds that the Jth select-list item is of type NUMBER, and you want to store the returned value in a COBOL variable declared as PIC S9(n)V9(n) COMP-1, simply set SELDVTYP(J) to 4 and SELDVLN(J) to the length of COMP-1 numbers on your system.

Exceptions

In some cases, the internal datatypes that DESCRIBE SELECT LIST returns might not suit your purposes. Two examples of this are DATE and NUMBER. When you DESCRIBE a DATE select-list item, Oracle8 returns the datatype code 12 to the SELDVTYP table. Unless you reset the code before the FETCH, the date value is returned in its 7-byte internal format. To get the date in its default character format, you must change the datatype code from 12 to 1 (VARCHAR2), and increase the SELDVLN value from 7 to 9.

Similarly, when you DESCRIBE a NUMBER select-list item, Oracle8 returns the datatype code 2 to the SELDVTYP table. Unless you reset the code before the FETCH, the numeric value is returned in its internal format, which is probably not what you want. So, change the code from 2 to 1 (VARCHAR2), 3 (INTEGER), 4 (FLOAT), or some other appropriate datatype.

Extracting Precision and Scale

The library subroutine SQLPRC extracts precision and scale. Normally, it is used after the DESCRIBE SELECT LIST, and its first parameter is SELDVLN(J). To call SQLPRC, use the following syntax

     CALL "SQLPRC" USING LENGTH, PRECISION, SCALE.

where:

LENGTH   Is an integer variable that stores the length of an Oracle8 NUMBER value. The scale and precision of the value are stored in the low and next-higher bytes, respectively.  
PRECISION   Is an integer variable that returns the precision of the NUMBER value. Precision is the number of significant digits. It is set to zero if the select-list item refers to a NUMBER of unspecified size. In this case, because the size is unspecified, assume the maximum precision, 38.  
SCALE   Is an integer variable that returns the scale of the NUMBER value. Scale specifies where rounding will occur. For example, a scale of 2 means the value is rounded to the nearest hundredth (3.456 becomes 3.46); a scale of -3 means that the number is rounded to the nearest thousand (3.456 becomes 3000).  

The following example shows how SQLPRC is used to compute maximum display lengths for NUMBER values that will be coerced to VARCHAR2:

 WORKING-STORAGE SECTION. 
     01  PRECISION       PIC S9(9) COMP. 
     01  SCALE           PIC S9(9) COMP. 
     01  DISPLAY-LENGTH  PIC S9(9) COMP. 
     01  MAX-LENGTH      PIC S9(9) COMP VALUE 80. 
     ... 
 PROCEDURE DIVISION. 
     ... 
     PERFORM ADJUST-LENGTH 
         VARYING J FROM 1 BY 1 UNTIL J > SQLDNUM IN SELDSC. 
 ADJUST-LENGTH. 
*    If datatype is NUMBER, extract precision and scale. 
     IF SELDVTYP(J) = 2 
         CALL "SQLPRC" USING SELDVLN(J), PRECISION, SCALE. 
     MOVE 0 TO DISPLAY-LENGTH. 
*    Precision is set to zero if the select-list item 
*    refers to a NUMBER of unspecified size.  We allow for 
*    a maximum precision of 10. 
     IF SELDVTYP(J) = 2 AND PRECISION = 0 
         MOVE 10 TO DISPLAY-LENGTH. 
*    Allow for possible decimal point and sign. 
     IF SELDVTYP(J) = 2 AND PRECISION > 0 
         ADD 2 TO PRECISION 
         MOVE PRECISION TO DISPLAY-LENGTH. 
     ... 

Notice that the first parameter in the subroutine call is the Jth element in the table of select-list lengths.

The SQLPRC procedure, defined in the SQLLIB runtime library, returns zero as the precision and scale values for certain SQL datatypes. The SQLPR2 procedure is similar to SQLPRC in that it has the same syntax and returns the same binary values, except for the datatypes shown in Table 12-4

.

SQL Datatype   Binary Precision   Binary Scale  

FLOAT

 

126

 

-127

 

FLOAT(n)

 

n (range is 1 .. 126)

 

-127

 

REAL

 

63

 

-127

 

DOUBLE PRECISION

 

126

 

-127

 

Handling Null/Not Null Datatypes

For every select-list column (not expression), DESCRIBE SELECT LIST returns a null/not null indication in the datatype table of the select descriptor. If the Jth select-list column is constrained to be not null, the high-order bit of SELDVTYP(J) datatype variable is clear; otherwise, it is set.

Before using the datatype in an OPEN or FETCH statement, if the null status bit is set, you must clear it. Never set the bit.

You can use the library routine SQLNUL to find out if a column allows nulls, and to clear the datatype's null status bit. You call SQLNUL using the syntax

     CALL "SQLNUL" USING VALUE-TYPE, TYPE-CODE, NULL-STATUS.

where:

VALUE-TYPE   Is a 2-byte integer variable that stores the datatype code of a select-list column.  
TYPE-CODE   Is a 2-byte intger variable that returns the datatype code of the select-list column with the high-order bit cleared.  
NULL-STATUS   Is an integer variable that returns the null status of the select-list column. 1 means that the column allows nulls; 0 means that it does not.  

The following example shows how to use SQLNUL:

 WORKING-STORAGE SECTION.
     ... 
*    Declare variable for subroutine call.
     01  NULL-STATUS  PIC S9(9) COMP.
     ... 
 PROCEDURE DIVISION.
 MAIN.
     EXEC SQL WHENEVER SQLERROR GOTO SQL-ERROR END-EXEC.
     ...
     PERFORM HANDLE-NULLS
         VARYING J FROM 1 BY 1 UNTIL J > SQLDNUM IN SELDSC.
     ...
 HANDLE-NULLS.
*    Find out if column is NOT NULL, and clear high-order bit.
     CALL "SQLNUL" USING SELDVTYP(J), SELDVTYP(J), NULL-STATUS.
*    If NULL-STATUS = 1, nulls are allowed.

Notice that the first and second parameters in the subroutine call are the same. Respectively, they are the datatype variable before and after its null status bit is cleared.

The Basic Steps

Method 4 can be used to process any dynamic SQL statement. In the example in "Using Host Tables with Method 4" on page 12-40, a query is processed so that you can see how both input and output host variables are handled.

To process the dynamic query, our example program takes the following steps:

  1. Declare a host string to hold the query text.
  2. Declare select and bind descriptors.
  3. Set the maximum number of select-list items and place-holders that can be DESCRIBEd.
  4. Initialize the select and bind descriptors.
  5. Store the query text in the host string.
  6. PREPARE the query from the host string.
  7. DECLARE a cursor FOR the query.
  8. DESCRIBE the bind variables INTO the bind descriptor.
  9. Reset the number of place-holders to the number actually found by DESCRIBE.
  10. Get values for the bind variables found by DESCRIBE.
  11. OPEN the cursor USING the bind descriptor.
  12. DESCRIBE the select list INTO the select descriptor.
  13. Reset the number of select-list items to the number actually found by DESCRIBE.
  14. Reset the length and datatype of each select-list item for display purposes.
  15. FETCH a row from the database INTO data buffers using the select descriptor.
  16. Process the select-list values returned by FETCH.
  17. CLOSE the cursor when there are no more rows to FETCH.

    Note: If the dynamic SQL statement is not a query or contains a known number of select-list items or place-holders, then some of the above steps are unnecessary.

A Closer Look at Each Step

This section discusses each step in more detail. Also, at the end of this chapter is a full-length program illustrating Method 4. With Method 4, you use the following sequence of embedded SQL statements:

     EXEC SQL
         PREPARE <statement_name>
         FROM {:<host_string>|<string_literal>}
     END-EXEC.
     EXEC SQL 
         DECLARE <cursor_name> CURSOR FOR <statement_name>
     END-EXEC.
     EXEC SQL
         DESCRIBE BIND VARIABLES FOR <statement_name>
         INTO <bind_descriptor_name>
     END-EXEC.
     EXEC SQL
         OPEN <cursor_name> 
         [USING DESCRIPTOR <bind_descriptor_name>]
     END-EXEC.
     EXEC SQL
         DESCRIBE [SELECT LIST FOR] <statement_name>
         INTO <select_descriptor_name>
     END-EXEC.
     EXEC SQL
         FETCH <cursor_name> USING DESCRIPTOR <select_descriptor_name>
     END-EXEC.
     EXEC SQL
         CLOSE <cursor_name>
     END-EXEC.

If the number of select-list items in a dynamic query is known, you can omit DESCRIBE SELECT LIST and use the following Method 3 FETCH statement:

EXEC SQL FETCH <cursor_name> INTO <host_variable_list> END-EXEC.

Or, if the number of place-holders for bind variables in a dynamic SQL statement is known, you can omit DESCRIBE BIND VARIABLES and use the following Method 3 OPEN statement:

     EXEC SQL OPEN <cursor_name> [USING <host_variable_list>] END-EXEC.

Next, you see how these statements allow your host program to accept and process a dynamic SQL statement using descriptors.

Note: Several figures accompany the following discussion. To avoid cluttering the figures, it was necessary to confine descriptor tables to 3 elements and to limit the maximum length of names and values to 5 and 10 characters, respectively.

Declare a Host String

Your program needs a host variable to store the text of the dynamic SQL statement. The host variable (SELECT-STMT in our example) must be declared as a character string:

     EXEC SQL BEGIN DECLARE SECTION END-EXEC. 
         ... 
         01  SELECT-STMT  PIC X(120). 
     EXEC SQL END DECLARE SECTION END-EXEC. 

Declare the SQLDAs

Because the query in our example might contain an unknown number of select-list items or place-holders, you must declare select and bind descriptors. Instead of hardcoding the SQLDAs, you use INCLUDE to copy them into your program, as follows:

     EXEC SQL INCLUDE SELDSC END-EXEC. 
     EXEC SQL INCLUDE BNDDSC END-EXEC. 

For reference, the INCLUDEd declaration of SELDSC follows:

 WORKING-STORAGE SECTION. 
     ... 
     01  SELDSC. 
         05  SQLDNUM              PIC S9(9) COMP. 
         05  SQLDFND              PIC S9(9) COMP. 
         05  SELDVAR              OCCURS 3 TIMES. 
             10 SELDV             PIC S9(9) COMP. 
             10 SELDFMT           PIC S9(9) COMP. 
             10 SELDVLN           PIC S9(9) COMP. 
             10 SELDFMTL          PIC S9(4) COMP. 
             10 SELDVTYP          PIC S9(4) COMP. 
             10 SELDI             PIC S9(9) COMP. 
             10 SELDH-VNAME       PIC S9(9) COMP. 
             10 SELDH-MAX-VNAMEL  PIC S9(4) COMP. 
             10 SELDH-CUR-VNAMEL  PIC S9(4) COMP. 
             10 SELDI-VNAME       PIC S9(9) COMP. 
             10 SELDI-MAX-VNAMEL  PIC S9(4) COMP. 
             10 SELDI-CUR-VNAMEL  PIC S9(4) COMP. 
             10 SELDFCLP          PIC S9(9) COMP. 
             10 SELDFCRCP         PIC S9(9) COMP. 

     01  XSELDI. 
         05  SEL-DI        OCCURS 3 TIMES PIC S9(9) COMP. 
     01  XSELDIVNAME. 
         05  SEL-DI-VNAME  OCCURS 3 TIMES PIC X(5). 
     01  XSELDV. 
         05  SEL-DV        OCCURS 3 TIMES PIC X(10). 
     01  XSELDHVNAME. 
         05  SEL-DH-VNAME  OCCURS 3 TIMES PIC X(5).  

Set the Maximum Number to DESCRIBE

Next, you set the maximum number of select-list items or place-holders that can be DESCRIBEd, as follows:

     MOVE 3 TO SQLDNUM IN SELDSC. 
     MOVE 3 TO SQLDNUM IN BNDDSC. 

Initialize the Descriptors

You must initialize several descriptor variables. Some require the library subroutine SQLADR.

In our example, you store the maximum lengths of name buffers in the SELDH-MAX-VNAMEL, BNDDH-MAX-VNAMEL, and BNDDI-MAX-VNAMEL tables, and use SQLADR to store the addresses of value and name buffers in the SELDV, SELDI, BNDDV, BNDDI, SELDH-VNAME, BNDDH-VNAME, and BNDDI-VNAME tables.

 PROCEDURE DIVISION. 
     ... 
     PERFORM INIT-SELDSC 
         VARYING J FROM 1 BY 1 UNTIL J > SQLDNUM IN SELDSC. 
     PERFORM INIT-BNDDSC 
         VARYING J FROM 1 BY 1 UNTIL J > SQLDNUM IN BNDDSC. 
     ... 
 INIT-SELDSC. 
     MOVE SPACES TO SEL-DV(J). 
     MOVE SPACES TO SEL-DH-VNAME(J). 
     MOVE 5 TO SELDH-MAX-VNAMEL(J). 
     CALL "SQLADR" USING SEL-DV(J), SELDV(J). 
     CALL "SQLADR" USING SEL-DH-VNAME(J), SELDH-VNAME(J). 
     CALL "SQLADR" USING SEL-DI(J), SELDI(J). 
     ... 
 INIT-BNDDSC. 
     MOVE SPACES TO BND-DV(J). 
     MOVE SPACES TO BND-DH-VNAME(J). 
     MOVE SPACES TO BND-DI-VNAME(J). 
     MOVE 5 TO BNDDH-MAX-VNAMEL(J). 
     MOVE 5 TO BNDDI-MAX-VNAMEL(J). 
     CALL "SQLADR" USING BND-DV(J), BNDDV(J). 
     CALL "SQLADR" USING BND-DH-VNAME(J), BNDDH-VNAME(J). 
     CALL "SQLADR" USING BND-DI(J), BNDDI(J). 
     CALL "SQLADR" USING BND-DI-VNAME(J), BNDDI-VNAME(J).
     ...

Figure 12-3 and Figure 12-4 represent the resulting descriptors.

Figure 12-3 Initialized Select Descriptor

Figure 12-4 Initialized Bind Descriptor

Store the Query Text in the Host String

Continuing our example, you prompt the user for a SQL statement, then store the input string in SELECT-STMT as follows:

     DISPLAY "Enter a SELECT statement: " WITH NO ADVANCING. 
     ACCEPT SELECT-STMT. 

We assume the user entered the following string:

     SELECT ENAME, EMPNO, COMM FROM EMP WHERE COMM < :BONUS

PREPARE the Query from the Host String

PREPARE parses the SQL statement and gives it a name. In our example, PREPARE parses the host string SELECT-STMT and gives it the name SQL-STMT, as follows:

     EXEC SQL PREPARE SQL-STMT FROM :SELECT-STMT END-EXEC. 

DECLARE a Cursor

DECLARE CURSOR defines a cursor by giving it a name and associating it with a specific SELECT statement.

To declare a cursor for static queries, you use the following syntax:

     EXEC SQL DECLARE cursor_name CURSOR FOR SELECT ... 

To declare a cursor for dynamic queries, the statement name given to the dynamic query by PREPARE is substituted for the static query. In our example, DECLARE CURSOR defines a cursor named EMP-CURSOR and associates it with SQL-STMT, as follows:

     EXEC SQL DECLARE EMP-CURSOR CURSOR FOR SQL-STMT END-EXEC.



Note: You must declare a cursor for all dynamic SQL statements, not just queries. With non-queries, OPENing the cursor executes the dynamic SQL statement.

DESCRIBE the Bind Variables

DESCRIBE BIND VARIABLES puts descriptions of bind variables into a bind descriptor. In our example, DESCRIBE readies BNDDSC as follows:

     EXEC SQL 
         DESCRIBE BIND VARIABLES FOR SQL-STMT 
         INTO BNDDSC 
     END-EXEC. 

Note that BNDDSC must not be prefixed with a colon.

The DESCRIBE BIND VARIABLES statement must follow the PREPARE statement but precede the OPEN statement.

Figure 12-5 shows the bind descriptor in our example after the DESCRIBE. Notice that DESCRIBE has set SQLDFND to the actual number of place-holders found in the processed SQL statement.

Figure 12-5 Bind Descriptor after the DESCRIBE

Reset Number of place-holders

Next, you must reset the maximum number of place-holders to the number actually found by DESCRIBE, as follows:

     IF SQLDFND IN BNDDSC < 0 
         DISPLAY "Too many bind variables" 
         GOTO ROLL-BACK 
     ELSE 
         MOVE SQLDFND IN BNDDSC TO SQLDNUM IN BNDDSC
     END-IF. 

Get Values for Bind Variables

Your program must get values for the bind variables in the SQL statement. How the program gets the values is up to you. For example, they can be hardcoded, read from a file, or entered interactively.

In our example, a value must be assigned to the bind variable that replaces the place-holder BONUS in the query WHERE clause. Prompt the user for the value, then process it, as follows:

 PROCEDURE DIVISION. 
     ... 
     PERFORM GET-INPUT-VAR 
         VARYING J FROM 1 BY 1 UNTIL J > SQLDNUM IN BNDDSC. 
     ... 
 GET-INPUT-VAR. 
     ... 
*    Replace the 0 DESCRIBEd into the datatype table 
*    with a 1 to avoid an "invalid datatype" Oracle error. 
     MOVE 1 TO BNDDVTYP(J). 
*    Get value of bind variable. 
     DISPLAY "Enter value of ", BND-DH-VNAME(J). 
     ACCEPT INPUT-STRING. 
     UNSTRING INPUT-STRING DELIMITED BY "  " 
         INTO BND-DV(J) COUNT IN BNDDVLN(J). 

Assuming that the user supplied a value of 625 for BONUS, the next table shows the resulting bind descriptor.

Figure 12-6 Bind Descriptor after Assigning Values

OPEN the Cursor

The OPEN statement for dynamic queries is similar to the one for static queries, except the cursor is associated with a bind descriptor. Values determined at run time and stored in buffers addressed by elements of the bind descriptor tables are used to evaluate the SQL statement. With queries, the values are also used to identify the active set.

In our example, OPEN associates EMP-CURSOR with BNDDSC as follows:

     EXEC SQL 
         OPEN EMP-CUR USING DESCRIPTOR BNDDSC 
     END-EXEC. 

Remember, BNDDSC must not be prefixed with a colon.

Then, OPEN executes the SQL statement. With queries, OPEN also identifies the active set and positions the cursor at the first row.

DESCRIBE the Select List

If the dynamic SQL statement is a query, the DESCRIBE SELECT LIST statement must follow the OPEN statement but precede the FETCH statement.

DESCRIBE SELECT LIST puts descriptions of select-list items into a select descriptor. In our example, DESCRIBE readies SELDSC as follows:

     EXEC SQL 
         DESCRIBE SELECT LIST FOR SQL-STMT INTO SELDSC 
     END-EXEC. 

Accessing the Oracle8 data dictionary, DESCRIBE sets the length and datatype of each select-list value.

Figure 12-7 shows the select descriptor in our example after the DESCRIBE. Notice that DESCRIBE has set SQLDFND to the actual number of items found in the query select list. If the SQL statement is not a query, SQLDFND is set to zero.

Also notice that the NUMBER lengths are not usable yet. For columns defined as NUMBER, you must use the library subroutine SQLPRC to extract precision and scale. See the section "Coercing Datatypes" on page 12-18.

Figure 12-7 Select Descriptor after the DESCRIBE

Reset Number of Select-List Items

Next, you must reset the maximum number of select-list items to the number actually found by DESCRIBE, as follows:

     MOVE SQLDFND IN SELDSC TO SQLDNUM IN SELDSC. 

Reset Length/Datatype of Each Select-List Item

In our example, before fetching the select-list values, you reset some elements in the length and datatype tables for display purposes.

 PROCEDURE DIVISION. 
     ... 
     PERFORM COERCE-COLUMN-TYPE 
         VARYING J FROM 1 BY 1 UNTIL J > SQLDNUM IN SELDSC. 
     ... 
 COERCE-COLUMN-TYPE. 
*    Clear NULL bit. 
     CALL "SQLNUL" USING SELDVTYP(J), SELDVTYP(J), NULL-STATUS. 

*    If datatype is DATE, lengthen to 9 characters. 
     IF SELDVTYP(J) = 12 
         MOVE 9 TO SELDVLN(J). 

*    If datatype is NUMBER, extract precision and scale. 
     MOVE 0 TO DISPLAY-LENGTH. 
     IF SELDVTYP(J) = 2 AND PRECISION = 0 
         MOVE 10 TO DISPLAY-LENGTH. 
     IF SELDVTYP(J) = 2 AND PRECISION > 0 
         ADD 2 TO PRECISION 
         MOVE PRECISION TO DISPLAY-LENGTH. 
     IF SELDVTYP(J) = 2 
         IF DISPLAY-LENGTH > MAX-LENGTH 
             DISPLAY "Column value too large for data buffer." 
             GO TO END-PROGRAM 
         ELSE 
             MOVE DISPLAY-LENGTH TO SELDVLN(J). 

*    Coerce datatypes to VARCHAR2. 
     MOVE 1 TO SELDVTYP(J). 

Figure 12-8 shows the resulting select descriptor. Notice that the NUMBER lengths are now usable and that all the datatypes are VARCHAR2. The lengths in SELDVLN(2) and SELDVLN(3) are 6 and 9 because we increased the DESCRIBEd lengths of 4 and 7 by 2 to allow for a possible sign and decimal point.

Figure 12-8 Select Descriptor before the FETCH

FETCH Rows from the Active Set

FETCH returns a row from the active set, stores select-list values in the data buffers, and advances the cursor to the next row in the active set. If there are no more rows, FETCH sets SQLCODE in the SQLCA, the SQLCODE variable, or the SQLSTATE variable to the "no data found" Oracle8 error code. In the following example, FETCH returns the values of columns ENAME, EMPNO, and COMM to SELDSC:

     EXEC SQL 
         FETCH EMP-CURSOR USING DESCRIPTOR SELDSC 
     END-EXEC. 

Figure 12-9 shows the select descriptor in our example after the FETCH. Notice that Oracle8 has stored the select-list and indicator values in the data buffers addressed by the elements of SELDV and SELDI.

For output buffers of datatype 1, Oracle8, using the lengths stored in SELDVLN, left-justifies CHAR or VARCHAR2 data, and right-justifies NUMBER data.

The value "MARTIN" was retrieved from a VARCHAR2(10) column in the EMP table. Using the length in SELDVLN(1), Oracle8 left-justifies the value in a 10-byte field, filling the buffer.

The value 7654 was retrieved from a NUMBER(4) column and coerced to "7654." However, the length in SELDVLN(2) was increased by two to allow for a possible sign and decimal point, so Oracle8 right-justifies the value in a 6-byte field.

The value 482.50 was retrieved from a NUMBER(7,2) column and coerced to "482.50." Again, the length in SELDVLN(3) was increased by two, so Oracle8 right-justifies the value in a 9-byte field.

Get and Process Select-List Values

After the FETCH, your program can process the select-list values returned by FETCH. In our example, values for columns ENAME, EMPNO, and COMM are processed.

CLOSE the Cursor

CLOSE disables the cursor. In our example, CLOSE disables EMP-CURSOR as follows:

     EXEC SQL CLOSE EMP-CURSOR END-EXEC.


Figure 12-9 Select Descriptor after the FETCH

Using Host Tables with Method 4

To use input or output host tables with Method 4, you must use the optional FOR clause to tell Oracle8 the size of your host table. For more information about the FOR clause, see Chapter 10, "Using Host Tables".

Set descriptor entries for the Jth select-list item or bind variable, but instead of addressing a single data buffer, SELDVLN(J) or BNDDVLN(J) addresses a table of data buffers. Then use a FOR clause in the EXECUTE or FETCH statement, as appropriate, to tell Oracle8 the number of table elements you want to process.

This procedure is necessary, because Oracle8 has no other way of knowing the size of your host table.

In the example below, two input host tables are used to insert 8 pairs of values of EMPNO and DEPTNO into the table EMP. Note that EXECUTE can be used for non-queries with Method 4.

 IDENTIFICATION DIVISION. 
 PROGRAM-ID. DYN4INS. 
 ENVIRONMENT DIVISION. 
 DATA DIVISION. 
 WORKING-STORAGE SECTION. 
 01  BNDDSC. 
     02  SQLDNUM              PIC S9(9) COMP VALUE 2. 
     02  SQLDFND              PIC S9(9) COMP. 
     02  BNDDVAR              OCCURS 2 TIMES. 
         03 BNDDV             PIC S9(9) COMP. 
         03 BNDDFMT           PIC S9(9) COMP. 
         03 BNDDVLN           PIC S9(9) COMP. 
         03 BNDDFMTL          PIC S9(4) COMP. 
         03 BNDDVTYP          PIC S9(4) COMP. 
         03 BNDDI             PIC S9(9) COMP. 
         03 BNDDH-VNAME       PIC S9(9) COMP. 
         03 BNDDH-MAX-VNAMEL  PIC S9(4) COMP. 
         03 BNDDH-CUR-VNAMEL  PIC S9(4) COMP. 
         03 BNDDI-VNAME       PIC S9(9) COMP. 
         03 BNDDI-MAX-VNAMEL  PIC S9(4) COMP. 
         03 BNDDI-CUR-VNAMEL  PIC S9(4) COMP. 
         03 BNDDFCLP          PIC S9(9) COMP. 
         03 BNDDFCRCP         PIC S9(9) COMP. 
 01  XBNDDI. 
     03  BND-DI               OCCURS 2 TIMES PIC S9(4) COMP. 
 01  XBNDDIVNAME. 
     03  BND-DI-VNAME         OCCURS 2 TIMES PIC X(80). 
 01  XBNDDV. 
*    Since you know what the SQL statement will be, you can set 
*    up a two-dimensional table with a maximum of 2 columns and 
*    8 rows.  Each element can be up to 10 characters long.  (You 
*    can alter these values according to your needs.) 
     03  BND-COLUMN           OCCURS 2 TIMES. 
         05  BND-ELEMENT      OCCURS 8 TIMES PIC X(10). 
 01  XBNDDHVNAME. 
     03  BND-DH-VNAME         OCCURS 2 TIMES PIC X(80).  
 01  COLUMN-INDEX             PIC 999. 
 01  ROW-INDEX                PIC 999. 
 01  DUMMY-INTEGER            PIC 9999.
     EXEC SQL BEGIN DECLARE SECTION END-EXEC. 
         01  USERNAME         PIC X(20). 
         01  PASSWD           PIC X(20). 
         01  DYN-STATEMENT    PIC X(80). 
         01  NUMBER-OF-ROWS   PIC S9(4) COMP. 
     EXEC SQL END DECLARE SECTION END-EXEC. 

     EXEC SQL INCLUDE SQLCA END-EXEC. 

 PROCEDURE DIVISION. 
 START-MAIN. 

     EXEC SQL WHENEVER SQLERROR GOTO SQL-ERROR END-EXEC. 

     MOVE "SCOTT" TO USERNAME. 
     MOVE "TIGER" TO PASSWD. 
     EXEC SQL 
         CONNECT :USERNAME IDENTIFIED BY :PASSWD 
     END-EXEC. 
     DISPLAY "Connected to Oracle". 

*    Initialize bind and select descriptors. 
     PERFORM INIT-BNDDSC THRU INIT-BNDDSC-EXIT 
         VARYING COLUMN-INDEX FROM 1 BY 1 
         UNTIL COLUMN-INDEX > 2. 

*    Set up the SQL statement. 
     MOVE SPACES TO DYN-STATEMENT. 
     MOVE "INSERT INTO EMP(EMPNO, DEPTNO) VALUES(:EMPNO,:DEPTNO)" 
         TO DYN-STATEMENT.
     DISPLAY DYN-STATEMENT.

*    Prepare the SQL statement. 
     EXEC SQL 
         PREPARE S1 FROM :DYN-STATEMENT 
     END-EXEC. 

*    Describe the bind variables. 
     EXEC SQL 
         DESCRIBE BIND VARIABLES FOR S1 INTO BNDDSC 
     END-EXEC. 

     PERFORM Z-BIND-TYPE THRU Z-BIND-TYPE-EXIT 
         VARYING COLUMN-INDEX FROM 1 BY 1 
         UNTIL COLUMN-INDEX > 2. 

     IF SQLDFND IN BNDDSC < 0 
         DISPLAY "TOO MANY BIND VARIABLES." 
         GO TO SQL-ERROR 
     ELSE 
         DISPLAY "BIND VARS = " WITH NO ADVANCING 
         MOVE SQLDFND IN BNDDSC TO DUMMY-INTEGER 
         DISPLAY DUMMY-INTEGER 
         MOVE SQLDFND IN BNDDSC TO SQLDNUM IN BNDDSC. 

         MOVE 8 TO NUMBER-OF-ROWS. 
         PERFORM GET-ALL-VALUES THRU GET-ALL-VALUES-EXIT 
             VARYING ROW-INDEX FROM 1 BY 1 
             UNTIL ROW-INDEX > NUMBER-OF-ROWS. 

*    Execute the SQL statement. 
     EXEC SQL FOR :NUMBER-OF-ROWS 
         EXECUTE S1 USING DESCRIPTOR BNDDSC 
     END-EXEC. 

     DISPLAY "INSERTED " WITH NO ADVANCING. 
     MOVE SQLERRD(3) TO DUMMY-INTEGER. 
     DISPLAY DUMMY-INTEGER WITH NO ADVANCING. 
     DISPLAY " ROWS.". 
     GO TO END-SQL. 

 SQL-ERROR. 
*    Display any SQL error message and code. 
     DISPLAY SQLERRMC. 
     EXEC SQL ROLLBACK WORK RELEASE END-EXEC. 
     STOP RUN. 

 END-SQL. 
     EXEC SQL WHENEVER SQLERROR CONTINUE END-EXEC. 
     EXEC SQL COMMIT WORK RELEASE END-EXEC. 
     STOP RUN. 

 INIT-BNDDSC. 
*    Start of COBOL PERFORM procedures, initialize the bind 
*    descriptor. 
     MOVE 80 TO BNDDH-MAX-VNAMEL(COLUMN-INDEX). 
     CALL "SQLADR" USING 
         BND-DH-VNAME(COLUMN-INDEX) 
         BNDDH-VNAME(COLUMN-INDEX). 
     MOVE 80 TO BNDDI-MAX-VNAMEL(COLUMN-INDEX). 
     CALL "SQLADR" USING 
         BND-DI-VNAME(COLUMN-INDEX) 
         BNDDI-VNAME (COLUMN-INDEX). 
     MOVE 10 TO BNDDVLN(COLUMN-INDEX). 
     CALL "SQLADR" USING 
         BND-ELEMENT(COLUMN-INDEX,1) 
         BNDDV(COLUMN-INDEX). 
     MOVE ZERO TO BNDDI(COLUMN-INDEX). 
     CALL "SQLADR" USING 
         BND-DI(COLUMN-INDEX) 
         BNDDI(COLUMN-INDEX). 
     MOVE ZERO TO BNDDFMT(COLUMN-INDEX). 
     MOVE ZERO TO BNDDFMTL(COLUMN-INDEX). 
     MOVE ZERO TO BNDDFCLP(COLUMN-INDEX). 
     MOVE ZERO TO BNDDFCRCP(COLUMN-INDEX). 
 INIT-BNDDSC-EXIT. 
     EXIT.

 Z-BIND-TYPE. 
*    Replace the 0s DESCRIBEd into the datatype table with 1s to 
*    avoid an "invalid datatype" Oracle error. 
     MOVE 1 TO BNDDVTYP(COLUMN-INDEX). 

 Z-BIND-TYPE-EXIT. 
     EXIT. 

 GET-ALL-VALUES. 
*    Get the bind variables for each row. 
     DISPLAY "ENTER VALUES FOR ROW NUMBER ",ROW-INDEX. 
     PERFORM GET-BIND-VARS 
         VARYING COLUMN-INDEX FROM 1 BY 1 
         UNTIL COLUMN-INDEX > SQLDFND IN BNDDSC. 
 GET-ALL-VALUES-EXIT. 
     EXIT. 

 GET-BIND-VARS. 
*    Get the value of each bind variable. 
     DISPLAY "    ENTER VALUE FOR ",BND-DH-VNAME(COLUMN-INDEX) 
         WITH NO ADVANCING. 
     ACCEPT BND-ELEMENT(COLUMN-INDEX,ROW-INDEX). 
 GET-BIND-VARS-EXIT. 
     EXIT.  

Sample Program 10: Dynamic SQL Method 4

This program shows the basic steps required to use dynamic SQL Method 4. After logging on to Oracle8, the program prompts the user for a SQL statement, PREPAREs the statement, DECLAREs a cursor, checks for any bind variables using DESCRIBE BIND, OPENs the cursor, and DESCRIBEs any select-list variables. If the input SQL statement is a query, the program FETCHes each row of data, then CLOSEs the cursor.

 IDENTIFICATION DIVISION.
 PROGRAM-ID.  DYNSQL4.
 ENVIRONMENT DIVISION.
 DATA DIVISION.
 WORKING-STORAGE SECTION.
 01  BNDDSC.             
     02  SQLDNUM               PIC S9(9) COMP VALUE 20.
     02  SQLDFND               PIC S9(9) COMP.
     02  BNDDVAR               OCCURS 20 TIMES.
         03  BNDDV             PIC S9(9) COMP.
         03  BNDDFMT           PIC S9(9) COMP.
         03  BNDDVLN           PIC S9(9) COMP.
         03  BNDDFMTL          PIC S9(4) COMP.
         03  BNDDVTYP          PIC S9(4) COMP.
         03  BNDDI             PIC S9(9) COMP.
         03  BNDDH-VNAME       PIC S9(9) COMP.
         03  BNDDH-MAX-VNAMEL  PIC S9(4) COMP.
         03  BNDDH-CUR-VNAMEL  PIC S9(4) COMP.
         03  BNDDI-VNAME       PIC S9(9) COMP.
         03  BNDDI-MAX-VNAMEL  PIC S9(4) COMP.
         03  BNDDI-CUR-VNAMEL  PIC S9(4) COMP.
         03  BNDDFCLP          PIC S9(9) COMP.
         03  BNDDFCRCP         PIC S9(9) COMP.
 01  XBNDDI. 
         03  BND-DI            OCCURS 20 TIMES PIC S9(4) COMP.
 01  XBNDDIVNAME. 
         03  BND-DI-VNAME      OCCURS 20 TIMES PIC X(80). 
 01  XBNDDV. 
         03  BND-DV            OCCURS 20 TIMES PIC X(80). 
 01  XBNDDHVNAME. 
         03  BND-DH-VNAME      OCCURS 20 TIMES PIC X(80). 
 01  SELDSC. 
     02  SQLDNUM               PIC S9(9) COMP VALUE 20. 
     02  SQLDFND               PIC S9(9) COMP. 
     02  SELDVAR               OCCURS 20 TIMES. 
         03  SELDV             PIC S9(9) COMP. 
         03  SELDFMT           PIC S9(9) COMP. 
         03  SELDVLN           PIC S9(9) COMP. 
         03  SELDFMTL          PIC S9(4) COMP. 
         03  SELDVTYP          PIC S9(4) COMP. 
         03  SELDI             PIC S9(9) COMP. 
         03  SELDH-VNAME       PIC S9(9) COMP. 
         03  SELDH-MAX-VNAMEL  PIC S9(4) COMP. 
         03  SELDH-CUR-VNAMEL  PIC S9(4) COMP. 
         03  SELDI-VNAME       PIC S9(9) COMP. 
         03  SELDI-MAX-VNAMEL  PIC S9(4) COMP. 
         03  SELDI-CUR-VNAMEL  PIC S9(4) COMP. 
         03  SELDFCLP          PIC S9(9) COMP. 
         03  SELDFCRCP         PIC S9(9) COMP. 
 01  XSELDI. 
         03  SEL-DI            OCCURS 20 TIMES PIC S9(4) COMP. 
 01  XSELDIVNAME. 
         03  SEL-DI-VNAME      OCCURS 20 TIMES PIC X(80). 
 01  XSELDV. 
         03  SEL-DV            OCCURS 20 TIMES PIC X(80). 
 01  XSELDHVNAME. 
         03  SEL-DH-VNAME      OCCURS 20 TIMES PIC X(80). 
 01  TABLE-INDEX               PIC 9(3). 
 01  VAR-COUNT                 PIC 9(2). 
 01  ROW-COUNT                 PIC 9(4).  
 01  NO-MORE-DATA              PIC X(1) VALUE "N".    
 01  NULLS-ALLOWED             PIC S9(9) COMP.          
 01  PRECISION                 PIC S9(9) COMP.          
 01  SCALE                     PIC S9(9) COMP.          
 01  DISPLAY-LENGTH            PIC S9(9) COMP.          
 01  MAX-LENGTH                PIC S9(9) COMP VALUE 80. 
 01  COLUMN-NAME               PIC X(30).

     EXEC SQL BEGIN DECLARE SECTION END-EXEC.  
         01  USERNAME          PIC X(20). 
         01  PASSWD            PIC X(20). 
         01  DYN-STATEMENT     PIC X(80). 
     EXEC SQL END DECLARE SECTION END-EXEC. 
     EXEC SQL INCLUDE SQLCA END-EXEC. 
 PROCEDURE DIVISION. 
 START-MAIN. 
     EXEC SQL 
         WHENEVER SQLERROR GOTO SQL-ERROR 
     END-EXEC. 
     DISPLAY "USERNAME: " WITH NO ADVANCING. 
     ACCEPT USERNAME. 
     DISPLAY "PASSWORD: " WITH NO ADVANCING. 
     ACCEPT PASSWD. 
     EXEC SQL 
         CONNECT :USERNAME IDENTIFIED BY :PASSWD  
     END-EXEC. 
     DISPLAY "CONNECTED TO ORACLE AS USER: ", USERNAME. 
         
*    INITIALIZE THE BIND AND SELECT DESCRIPTORS. 
     PERFORM INIT-BNDDSC 
         VARYING TABLE-INDEX FROM 1 BY 1  
         UNTIL TABLE-INDEX > 20. 
     PERFORM INIT-SELDSC 
         VARYING TABLE-INDEX FROM 1 BY 1  
         UNTIL TABLE-INDEX > 20. 
 
*    GET A SQL STATEMENT FROM THE OPERATOR. 
     DISPLAY "ENTER SQL STATEMENT WITHOUT TERMINATOR:". 
     DISPLAY ">" WITH NO ADVANCING. 
     ACCEPT DYN-STATEMENT. 
     DISPLAY " ". 
         
*    PREPARE THE SQL STATEMENT AND DECLARE A CURSOR. 
     EXEC SQL
         PREPARE S1 FROM :DYN-STATEMENT  
     END-EXEC. 
     EXEC SQL  
         DECLARE C1 CURSOR FOR S1        
     END-EXEC. 
 
*    DESCRIBE ANY BIND VARIABLES. 
     EXEC SQL  
         DESCRIBE BIND VARIABLES FOR S1 INTO BNDDSC 
     END-EXEC. 
     IF SQLDFND IN BNDDSC < 0 
         DISPLAY "TOO MANY BIND VARIABLES." 
         GO TO END-SQL 
     ELSE 
         DISPLAY "NUMBER OF BIND VARIABLES: " WITH NO ADVANCING 
         MOVE SQLDFND IN BNDDSC TO VAR-COUNT 
         DISPLAY VAR-COUNT 
         MOVE SQLDFND IN BNDDSC TO SQLDNUM IN BNDDSC 
     END-IF. 
*    REPLACE THE 0S DESCRIBED INTO THE DATATYPE FIELDS OF THE BIND
*    DESCRIPTOR WITH 1S TO AVOID AN ORACLE "INVALID DATATYPE" 
*    ERROR. 
     MOVE 1 TO TABLE-INDEX. 
 FIX-BIND-TYPE. 
     MOVE 1 TO BNDDVTYP(TABLE-INDEX).
     ADD 1 TO TABLE-INDEX.
     IF TABLE-INDEX <= 20 
         GO TO FIX-BIND-TYPE. 
         
*    LET THE USER FILL IN THE BIND VARIABLES. 
     IF SQLDFND IN BNDDSC = 0 
         GO TO DESCRIBE-ITEMS. 
     MOVE 1 TO TABLE-INDEX. 
 GET-BIND-VAR. 
     DISPLAY "ENTER VALUE FOR ", BND-DH-VNAME(TABLE-INDEX). 
     ACCEPT BND-DV(TABLE-INDEX). 
     ADD 1 TO TABLE-INDEX.
     IF TABLE-INDEX <= SQLDFND IN BNDDSC 
         GO TO GET-BIND-VAR. 
 
 DESCRIBE-ITEMS. 
*    OPEN THE CURSOR AND DESCRIBE THE SELECT-LIST ITEMS. 
     EXEC SQL
         OPEN C1 USING DESCRIPTOR BNDDSC           
     END-EXEC. 
     EXEC SQL
         DESCRIBE SELECT LIST FOR S1 INTO SELDSC   
     END-EXEC. 

     IF SQLDFND IN SELDSC < 0 
         DISPLAY "TOO MANY SELECT-LIST ITEMS." 
         GO TO END-SQL 
     ELSE 
         DISPLAY "NUMBER OF SELECT-LIST ITEMS: " 
             WITH NO ADVANCING 
         MOVE SQLDFND IN SELDSC TO VAR-COUNT 
         DISPLAY VAR-COUNT 
         DISPLAY " " 
         MOVE SQLDFND IN SELDSC TO SQLDNUM IN SELDSC 
     END-IF. 
 
*    COERCE THE DATATYPE OF ALL SELECT-LIST ITEMS TO VARCHAR2. 
     IF SQLDNUM IN SELDSC > 0 
         PERFORM COERCE-COLUMN-TYPE 
         VARYING TABLE-INDEX FROM 1 BY 1 
             UNTIL TABLE-INDEX > SQLDNUM IN SELDSC 
         DISPLAY " ". 
 
*    FETCH EACH ROW AND PRINT EACH SELECT-LIST VALUE. 
     IF SQLDNUM IN SELDSC > 0 
         PERFORM FETCH-ROWS UNTIL NO-MORE-DATA = "Y". 
     DISPLAY " " 
     DISPLAY "NUMBER OF ROWS PROCESSED: " WITH NO ADVANCING. 
     MOVE SQLERRD(3) TO ROW-COUNT. 
     DISPLAY ROW-COUNT. 
 
*    CLEAN UP AND TERMINATE. 
     EXEC SQL
         CLOSE C1 
     END-EXEC. 
     EXEC SQL
         COMMIT WORK RELEASE
     END-EXEC. 
     DISPLAY " ". 
     DISPLAY "HAVE A GOOD DAY!". 
     DISPLAY " ". 
     STOP RUN. 

 SQL-ERROR. 
*    DISPLAY ORACLE ERROR MESSAGE AND CODE. 
     DISPLAY " ". 
     DISPLAY SQLERRMC. 

 END-SQL. 
     EXEC SQL 
         WHENEVER SQLERROR CONTINUE 
     END-EXEC. 
     EXEC SQL 
         ROLLBACK WORK RELEASE 
     END-EXEC. 
     STOP RUN. 
 
*    PERFORMED SUBROUTINES BEGIN HERE: 
 
 INIT-BNDDSC. 
*    INITIALIZE THE BIND DESCRIPTOR. 
     MOVE SPACES TO BND-DH-VNAME(TABLE-INDEX). 
     MOVE 80 TO BNDDH-MAX-VNAMEL(TABLE-INDEX). 
     CALL "SQLADR" USING  
         BND-DH-VNAME(TABLE-INDEX)  
         BNDDH-VNAME(TABLE-INDEX).  
     MOVE SPACES TO BND-DI-VNAME(TABLE-INDEX). 
     MOVE 80 TO BNDDI-MAX-VNAMEL(TABLE-INDEX). 
     CALL "SQLADR" USING  
         BND-DI-VNAME(TABLE-INDEX)  
         BNDDI-VNAME (TABLE-INDEX). 
     MOVE SPACES TO BND-DV(TABLE-INDEX). 
     MOVE 80 TO BNDDVLN(TABLE-INDEX). 
     CALL "SQLADR" USING  
         BND-DV(TABLE-INDEX)  
         BNDDV(TABLE-INDEX). 
     MOVE ZERO TO BND-DI(TABLE-INDEX). 
     CALL "SQLADR" USING  
         BND-DI(TABLE-INDEX)  
         BNDDI(TABLE-INDEX). 
     MOVE ZERO TO BNDDFMT(TABLE-INDEX). 
     MOVE ZERO TO BNDDFMTL(TABLE-INDEX). 
     MOVE ZERO TO BNDDFCLP(TABLE-INDEX). 
     MOVE ZERO TO BNDDFCRCP(TABLE-INDEX). 
     EXIT. 
 
 INIT-SELDSC. 
*    INITIALIZE THE SELECT DESCRIPTOR. 
     MOVE SPACES TO SEL-DH-VNAME(TABLE-INDEX). 
     MOVE 80 TO SELDH-MAX-VNAMEL(TABLE-INDEX). 
     CALL "SQLADR" USING  
         SEL-DH-VNAME(TABLE-INDEX)  
         SELDH-VNAME(TABLE-INDEX).  
     MOVE SPACES TO SEL-DI-VNAME(TABLE-INDEX). 
     MOVE 80 TO SELDI-MAX-VNAMEL(TABLE-INDEX). 
     CALL "SQLADR" USING  
         SEL-DI-VNAME(TABLE-INDEX)  
         SELDI-VNAME (TABLE-INDEX). 
     MOVE SPACES TO SEL-DV(TABLE-INDEX). 
     MOVE 80 TO SELDVLN(TABLE-INDEX). 
     CALL "SQLADR" USING  
         SEL-DV(TABLE-INDEX)  
         SELDV(TABLE-INDEX). 
     MOVE ZERO TO SEL-DI(TABLE-INDEX). 
     CALL "SQLADR" USING  
         SEL-DI(TABLE-INDEX)  
         SELDI(TABLE-INDEX). 
     MOVE ZERO TO SELDFMT(TABLE-INDEX). 
     MOVE ZERO TO SELDFMTL(TABLE-INDEX). 
     MOVE ZERO TO SELDFCLP(TABLE-INDEX). 
     MOVE ZERO TO SELDFCRCP(TABLE-INDEX). 
     EXIT. 
         
 COERCE-COLUMN-TYPE. 
*    COERCE SELECT-LIST DATATYPES TO VARCHAR2. 
     CALL "SQLNUL" USING 
         SELDVTYP(TABLE-INDEX) 
         SELDVTYP(TABLE-INDEX) 
         NULLS-ALLOWED. 
         
*    IF DATATYPE IS DATE, LENGTHEN TO 9 CHARACTERS. 
     IF SELDVTYP(TABLE-INDEX) = 12 
        MOVE 9 TO SELDVLN(TABLE-INDEX). 
 
*    IF DATATYPE IS NUMBER, SET LENGTH TO PRECISION. 
     IF SELDVTYP(TABLE-INDEX) = 2 
         CALL "SQLPRC" USING SELDVLN(TABLE-INDEX) PRECISION SCALE. 
     MOVE 0 TO DISPLAY-LENGTH. 
     IF SELDVTYP(TABLE-INDEX) = 2 AND PRECISION = 0 
         MOVE 40 TO DISPLAY-LENGTH. 
     IF SELDVTYP(TABLE-INDEX) = 2 AND PRECISION > 0 
         ADD 2 TO PRECISION 
         MOVE PRECISION TO DISPLAY-LENGTH. 
     IF SELDVTYP(TABLE-INDEX) = 2 
         IF DISPLAY-LENGTH > MAX-LENGTH 
             DISPLAY "COLUMN VALUE TOO LARGE FOR DATA BUFFER." 
             GO TO END-SQL 
         ELSE 
             MOVE DISPLAY-LENGTH TO SELDVLN(TABLE-INDEX). 
         
*    COERCE DATATYPES TO VARCHAR2. 
     MOVE 1 TO SELDVTYP(TABLE-INDEX). 
         
*    DISPLAY COLUMN HEADING. 
     MOVE SEL-DH-VNAME(TABLE-INDEX) TO COLUMN-NAME. 
     DISPLAY COLUMN-NAME(1:SELDVLN(TABLE-INDEX)), " " 
         WITH NO ADVANCING. 
     EXIT. 
 
 FETCH-ROWS. 
*    FETCH A ROW AND PRINT THE SELECT-LIST VALUE. 
     EXEC SQL  
         FETCH C1 USING DESCRIPTOR SELDSC  
     END-EXEC. 
     IF SQLCODE NOT = 0 
         MOVE "Y" TO NO-MORE-DATA. 
     IF SQLCODE = 0 
         PERFORM PRINT-COLUMN-VALUES 
             VARYING TABLE-INDEX FROM 1 BY 1 
             UNTIL TABLE-INDEX > SQLDNUM IN SELDSC 
         DISPLAY " ". 
 
 PRINT-COLUMN-VALUES. 
*    PRINT A SELECT-LIST VALUE. 
     DISPLAY SEL-DV(TABLE-INDEX)(1:SELDVLN(TABLE-INDEX)), " " 
         WITH NO ADVANCING. 




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