Programmer's Guide to the Oracle Precompilers, 1.8 Go To Documentation Library
Home
Go To Product List
Book List
Go To Table Of Contents
Contents
Go To Index
Index

Master Index

Feedback

Go to previous file in sequence Go to next file in sequence

Using Embedded PL/SQL


This chapter shows you how to improve performance by embedding PL/SQL transaction processing blocks in your program. After pointing out the advantages of PL/SQL, this chapter discusses the following subjects:

Advantages of PL/SQL

This section looks at some of the features and benefits offered by PL/SQL, such as

For more information about PL/SQL, see the PL/SQL User's Guide and Reference.

Better Performance

PL/SQL can help you reduce overhead, improve performance, and increase productivity. For example, without PL/SQL, Oracle must process SQL statements one at a time. Each SQL statement results in another call to the Server and higher overhead. However, with PL/SQL, you can send an entire block of SQL statements to the Server. This minimizes communication between your application and Oracle.

Integration with Oracle

PL/SQL is tightly integrated with the Oracle Server. For example, most PL/SQL datatypes are native to the Oracle data dictionary. Furthermore, you can use the %TYPE attribute to base variable declarations on column definitions stored in the data dictionary, as the following example shows:

job_title  emp.job%TYPE;

That way, you need not know the exact datatype of the column. Furthermore, if a column definition changes, the variable declaration changes accordingly and automatically. This provides data independence, reduces maintenance costs, and allows programs to adapt as the database changes.

Cursor FOR Loops

With PL/SQL, you need not use the DECLARE, OPEN, FETCH, and CLOSE statements to define and manipulate a cursor. Instead, you can use a cursor FOR loop, which implicitly declares its loop index as a record, opens the cursor associated with a given query, repeatedly fetches data from the cursor into the record, then closes the cursor. An example follows:

DECLARE
    ...
BEGIN
    FOR emprec IN (SELECT empno, sal, comm FROM emp) LOOP
        IF emprec.comm / emprec.sal > 0.25 THEN ...
        ...
    END LOOP;
END;

Notice that you use dot notation to reference fields in the record.

Subprograms

PL/SQL has two types of subprograms called procedures and functions, which aid application development by letting you isolate operations. Generally, you use a procedure to perform an action and a function to compute a value.

Procedures and functions provide extensibility. That is, they let you tailor the PL/SQL language to suit your needs. For example, if you need a procedure that creates a new department, just write your own as follows:

PROCEDURE create_dept
    (new_dname  IN CHAR(14),
     new_loc    IN CHAR(13),
     new_deptno OUT NUMBER(2)) IS
BEGIN
    SELECT deptno_seq.NEXTVAL INTO new_deptno FROM dual;
    INSERT INTO dept VALUES (new_deptno, new_dname, new_loc);
END create_dept;

When called, this procedure accepts a new department name and location, selects the next value in a department-number database sequence, inserts the new number, name, and location into the dept table, then returns the new number to the caller.

You can store subprograms in the database (using CREATE FUNCTION and CREATE PROCEDURE) that can be called from multiple applications without needing to be recompiled each time.

Parameter Modes

You use parameter modes to define the behavior of formal parameters. There are three parameter modes: IN (the default), OUT, and IN OUT. An IN parameter lets you pass values to the subprogram being called. An OUT parameter lets you return values to the caller of a subprogram. An IN OUT parameter lets you pass initial values to the subprogram being called and return updated values to the caller.

The datatype of each actual parameter must be convertible to the datatype of its corresponding formal parameter. Table 3 - 6 [*] shows the legal conversions between datatypes.

Packages

PL/SQL lets you bundle logically related types, program objects, and subprograms into a package. Packages can be compiled and stored in an Oracle database, where their contents can be shared by multiple applications.

Packages usually have two parts: a specification and a body. The specification is the interface to your applications; it declares the types, constants, variables, exceptions, cursors, and subprograms available for use. The body defines cursors and subprograms and so implements the specification. In the following example, you "package" two employment procedures:

PACKAGE emp_actions IS  -- package specification
    PROCEDURE hire_employee (empno NUMBER, ename CHAR, ...);
    PROCEDURE fire_employee (emp_id NUMBER);
END emp_actions;
PACKAGE BODY emp_actions IS  -- package body
    PROCEDURE hire_employee (empno NUMBER, ename CHAR, ...) IS
    BEGIN
        INSERT INTO emp VALUES (empno, ename, ...);
    END hire_employee;
    PROCEDURE fire_employee (emp_id NUMBER) IS
    BEGIN
        DELETE FROM emp WHERE empno = emp_id;
    END fire_employee;
END emp_actions;

Only the declarations in the package specification are visible and accessible to applications. Implementation details in the package body are hidden and inaccessible.

PL/SQL Tables

PL/SQL provides a composite datatype named TABLE. Objects of type TABLE are called PL/SQL tables, which are modelled as (but not the same as) database tables. PL/SQL tables have only one column and use a primary key to give you array-like access to rows. The column can belong to any scalar type (such as CHAR, DATE, or NUMBER), but the primary key must belong to type BINARY_INTEGER.

You can declare PL/SQL table types in the declarative part of any block, procedure, function, or package. In the following example, you declare a TABLE type called NumTabTyp:

DECLARE
    TYPE NumTabTyp IS TABLE OF NUMBER
        INDEX BY BINARY_INTEGER;
    ...
BEGIN
    ...
END;

Once you define type NumTabTyp, you can declare PL/SQL tables of that type, as the next example shows:

num_tab  NumTabTyp;

The identifier num_tab represents an entire PL/SQL table.

You reference rows in a PL/SQL table using array-like syntax to specify the primary key value. For example, you reference the ninth row in the PL/SQL table named num_tab as follows:

num_tab(9) ...

User-defined Records

You can use the %ROWTYPE attribute to declare a record that represents a row in a database table or a row fetched by a cursor. However, you cannot specify the datatypes of fields in the record or define fields of your own. The composite datatype RECORD lifts those restrictions.

Objects of type RECORD are called records. Unlike PL/SQL tables, records have uniquely named fields, which can belong to different datatypes. For example, suppose you have different kinds of data about an employee such as name, salary, hire date, and so on. This data is dissimilar in type but logically related. A record that contains such fields as the name, salary, and hire date of an employee would let you treat the data as a logical unit.

You can declare record types and objects in the declarative part of any block, procedure, function, or package. In the following example, you declare a RECORD type called DeptRecTyp:

DECLARE
    TYPE DeptRecTyp IS RECORD
        (deptno  NUMBER(4) NOT NULL := 10,  -- must initialize
         dname   CHAR(9),
         loc     CHAR(14));

Notice that the field declarations are like variable declarations. Each field has a unique name and specific datatype. You can add the NOT NULL option to any field declaration and so prevent the assigning of nulls to that field. However, you must initialize NOT NULL fields.

Once you define type DeptRecTyp, you can declare records of that type, as the next example shows:

dept_rec  DeptRecTyp;

The identifier dept_rec represents an entire record.

You use dot notation to reference individual fields in a record. For example, you reference the dname field in the dept_rec record as follows:

dept_rec.dname ...

Embedding PL/SQL Blocks

The Oracle Precompilers treat a PL/SQL block like a single embedded SQL statement. So, you can place a PL/SQL block anywhere in a host program that you can place a SQL statement.

To embed a PL/SQL block in your host program, simply bracket the PL/SQL block with the keywords EXEC SQL EXECUTE and END-EXEC as follows:

EXEC SQL EXECUTE
    DECLARE
        ...
    BEGIN
        ...
    END;
END-EXEC;

The keyword END-EXEC must be followed by the statement terminator for your host language.

When your program embeds PL/SQL blocks, you must specify the precompiler option SQLCHECK=SEMANTICS because PL/SQL must be parsed by Oracle. To connect to Oracle, you must also specify the option USERID. For more information, see "Using the Precompiler Options" [*].

Using Host Variables

Host variables are the key to communication between a host language and a PL/SQL block. Host variables can be shared with PL/SQL, meaning that PL/SQL can set and reference host variables.

For example, you can prompt a user for information and use host variables to pass that information to a PL/SQL block. Then, PL/SQL can access the database and use host variables to pass the results back to your host program.

Inside a PL/SQL block, host variables are treated as global to the entire block and can be used anywhere a PL/SQL variable is allowed. However, character host variables cannot exceed 255 characters in length. Like host variables in a SQL statement, host variables in a PL/SQL block must be prefixed with a colon. The colon sets host variables apart from PL/SQL variables and database objects.

An Example

The following example illustrates the use of host variables with PL/SQL. The program prompts the user for an employee number, then displays the job title, hire date, and salary of that employee.

EXEC SQL BEGIN DECLARE SECTION;
    username    CHARACTER(20);
    password    CHARACTER(20);
    emp_number  INTEGER;
    job_title   CHARACTER(20);
    hire_date   CHARACTER(9);
    salary      REAL;
EXEC SQL END DECLARE SECTION;
EXEC SQL INCLUDE SQLCA;
display 'Username? ';
read username;
display 'Password? ';
read password;
EXEC SQL WHENEVER SQLERROR DO sql_error;
EXEC SQL CONNECT :username IDENTIFIED BY :password;
display 'Connected to Oracle';
LOOP
    display 'Employee Number (0 to end)? ';
    read emp_number;
    IF emp_number = 0 THEN
        EXEC SQL COMMIT WORK RELEASE;
        display 'Exiting program';
        exit program;
    ENDIF;
   ---------------- begin PL/SQL block -----------------
    EXEC SQL EXECUTE
        BEGIN
            SELECT job, hiredate, sal
                INTO :job_title, :hire_date, :salary
                FROM emp
                WHERE empno = :emp_number;
        END;
    END-EXEC;
    ---------------- end PL/SQL block -----------------
    display 'Number  Job Title  Hire Date  Salary';
    display '------------------------------------';
    display emp_number, job_title, hire_date, salary;
ENDLOOP;
...
ROUTINE sql_error
BEGIN
    EXEC SQL WHENEVER SQLERROR CONTINUE;
    EXEC SQL ROLLBACK WORK RELEASE;
    display 'Processing error';
    exit program with an error;
END sql_error;

Notice that the host variable emp_number is set before the PL/SQL block is entered, and the host variables job_title, hire_date, and salary are set inside the block.

A More Complex Example

In the example below, you prompt the user for a bank account number, transaction type, and transaction amount, then debit or credit the account. If the account does not exist, you raise an exception. When the transaction is complete, you display its status.

EXEC SQL BEGIN DECLARE SECTION;
    username    CHARACTER(20);
    password    CHARACTER(20);
    acct_num    INTEGER;
    trans_type  CHARACTER(1);
    trans_amt   REAL;
    status      CHARACTER(80);
EXEC SQL END DECLARE SECTION;
EXEC SQL INCLUDE SQLCA;
display 'Username? ';
read username;
display 'Password? ';
read password;
EXEC SQL WHENEVER SQLERROR DO sql_error;
EXEC SQL CONNECT :username IDENTIFIED BY :password;
display 'Connected to Oracle';
LOOP
    display 'Account Number (0 to end)? ';
    read acct_num;
    IF acct_num = 0 THEN
        EXEC SQL COMMIT WORK RELEASE;
        display 'Exiting program';
        exit program;
    ENDIF;
    display 'Transaction Type - D)ebit or C)redit? '
    read trans_type;
    display 'Transaction Amount? '
    read trans_amt;
   --------------------- begin PL/SQL block -------------------
    EXEC SQL EXECUTE
        DECLARE
            old_bal      NUMBER(9,2);
            err_msg      CHAR(70);
            nonexistent  EXCEPTION;
        BEGIN
           :trans_type := UPPER(:trans_type);
            IF :trans_type = 'C' THEN      -- credit the account
                UPDATE accts SET bal = bal + :trans_amt
                    WHERE acctid = :acct_num;
                IF SQL%ROWCOUNT = 0 THEN    -- no rows affected
                    RAISE nonexistent;
                ELSE
                   :status := 'Credit applied';
                END IF;
            ELSIF :trans_type = 'D' THEN   -- debit the account
                SELECT bal INTO old_bal FROM accts
                    WHERE acctid = :acct_num;
                IF old_bal >= :trans_amt THEN  -- enough funds
                    UPDATE accts SET bal = bal - :trans_amt
                        WHERE acctid = :acct_num;
                    :status := 'Debit applied';
                ELSE
                    :status := 'Insufficient funds';
                END IF;
            ELSE
                :status := 'Invalid type: ' || :trans_type;
            END IF;
            COMMIT;
     EXCEPTION
            WHEN NO_DATA_FOUND OR nonexistent THEN
                :status := 'Nonexistent account';
            WHEN OTHERS THEN
                err_msg := SUBSTR(SQLERRM, 1, 70);
               :status := 'Error: ' || err_msg;
        END;
    END-EXEC;
    ------------------- end PL/SQL block -----------------------
    display 'Status: ', status;
ENDLOOP;
ROUTINE sql_error
BEGIN
   EXEC SQL WHENEVER SQLERROR CONTINUE;
    EXEC SQL ROLLBACK WORK RELEASE; 
    display 'Processing error';
    exit program with an error;
END sql_error;

VARCHAR Pseudotype

Recall from Chapter 3, "Meeting Program Requirements" that you can use the VARCHAR pseudotype to declare variable-length character strings. If the VARCHAR is an input host variable, you must tell Oracle what length to expect. So, set the length field to the actual length of the value stored in the string field.

If the VARCHAR is an output host variable, Oracle automatically sets the length field. However, to use a VARCHAR output host variable in your PL/SQL block, you must initialize the length field before entering the block. So, set the length field to the declared (maximum) length of the VARCHAR, as shown in the following example:

EXEC SQL BEGIN DECLARE SECTION;
    emp_number  INTEGER;
    emp_name    VARCHAR(10);
    salary      REAL;
    ...
EXEC SQL END DECLARE SECTION;
...
set emp_name.len = 10;  -- initialize length field
EXEC SQL EXECUTE
    BEGIN
        SELECT ename, sal INTO :emp_name, :salary
            FROM emp
            WHERE empno = :emp_number;
        ...
    END;
END-EXEC;

Using Indicator Variables

PL/SQL does not need indicator variables because it can manipulate nulls. For example, within PL/SQL, you can use the IS NULL operator to test for nulls, as follows:

IF variable IS NULL THEN ...

You can use the assignment operator (:=) to assign nulls, as follows:

variable := NULL;

However, host languages need indicator variables because they cannot manipulate nulls. Embedded PL/SQL meets this need by letting you use indicator variables to

When used in a PL/SQL block, indicator variables are subject to the following rules:

In the following example, the indicator variable ind_comm appears with its host variable commission in the SELECT statement, so it must appear that way in the IF statement:

EXEC SQL EXECUTE
    BEGIN
        SELECT ename, comm
            INTO :emp_name, :commission:ind_comm FROM emp
            WHERE empno = :emp_number;
        IF :commission:ind_comm IS NULL THEN ...
        ...
    END;
END-EXEC;

Notice that PL/SQL treats :commission:ind_comm like any other simple variable. Though you cannot refer directly to an indicator variable inside a PL/SQL block, PL/SQL checks the value of the indicator variable when entering the block and sets the value correctly when exiting the block.

Handling Nulls

When entering a block, if an indicator variable has a value of -1, PL/SQL automatically assigns a null to the host variable. When exiting the block, if a host variable is null, PL/SQL automatically assigns a value of -1 to the indicator variable. In the next example, if ind_sal had a value of -1 before the PL/SQL block was entered, the salary_missing exception is raised. An exception is a named error condition.

EXEC SQL EXECUTE
    BEGIN
        IF :salary:ind_sal IS NULL THEN
            RAISE salary_missing;
        END IF;
        ...
    END;
END-EXEC;

Handling Truncated Values

PL/SQL does not raise an exception when a truncated string value is assigned to a host variable. However, if you use an indicator variable, PL/SQL sets it to the original length of the string. In the following example, the host program will be able to tell, by checking the value of ind_name, if a truncated value was assigned to emp_name:

EXEC SQL EXECUTE
    DECLARE
        ...
        new_name  CHAR(10);
    BEGIN
        ...
        :emp_name:ind_name := new_name;
        ...
    END;
END-EXEC;

Using Host Arrays

You can pass input host arrays and indicator arrays to a PL/SQL block. They can be indexed by a PL/SQL variable of type BINARY_INTEGER or by a host variable compatible with that type. Normally, the entire host array is passed to PL/SQL, but you can use the ARRAYLEN statement (discussed later) to specify a smaller array dimension.

Furthermore, you can use a subprogram call to assign all the values in a host array to rows in a PL/SQL table. Given that the array subscript range is m .. n, the corresponding PL/SQL table index range is always 1 .. (n - m + 1). For example, if the array subscript range is 5 .. 10, the corresponding PL/SQL table index range is 1 .. (10 - 5 + 1) or 1 .. 6.

Note: The Oracle Precompilers do not check your usage of host arrays. For instance, no index range checking is done.

In the example below, you pass a host array named salary to a PL/SQL block, which uses the host array in a function call. The function is named median because it finds the middle value in a series of numbers. Its formal parameters include a PL/SQL table named num_tab. The function call assigns all the values in the actual parameter salary to rows in the formal parameter num_tab.

EXEC SQL BEGIN DECLARE SECTION;
    ...
    salary (100)   REAL;
    median_salary  REAL;
EXEC SQL END DECLARE SECTION;
-- populate the host array
EXEC SQL EXECUTE
    DECLARE
        TYPE NumTabTyp IS TABLE OF REAL
            INDEX BY BINARY_INTEGER;
        n  BINARY_INTEGER;
        ...
        FUNCTION median (num_tab NumTabTyp, n INTEGER)
            RETURN REAL IS
        BEGIN
            -- compute median
        END;
    BEGIN
        n := 100;
        :median_salary := median(:salary, n);
        ...
    END;
END-EXEC;

You can also use a subprogram call to assign all row values in a PL/SQL table to corresponding elements in a host array. For an example, see "Stored Subprograms" [*].

Table 5 - 1 shows the legal conversions between row values in a PL/SQL table and elements in a host array. For example, a host array of type LONG is compatible with a PL/SQL table of type VARCHAR2, LONG, RAW, or LONG RAW. Notably, it is not compatible with a PL/SQL table of type CHAR.

PL/SQL Table
Host Array CHAR DATE LONG LONG RAW NUMBER RAW ROWID VARCHAR2
CHARF _/
CHARZ _/
DATE _/
DECIMAL _/
DISPLAY _/
FLOAT _/
INTEGER _/
LONG _/ _/
LONG VARCHAR _/ _/ _/ _/
LONG VARRAW _/ _/
NUMBER _/
RAW _/ _/
ROWID _/
STRING _/ _/ _/ _/
UNSIGNED _/
VARCHAR _/ _/ _/ _/
VARCHAR2 _/ _/ _/ _/
VARNUM _/
VARRAW _/ _/
Table 5 - 1. Legal Datatype Conversions

ARRAYLEN Statement

Suppose you must pass an input host array to a PL/SQL block for processing. By default, when binding such a host array, the Oracle Precompilers use its declared dimension. However, you might not want to process the entire array. In that case, you can use the ARRAYLEN statement to specify a smaller array dimension. ARRAYLEN associates the host array with a host variable, which stores the smaller dimension. The statement syntax is

EXEC SQL ARRAYLEN host_array (dimension);

where dimension is a 4-byte, integer host variable, not a literal or an expression.

The ARRAYLEN statement must appear in the Declare Section along with, but somewhere after, the declarations of host_array and dimension. You cannot specify an offset into the host array. However, you might be able to use host-language features for that purpose.

In the following example, you use ARRAYLEN to override the default dimension of a host array named bonus:

EXEC SQL BEGIN DECLARE SECTION;
    bonus (100)  REAL;
    my_dim       INTEGER;
    EXEC SQL ARRAYLEN bonus (my_dim);
EXEC SQL END DECLARE SECTION; 
-- populate the host array
...
set my_dim = 25;  -- set smaller array dimension
EXEC SQL EXECUTE
    DECLARE
        TYPE NumTabTyp IS TABLE OF REAL
            INDEX BY BINARY_INTEGER;
        median_bonus  REAL;
        FUNCTION median (num_tab NumTabTyp, n INTEGER)
            RETURN REAL IS
        BEGIN
            -- compute median
        END;
    BEGIN
        median_bonus := median(:bonus, :my_dim);
        ...
    END;
END-EXEC;

Only 25 array elements are passed to the PL/SQL block because ARRAYLEN downsizes the host array from 100 to 25 elements. As a result, when the PL/SQL block is sent to Oracle for execution, a much smaller host array is sent along. This saves time and, in a networked environment, reduces network traffic.

Using Cursors

Every embedded SQL statement is assigned a cursor, either explicitly by you in a DECLARE CURSOR statement or implicitly by the precompiler. Internally, the Oracle Precompilers maintain a cache, called the cursor cache, to control the execution of embedded SQL statements. When executed, every SQL statement is assigned an entry in the cursor cache. This entry is linked to a private SQL area in your Program Global Area (PGA) within Oracle.

Various precompiler options, including MAXOPENCURSORS, HOLD_CURSOR, and RELEASE_CURSOR, let you manage the cursor cache to improve performance. For example, RELEASE_CURSOR controls what happens to the link between the cursor cache and private SQL area. If you specify RELEASE_CURSOR=YES, the link is removed after Oracle executes the SQL statement. This frees memory allocated to the private SQL area and releases parse locks.

For purposes of cursor cache management, an embedded PL/SQL block is treated just like a SQL statement. At run time, a cursor, called a parent cursor, is associated with the entire PL/SQL block. A corresponding entry is made to the cursor cache, and this entry is linked to a private SQL area in the PGA.

Each SQL statement inside the PL/SQL block also requires a private SQL area in the PGA. So, PL/SQL manages a separate cache, called the child cursor cache, for these SQL statements. Their cursors are called child cursors. Because PL/SQL manages the child cursor cache, you do not have direct control over child cursors.

The maximum number of cursors your program can use simultaneously is set by the Oracle initialization parameter OPEN_CURSORS. Figure 5 - 1 shows you how to calculate the maximum number of cursors in use.

Text description of image009.gif follows.

Text description of the illustration image009.gif. Figure 5 - 1. Maximum Cursors in Use

If your program exceeds the limit imposed by OPEN_CURSORS, you get the following Oracle error:

ORA-01000: maximum open cursors exceeded

You can avoid this error by specifying the RELEASE_CURSOR=YES and HOLD_CURSOR=NO options. If you do not want to precompile the entire program with RELEASE_CURSOR set to YES, simply reset it to NO after each PL/SQL block, as follows:

    EXEC ORACLE OPTION (RELEASE_CURSOR=YES);
--  first embedded PL/SQL block
    EXEC ORACLE OPTION (RELEASE_CURSOR=NO);
--  embedded SQL statements
    EXEC ORACLE OPTION (RELEASE_CURSOR=YES);
--  second embedded PL/SQL block
    EXEC ORACLE OPTION (RELEASE_CURSOR=NO);
--  embedded SQL statements

An Alternative

The MAXOPENCURSORS option specifies the initial size of the cursor cache. For example, when MAXOPENCURSORS=10, the cursor cache can hold up to 10 entries. If a new cursor is needed, there are no free cache entries, and HOLD_CURSOR=NO, the precompiler tries to reuse an entry. If you specify a very low value for MAXOPENCURSORS, the precompiler is forced to reuse the parent cursor more often. All the child cursors are released as soon as the parent cursor is reused.

Stored Subprograms

Unlike anonymous blocks, PL/SQL subprograms (procedures and functions) can be compiled separately, stored in an Oracle database, and invoked. A subprogram explicitly created using an Oracle tool such as SQL*Plus or Server Manager is called a stored subprogram. Once compiled and stored in the data dictionary, it is a database object, which can be reexecuted without being recompiled.

When a subprogram within a PL/SQL block or stored subprogram is sent to Oracle by your application, it is called an inline subprogram. Oracle compiles the inline subprogram and caches it in the System Global Area (SGA), but does not store the source or object code in the data dictionary.

Subprograms defined within a package are considered part of the package, and so are called packaged subprograms. Stored subprograms not defined within a package are called standalone subprograms.

Creating Stored Subprograms

You can embed the SQL statements CREATE FUNCTION, CREATE PROCEDURE, and CREATE PACKAGE in a host program, as the following example shows:

EXEC SQL CREATE
    FUNCTION sal_ok (salary REAL, title CHAR)
      RETURN BOOLEAN AS
        min_sal  REAL;
        max_sal  REAL;
    BEGIN
        SELECT losal, hisal INTO min_sal, max_sal
            FROM sals
            WHERE job = title;
        RETURN (salary >= min_sal) AND
               (salary <= max_sal);
    END sal_ok;
END-EXEC;

Notice that the embedded CREATE {FUNCTION | PROCEDURE | PACKAGE} statement is a hybrid. Like all other embedded CREATE statements, it begins with the keywords EXEC SQL (not EXEC SQL EXECUTE). But, unlike other embedded CREATE statements, it ends with the PL/SQL terminator END-EXEC.

In the example below, you create a package that contains a procedure named get_employees, which fetches a batch of rows from the emp table. The batch size is determined by the caller of the procedure, which might be another stored subprogram or a client application program.

The procedure declares three PL/SQL tables as OUT formal parameters, then fetches a batch of employee data into the PL/SQL tables. The matching actual parameters are host arrays. When the procedure finishes, it automatically assigns all row values in the PL/SQL tables to corresponding elements in the host arrays.

EXEC SQL CREATE OR REPLACE PACKAGE emp_actions AS
        TYPE CharArrayTyp IS TABLE OF VARCHAR2(10)
            INDEX BY BINARY_INTEGER;
        TYPE NumArrayTyp IS TABLE OF FLOAT
            INDEX BY BINARY_INTEGER;
        PROCEDURE get_employees(
            dept_number IN     INTEGER,
            batch_size  IN     INTEGER,
            found       IN OUT INTEGER,
            done_fetch  OUT    INTEGER,
            emp_name    OUT    CharArrayTyp,
            job-title   OUT    CharArrayTyp,
            salary      OUT    NumArrayTyp);
    END emp_actions;
END-EXEC;
EXEC SQL CREATE OR REPLACE PACKAGE BODY emp_actions AS
        CURSOR get_emp (dept_number IN INTEGER) IS
            SELECT ename, job, sal FROM emp
                WHERE deptno = dept_number;
        PROCEDURE get_employees(
            dept_number IN     INTEGER,
            batch_size  IN     INTEGER,
            found       IN OUT INTEGER,
            done_fetch  OUT    INTEGER,
            emp_name    OUT    CharArrayTyp,
            job_title   OUT    CharArrayTyp,
            salary      OUT    NumArrayTyp) IS
        BEGIN
            IF NOT get_emp%ISOPEN THEN
                OPEN get_emp(dept_number);
            END IF;
            done_fetch := 0;
            found := 0;
            FOR i IN 1..batch_size LOOP
                FETCH get_emp INTO emp_name(i),
                    job_title(i), salary(i);
                IF get_emp%NOTFOUND THEN
                    CLOSE get_emp;
                    done_fetch := 1;
                    EXIT;
                ELSE
                    found := found + 1;
                END IF;
            END LOOP;
        END get_employees;
    END emp_actions;
END-EXEC;

You specify the REPLACE clause in the CREATE statement to redefine an existing package without having to drop the package, recreate it, and regrant privileges on it. For the full syntax of the CREATE statement see the Oracle7 Server SQL Reference.

If an embedded CREATE {FUNCTION|PROCEDURE|PACKAGE} statement fails, Oracle generates a warning, not an error.

Calling a Stored Subprogram

To invoke (call) a stored subprogram from your host program, you must use an anonymous PL/SQL block. In the following example, you call a standalone procedure named raise_salary:

EXEC SQL EXECUTE
    BEGIN
        raise_salary(:emp_id, :increase);
    END;
END-EXEC;

Notice that stored subprograms can take parameters. In this example, the actual parameters emp_id and increase are host variables.

In the next example, the procedure raise_salary is stored in a package named emp_actions, so you must use dot notation to fully qualify the procedure call:

EXEC SQL EXECUTE
    BEGIN
        emp_actions.raise_salary(:emp_id, :increase);
    END;
END-EXEC;

An actual IN parameter can be a literal, host variable, host array, PL/SQL constant or variable, PL/SQL table, PL/SQL user-defined record, subprogram call, or expression. However, an actual OUT parameter cannot be a literal, subprogram call, or expression.

In the Pro*C example below, three of the formal parameters are PL/SQL tables, and the corresponding actual parameters are host arrays. The program calls the stored procedure get_employees repeatedly, displaying each batch of employee data, until no more data is found.

#include <stdio.h>
#include <string.h>
typedef char asciz;
EXEC SQL BEGIN DECLARE SECTION;
    /* Define type for null-terminated strings */
    EXEC SQL TYPE asciz IS STRING(20);
    asciz   username[20];
    asciz   password[20];
    int     dept_no;    /* which department to query */
    char    emp_name[10][21];
    char    job[10][21];
    float   salary[10];
    int     done_flag;
    int     array_size;
    int     num_ret;    /* number of rows returned */
    int     SQLCODE;
EXEC SQL END DECLARE SECTION;
EXEC SQL INCLUDE sqlca;
int print_rows();  /* produces program output      */
int sql_error();    /* handles unrecoverable errors */
main()
{
    int i;
    /* Connect to Oracle. */
    strcpy(username, "SCOTT");
    strcpy(password, "TIGER");
    EXEC SQL WHENEVER SQLERROR DO sql_error();
    EXEC SQL CONNECT :username IDENTIFIED BY :password;
    printf("\nConnected to Oracle as user: %s\n", username);
    printf("enter department number: ");
    scanf("%d", &dept_no);
    fflush(stdin);
    /* Set the array size. */
    array_size = 10;
    done_flag = 0;
    num_ret = 0;
    /* Array fetch loop - ends when done_flag is true. */
    for (;;)
    {
        EXEC SQL EXECUTE
            BEGIN emp_actions.get_employees
                (:dept_no, :array_size, :num_ret,
                 :done_flag, :emp_name, :job, :salary);
            END;
        END-EXEC;
        print_rows(num_ret);
        if (done_flag)
            break;
    }
    /* Disconnect from the database. */
    EXEC SQL COMMIT WORK RELEASE;
    exit(0);
}
print_rows(n)
int n;
{
    int i;
    if (n == 0)
    {
        printf("No rows retrieved.\n");
        return;
    }
    printf("\n\nGot %d row%c\n", n, n == 1 ? '\0' : 's');
    printf("%-20.20s%-20.20s%s\n", "Ename", "Job", "Salary");
    for (i = 0; i < n; i++)
        printf("%20.20s%20.20s%6.2f\n",
               emp_name[i], job[i], salary[i]);
}
sql_error()
{
    EXEC SQL WHENEVER SQLERROR CONTINUE;
    printf("\nOracle error detected:");
    printf("\n% .70s \n", sqlca.sqlerrm.sqlerrmc);
    EXEC SQL ROLLBACK WORK RELEASE;
    exit(1);
}

Remember, the datatype of each actual parameter must be convertible to the datatype of its corresponding formal parameter. Also, before a stored subprogram exits, all OUT formal parameters must be assigned values. Otherwise, the values of corresponding actual parameters are indeterminate.

Remote Access

PL/SQL lets you access remote databases via database links. Typically, database links are established by your DBA and stored in the Oracle data dictionary. A database link tells Oracle where the remote database is located, the path to it, and what Oracle username and password to use. In the following example, you use the database link dallas to call the raise_salary procedure:

EXEC SQL EXECUTE
    BEGIN
        raise_salary@dallas(:emp_id, :increase);
    END;
END-EXEC;

You can create synonyms to provide location transparency for remote subprograms, as the following example shows:

CREATE PUBLIC SYNONYM raise_salary FOR raise_salary@dallas;

Getting Information about Stored Subprograms

In Chapter 3, you learned how to embed OCI calls in your host program. After calling the library routine SQLLDA to set up the LDA, you can use the OCI call ODESSP to get useful information about a stored subprogram. When you call ODESSP, you must pass it a valid LDA and the name of the subprogram. For packaged subprograms, you must also pass the name of the package. ODESSP returns information about each subprogram parameter such as its datatype, size, position, and so on. For details, see the Programmer's Guide to the Oracle Call Interface.

You can also use the procedure describe_procedure in package DBMS_DESCRIBE, which is supplied with Oracle7. For more information, see the Oracle7 Server Application Developer's Guide

Using Dynamic PL/SQL

Recall that the Oracle Precompilers treat an entire PL/SQL block like a single SQL statement. Therefore, you can store a PL/SQL block in a string host variable. Then, if the block contains no host variables, you can use dynamic SQL Method 1 to execute the PL/SQL string. Or, if the block contains a known number of host variables, you can use dynamic SQL Method 2 to prepare and execute the PL/SQL string. If the block contains an unknown number of host variables, you must use dynamic SQL Method 4. For more information, refer to Chapter 10, "Using Dynamic SQL."

Restriction

In dynamic SQL Method 4, a host array cannot be bound to a PL/SQL procedure with a parameter of type "table."


Go to previous file in sequence Go to next file in sequence Oracle
Copyright © 1996-2001, Oracle Corporation.
All Rights Reserved.
Go To Documentation Library
Home
Go To Product List
Book List
Go To Table Of Contents
Contents
Go To Index
Index

Master Index

Feedback