Skip Headers
Oracle® Database PL/SQL User's Guide and Reference
10g Release 2 (10.2)

Part Number B14261-01
Go to Documentation Home
Home
Go to Book List
Book List
Go to Table of Contents
Contents
Go to Index
Index
Go to Master Index
Master Index
Go to Feedback page
Contact Us

Go to previous page
Previous
Go to next page
Next
View PDF

6 Performing SQL Operations from PL/SQL

This chapter shows how PL/SQL supports the SQL commands, functions, and operators that let you manipulate Oracle data.

This chapter contains these topics:

Overview of SQL Support in PL/SQL

By extending SQL, PL/SQL offers a unique combination of power and ease of use. You can manipulate Oracle data flexibly and safely because PL/SQL fully supports all SQL data manipulation statements (except EXPLAIN PLAN), transaction control statements, functions, pseudocolumns, and operators. PL/SQL also conforms to the current ANSI/ISO SQL standard.

In addition to static SQL discussed in this chapter, PL/SQL also supports dynamic SQL, which enables you to execute SQL data definition, data control, and session control statements dynamically. See Chapter 7, "Performing SQL Operations with Native Dynamic SQL".

Data Manipulation

To manipulate Oracle data you can include DML operations, such as INSERT, UPDATE, and DELETE statements, directly in PL/SQL programs, without any special notation, as shown in Example 6-1. You can also include the SQL COMMIT statement directly in a PL/SQL program; see "Overview of Transaction Processing in PL/SQL". See also COMMIT in the Oracle Database SQL Reference.

Example 6-1 Data Manipulation With PL/SQL

CREATE TABLE employees_temp AS SELECT employee_id, first_name, last_name 
       FROM employees;
DECLARE
  emp_id          employees_temp.employee_id%TYPE;
  emp_first_name  employees_temp.first_name%TYPE;
  emp_last_name   employees_temp.last_name%TYPE;
BEGIN
   INSERT INTO employees_temp VALUES(299, 'Bob', 'Henry');
   UPDATE employees_temp SET first_name = 'Robert' WHERE employee_id = 299;
   DELETE FROM employees_temp WHERE employee_id = 299 
     RETURNING first_name, last_name INTO emp_first_name, emp_last_name;
   COMMIT;
   DBMS_OUTPUT.PUT_LINE( emp_first_name  || ' ' || emp_last_name);
END;
/

To find out how many rows are affected by DML statements, you can check the value of SQL%ROWCOUNT as shown in Example 6-2.

Example 6-2 Checking SQL%ROWCOUNT After an UPDATE

CREATE TABLE employees_temp AS SELECT * FROM employees;
BEGIN
  UPDATE employees_temp SET salary = salary * 1.05 WHERE salary < 5000;
  DBMS_OUTPUT.PUT_LINE('Updated ' || SQL%ROWCOUNT || ' salaries.');
END;
/

Wherever you would use literal values, or bind variables in some other programming language, you can directly substitute PL/SQL variables as shown in Example 6-3.

Example 6-3 Substituting PL/SQL Variables

CREATE TABLE employees_temp AS SELECT first_name, last_name FROM employees;
DECLARE
   x VARCHAR2(20) := 'my_first_name';
   y VARCHAR2(25) := 'my_last_name';
BEGIN
   INSERT INTO employees_temp VALUES(x, y);
   UPDATE employees_temp SET last_name = x WHERE first_name = y;
   DELETE FROM employees_temp WHERE first_name = x;
   COMMIT;
END;
/

With this notation, you can use variables in place of values in the WHERE clause. To use variables in place of table names, column names, and so on, requires the EXECUTE IMMEDIATE statement that is explained in "Using the EXECUTE IMMEDIATE Statement in PL/SQL".

For information on the use of PL/SQL records with SQL to update and insert data, see "Inserting PL/SQL Records into the Database" and "Updating the Database with PL/SQL Record Values".

For additional information on assigning values to PL/SQL variables, see "Assigning a SQL Query Result to a PL/SQL Variable".

Note:

When issuing a data manipulation (DML) statement in PL/SQL, there are some situations when the value of a variable is undefined after the statement is executed. These include:
  • If a FETCH or SELECT statement raises any exception, then the values of the define variables after that statement are undefined.

  • If a DML statement affects zero rows, the values of the OUT binds after the DML executes are undefined. This does not apply to a BULK or multirow operation.

Transaction Control

Oracle is transaction oriented; that is, Oracle uses transactions to ensure data integrity. A transaction is a series of SQL data manipulation statements that does a logical unit of work. For example, two UPDATE statements might credit one bank account and debit another. It is important not to allow one operation to succeed while the other fails.

At the end of a transaction that makes database changes, Oracle makes all the changes permanent or undoes them all. If your program fails in the middle of a transaction, Oracle detects the error and rolls back the transaction, restoring the database to its former state.

You use the COMMIT, ROLLBACK, SAVEPOINT, and SET TRANSACTION commands to control transactions. COMMIT makes permanent any database changes made during the current transaction. ROLLBACK ends the current transaction and undoes any changes made since the transaction began. SAVEPOINT marks the current point in the processing of a transaction. Used with ROLLBACK, SAVEPOINT undoes part of a transaction. SET TRANSACTION sets transaction properties such as read-write access and isolation level. See "Overview of Transaction Processing in PL/SQL".

SQL Functions

Example 6-4 shows some queries that call SQL functions.

Example 6-4 Calling the SQL COUNT Function in PL/SQL

DECLARE
  job_count NUMBER;
  emp_count NUMBER;
BEGIN
  SELECT COUNT(DISTINCT job_id) INTO job_count FROM employees;
  SELECT COUNT(*) INTO emp_count FROM employees;
END;
/

SQL Pseudocolumns

PL/SQL recognizes the SQL pseudocolumns CURRVAL, LEVEL, NEXTVAL, ROWID, and ROWNUM. However, there are limitations on the use of pseudocolumns, including the restriction on the use of some pseudocolumns in assignments or conditional tests. For additional information, including restrictions, on the use of SQL pseudocolumns, see Oracle Database SQL Reference.

CURRVAL and NEXTVAL

A sequence is a schema object that generates sequential numbers. When you create a sequence, you can specify its initial value and an increment. CURRVAL returns the current value in a specified sequence. Before you can reference CURRVAL in a session, you must use NEXTVAL to generate a number. A reference to NEXTVAL stores the current sequence number in CURRVAL. NEXTVAL increments the sequence and returns the next value. To get the current or next value in a sequence, use dot notation:


sequence_name.CURRVAL
sequence_name.NEXTVAL

Each time you reference the NEXTVAL value of a sequence, the sequence is incremented immediately and permanently, whether you commit or roll back the transaction.

After creating a sequence, you can use it to generate unique sequence numbers for transaction processing. You can use CURRVAL and NEXTVAL only in a SELECT list, the VALUES clause, and the SET clause. Example 6-5 shows how to generate a new sequence number and refer to that same number in more than one statement.

Example 6-5 Using CURRVAL and NEXTVAL

CREATE TABLE employees_temp AS SELECT employee_id, first_name, last_name 
  FROM employees;
CREATE TABLE employees_temp2 AS SELECT employee_id, first_name, last_name 
  FROM employees;
 
DECLARE
   seq_value   NUMBER;
BEGIN
-- Display initial value of NEXTVAL
-- This is invalid: seq_value := employees_seq.NEXTVAL;
   SELECT employees_seq.NEXTVAL INTO seq_value FROM dual;
   DBMS_OUTPUT.PUT_LINE ('Initial sequence value: ' || TO_CHAR(seq_value));
-- The NEXTVAL value is the same no matter what table you select from
-- You usually use NEXTVAL to create unique numbers when inserting data.
   INSERT INTO employees_temp VALUES (employees_seq.NEXTVAL, 'Lynette', 'Smith');
-- If you need to store the same value somewhere else, you use CURRVAL
   INSERT INTO employees_temp2 VALUES (employees_seq.CURRVAL, 'Morgan', 'Smith');
-- Because NEXTVAL values might be referenced by different users and
-- applications, and some NEXTVAL values might not be stored in the
-- database, there might be gaps in the sequence
-- The following uses the stored value of the CURRVAL in seq_value to specify 
-- the record to delete because CURRVAL (or NEXTVAL) cannot used in a WHERE clause
-- This is invalid: WHERE employee_id = employees_seq.CURRVAL;
   SELECT employees_seq.CURRVAL INTO seq_value FROM dual;
   DELETE FROM employees_temp2 WHERE employee_id = seq_value;
-- The following udpates the employee_id with NEXTVAL for the specified record
   UPDATE employees_temp SET employee_id = employees_seq.NEXTVAL 
     WHERE first_name = 'Lynette' AND last_name = 'Smith';
-- Display end value of CURRVAL
   SELECT employees_seq.CURRVAL INTO seq_value FROM dual;
   DBMS_OUTPUT.PUT_LINE ('Ending sequence value: ' || TO_CHAR(seq_value));
END;
/

LEVEL

You use LEVEL with the SELECT CONNECT BY statement to organize rows from a database table into a tree structure. You might use sequence numbers to give each row a unique identifier, and refer to those identifiers from other rows to set up parent-child relationships. LEVEL returns the level number of a node in a tree structure. The root is level 1, children of the root are level 2, grandchildren are level 3, and so on.

In the START WITH clause, you specify a condition that identifies the root of the tree. You specify the direction in which the query traverses the tree (down from the root or up from the branches) with the PRIOR operator.

ROWID

ROWID returns the rowid (binary address) of a row in a database table. You can use variables of type UROWID to store rowids in a readable format.

When you select or fetch a physical rowid into a UROWID variable, you can use the function ROWIDTOCHAR, which converts the binary value to a character string. You can compare the UROWID variable to the ROWID pseudocolumn in the WHERE clause of an UPDATE or DELETE statement to identify the latest row fetched from a cursor. For an example, see "Fetching Across Commits".

ROWNUM

ROWNUM returns a number indicating the order in which a row was selected from a table. The first row selected has a ROWNUM of 1, the second row has a ROWNUM of 2, and so on. If a SELECT statement includes an ORDER BY clause, ROWNUMs are assigned to the retrieved rows before the sort is done; use a subselect to get the first n sorted rows. The value of ROWNUM increases only when a row is retrieved, so the only meaningful uses of ROWNUM in a WHERE clause are:


... WHERE ROWNUM < constant;
... WHERE ROWNUM <= constant;

You can use ROWNUM in an UPDATE statement to assign unique values to each row in a table, or in the WHERE clause of a SELECT statement to limit the number of rows retrieved, as shown in Example 6-6.

Example 6-6 Using ROWNUM

CREATE TABLE employees_temp AS SELECT * FROM employees;
DECLARE
   CURSOR c1 IS SELECT employee_id, salary FROM employees_temp
      WHERE salary > 2000 AND ROWNUM <= 10;  -- 10 arbitrary rows
   CURSOR c2 IS SELECT * FROM
     (SELECT employee_id, salary FROM employees_temp
       WHERE salary > 2000 ORDER BY salary DESC)
     WHERE ROWNUM < 5;  -- first 5 rows, in sorted order
BEGIN
-- Each row gets assigned a different number
  UPDATE employees_temp SET employee_id = ROWNUM;
END;
/

SQL Operators

PL/SQL lets you use all the SQL comparison, set, and row operators in SQL statements. This section briefly describes some of these operators. For more information, see Oracle Database SQL Reference.

Comparison Operators

Typically, you use comparison operators in the WHERE clause of a data manipulation statement to form predicates, which compare one expression to another and yield TRUE, FALSE, or NULL. You can use the comparison operators in the following list to form predicates. You can combine predicates using the logical operators AND, OR, and NOT.

Operator Description
ALL Compares a value to each value in a list or returned by a subquery and yields TRUE if all of the individual comparisons yield TRUE.
ANY, SOME Compares a value to each value in a list or returned by a subquery and yields TRUE if any of the individual comparisons yields TRUE.
BETWEEN Tests whether a value lies in a specified range.
EXISTS Returns TRUE if a subquery returns at least one row.
IN Tests for set membership.
IS NULL Tests for nulls.
LIKE Tests whether a character string matches a specified pattern, which can include wildcards.

Set Operators

Set operators combine the results of two queries into one result. INTERSECT returns all distinct rows selected by both queries. MINUS returns all distinct rows selected by the first query but not by the second. UNION returns all distinct rows selected by either query. UNION ALL returns all rows selected by either query, including all duplicates.

Row Operators

Row operators return or reference particular rows. ALL retains duplicate rows in the result of a query or in an aggregate expression. DISTINCT eliminates duplicate rows from the result of a query or from an aggregate expression. PRIOR refers to the parent row of the current row returned by a tree-structured query.

Managing Cursors in PL/SQL

PL/SQL uses implicit and explicit cursors. PL/SQL declares a cursor implicitly for all SQL data manipulation statements, including queries that return only one row. If you want precise control over query processing, you can declare an explicit cursor in the declarative part of any PL/SQL block, subprogram, or package. You must declare an explicit cursor for queries that return more than one row.

Implicit Cursors

Implicit cursors are managed automatically by PL/SQL so you are not required to write any code to handle these cursors. However, you can track information about the execution of an implicit cursor through its cursor attributes.

Attributes of Implicit Cursors

Implicit cursor attributes return information about the execution of DML and DDL statements, such INSERT, UPDATE, DELETE, SELECT INTO, COMMIT, or ROLLBACK statements. The cursor attributes are %FOUND, %ISOPEN %NOTFOUND, and %ROWCOUNT. The values of the cursor attributes always refer to the most recently executed SQL statement. Before Oracle opens the SQL cursor, the implicit cursor attributes yield NULL.

The SQL cursor has another attribute, %BULK_ROWCOUNT, designed for use with the FORALL statement. For more information, see "Counting Rows Affected by FORALL with the %BULK_ROWCOUNT Attribute".

%FOUND Attribute: Has a DML Statement Changed Rows?

Until a SQL data manipulation statement is executed, %FOUND yields NULL. Thereafter, %FOUND yields TRUE if an INSERT, UPDATE, or DELETE statement affected one or more rows, or a SELECT INTO statement returned one or more rows. Otherwise, %FOUND yields FALSE. In Example 6-7, you use %FOUND to insert a row if a delete succeeds.

Example 6-7 Using SQL%FOUND

CREATE TABLE dept_temp AS SELECT * FROM departments;
DECLARE
  dept_no NUMBER(4) := 270;
BEGIN
  DELETE FROM dept_temp WHERE department_id = dept_no;
  IF SQL%FOUND THEN  -- delete succeeded
    INSERT INTO dept_temp VALUES (270, 'Personnel', 200, 1700);
  END IF;
END;
/

%ISOPEN Attribute: Always FALSE for Implicit Cursors

Oracle closes the SQL cursor automatically after executing its associated SQL statement. As a result, %ISOPEN always yields FALSE.

%NOTFOUND Attribute: Has a DML Statement Failed to Change Rows?

%NOTFOUND is the logical opposite of %FOUND. %NOTFOUND yields TRUE if an INSERT, UPDATE, or DELETE statement affected no rows, or a SELECT INTO statement returned no rows. Otherwise, %NOTFOUND yields FALSE.

%ROWCOUNT Attribute: How Many Rows Affected So Far?

%ROWCOUNT yields the number of rows affected by an INSERT, UPDATE, or DELETE statement, or returned by a SELECT INTO statement. %ROWCOUNT yields 0 if an INSERT, UPDATE, or DELETE statement affected no rows, or a SELECT INTO statement returned no rows. In Example 6-8, %ROWCOUNT returns the number of rows that have been deleted.

Example 6-8 Using SQL%ROWCOUNT

CREATE TABLE employees_temp AS SELECT * FROM employees;
DECLARE
  mgr_no NUMBER(6) := 122;
BEGIN
  DELETE FROM employees_temp WHERE manager_id = mgr_no;
  DBMS_OUTPUT.PUT_LINE('Number of employees deleted: ' || TO_CHAR(SQL%ROWCOUNT));
END;
/

If a SELECT INTO statement returns more than one row, PL/SQL raises the predefined exception TOO_MANY_ROWS and %ROWCOUNT yields 1, not the actual number of rows that satisfy the query.

The value of the SQL%ROWCOUNT attribute refers to the most recently executed SQL statement from PL/SQL. To save an attribute value for later use, assign it to a local variable immediately.

The SQL%ROWCOUNT attribute is not related to the state of a transaction. When a rollback to a savepoint is performed, the value of SQL%ROWCOUNT is not restored to the old value before the savepoint was taken. Also, when an autonomous transaction is exited, SQL%ROWCOUNT is not restored to the original value in the parent transaction.

Guidelines for Using Attributes of Implicit Cursors

The following are considerations when using attributes of implicit cursors:

  • The values of the cursor attributes always refer to the most recently executed SQL statement, wherever that statement is. It might be in a different scope (for example, in a sub-block). To save an attribute value for later use, assign it to a local variable immediately. Doing other operations, such as procedure calls, might change the value of the variable before you can test it.

  • The %NOTFOUND attribute is not useful in combination with the SELECT INTO statement:

    • If a SELECT INTO statement fails to return a row, PL/SQL raises the predefined exception NO_DATA_FOUND immediately, interrupting the flow of control before you can check %NOTFOUND.

    • A SELECT INTO statement that calls a SQL aggregate function always returns a value or a null. After such a statement, the %NOTFOUND attribute is always FALSE, so checking it is unnecessary.

Explicit Cursors

When you need precise control over query processing, you can explicitly declare a cursor in the declarative part of any PL/SQL block, subprogram, or package.

You use three commands to control a cursor: OPEN, FETCH, and CLOSE. First, you initialize the cursor with the OPEN statement, which identifies the result set. Then, you can execute FETCH repeatedly until all rows have been retrieved, or you can use the BULK COLLECT clause to fetch all rows at once. When the last row has been processed, you release the cursor with the CLOSE statement.

This technique requires more code than other techniques such as the implicit cursor FOR loop. Its advantage is flexibility. You can:

  • Process several queries in parallel by declaring and opening multiple cursors.

  • Process multiple rows in a single loop iteration, skip rows, or split the processing into more than one loop.

Declaring a Cursor

You must declare a cursor before referencing it in other statements. You give the cursor a name and associate it with a specific query. You can optionally declare a return type for the cursor, such as table_name%ROWTYPE. You can optionally specify parameters that you use in the WHERE clause instead of referring to local variables. These parameters can have default values. Example 6-9 shows how you can declare cursors.

Example 6-9 Declaring a Cursor

DECLARE
  my_emp_id     NUMBER(6);      -- variable for employee_id
  my_job_id     VARCHAR2(10);   -- variable for job_id
  my_sal        NUMBER(8,2);    -- variable for salary
  CURSOR c1 IS SELECT employee_id, job_id, salary FROM employees
      WHERE salary > 2000; 
  my_dept   departments%ROWTYPE;  -- variable for departments row
  CURSOR c2 RETURN departments%ROWTYPE IS 
      SELECT * FROM departments WHERE department_id = 110;

The cursor is not a PL/SQL variable: you cannot assign values to a cursor or use it in an expression. Cursors and variables follow the same scoping rules. Naming cursors after database tables is possible but not recommended.

A cursor can take parameters, which can appear in the associated query wherever constants can appear. The formal parameters of a cursor must be IN parameters; they supply values in the query, but do not return any values from the query. You cannot impose the constraint NOT NULL on a cursor parameter.

As the following example shows, you can initialize cursor parameters to default values. You can pass different numbers of actual parameters to a cursor, accepting or overriding the default values as you please. Also, you can add new formal parameters without having to change existing references to the cursor.

DECLARE
   CURSOR c1 (low  NUMBER DEFAULT 0, high NUMBER DEFAULT 99) IS
              SELECT * FROM departments WHERE department_id > low
              AND department_id < high;

Cursor parameters can be referenced only within the query specified in the cursor declaration. The parameter values are used by the associated query when the cursor is opened.

Opening a Cursor

Opening the cursor executes the query and identifies the result set, which consists of all rows that meet the query search criteria. For cursors declared using the FOR UPDATE clause, the OPEN statement also locks those rows. An example of the OPEN statement follows:

DECLARE
   CURSOR c1 IS SELECT employee_id, last_name, job_id, salary FROM employees
      WHERE salary > 2000; 
BEGIN
  OPEN C1;

Rows in the result set are retrieved by the FETCH statement, not when the OPEN statement is executed.

Fetching with a Cursor

Unless you use the BULK COLLECT clause, discussed in "Fetching with a Cursor", the FETCH statement retrieves the rows in the result set one at a time. Each fetch retrieves the current row and advances the cursor to the next row in the result set. You can store each column in a separate variable, or store the entire row in a record that has the appropriate fields, usually declared using %ROWTYPE.

For each column value returned by the query associated with the cursor, there must be a corresponding, type-compatible variable in the INTO list. Typically, you use the FETCH statement with a LOOP and EXIT WHEN .. NOTFOUND statements, as shown in Example 6-10. Note the use of built-in regular expression functions in the queries.

Example 6-10 Fetching With a Cursor

DECLARE
  v_jobid     employees.job_id%TYPE;     -- variable for job_id
  v_lastname  employees.last_name%TYPE;  -- variable for last_name
  CURSOR c1 IS SELECT last_name, job_id FROM employees 
                 WHERE REGEXP_LIKE (job_id, 'S[HT]_CLERK');
  v_employees employees%ROWTYPE;         -- record variable for row
  CURSOR c2 is SELECT * FROM employees 
                 WHERE REGEXP_LIKE (job_id, '[ACADFIMKSA]_M[ANGR]');
BEGIN
  OPEN c1; -- open the cursor before fetching
  LOOP
    FETCH c1 INTO v_lastname, v_jobid; -- fetches 2 columns into variables
    EXIT WHEN c1%NOTFOUND;
    DBMS_OUTPUT.PUT_LINE( RPAD(v_lastname, 25, ' ') || v_jobid );
  END LOOP;
  CLOSE c1;
  DBMS_OUTPUT.PUT_LINE( '-------------------------------------' );
  OPEN c2;
  LOOP
    FETCH c2 INTO v_employees; -- fetches entire row into the v_employees record
    EXIT WHEN c2%NOTFOUND;
    DBMS_OUTPUT.PUT_LINE( RPAD(v_employees.last_name, 25, ' ') ||
                               v_employees.job_id );
  END LOOP;
  CLOSE c2;
END;
/

The query can reference PL/SQL variables within its scope. Any variables in the query are evaluated only when the cursor is opened. In Example 6-11, each retrieved salary is multiplied by 2, even though factor is incremented after every fetch.

Example 6-11 Referencing PL/SQL Variables Within Its Scope

DECLARE
  my_sal employees.salary%TYPE;
  my_job employees.job_id%TYPE;
  factor INTEGER := 2;
  CURSOR c1 IS
    SELECT factor*salary FROM employees WHERE job_id = my_job;
BEGIN
   OPEN c1;  -- factor initially equals 2
   LOOP
      FETCH c1 INTO my_sal;
      EXIT WHEN c1%NOTFOUND;
      factor := factor + 1;  -- does not affect FETCH
   END LOOP;
   CLOSe c1;
END;
/

To change the result set or the values of variables in the query, you must close and reopen the cursor with the input variables set to their new values. However, you can use a different INTO list on separate fetches with the same cursor. Each fetch retrieves another row and assigns values to the target variables, as shown inExample 6-12.

Example 6-12 Fetching the Same Cursor Into Different Variables

DECLARE
   CURSOR c1 IS SELECT last_name FROM employees ORDER BY last_name;
   name1 employees.last_name%TYPE;
   name2 employees.last_name%TYPE;
   name3 employees.last_name%TYPE;
BEGIN
   OPEN c1;
   FETCH c1 INTO name1;  -- this fetches first row
   FETCH c1 INTO name2;  -- this fetches second row
   FETCH c1 INTO name3;  -- this fetches third row
   CLOSE c1;
END;/

If you fetch past the last row in the result set, the values of the target variables are undefined. Eventually, the FETCH statement fails to return a row. When that happens, no exception is raised. To detect the failure, use the cursor attribute %FOUND or %NOTFOUND. For more information, see "Using Cursor Expressions".

Fetching Bulk Data with a Cursor

The BULK COLLECT clause lets you fetch all rows from the result set at once. See "Retrieving Query Results into Collections with the BULK COLLECT Clause". In Example 6-13, you bulk-fetch from a cursor into two collections.

Example 6-13 Fetching Bulk Data With a Cursor

DECLARE
  TYPE IdsTab IS TABLE OF employees.employee_id%TYPE;
  TYPE NameTab IS TABLE OF employees.last_name%TYPE;
  ids  IdsTab;
  names NameTab;
  CURSOR c1 IS
    SELECT employee_id, last_name FROM employees WHERE job_id = 'ST_CLERK';
BEGIN
  OPEN c1;
  FETCH c1 BULK COLLECT INTO ids, names;
  CLOsE c1;
-- Here is where you process the elements in the collections
  FOR i IN ids.FIRST .. ids.LAST
    LOOP
      IF ids(i) > 140 THEN
          DBMS_OUTPUT.PUT_LINE( ids(i) );
       END IF;
    END LOOP;
  FOR i IN names.FIRST .. names.LAST
    LOOP
      IF names(i) LIKE '%Ma%' THEN
          DBMS_OUTPUT.PUT_LINE( names(i) );
       END IF;
    END LOOP;
END;
/

Closing a Cursor

The CLOSE statement disables the cursor, and the result set becomes undefined. Once a cursor is closed, you can reopen it, which runs the query again with the latest values of any cursor parameters and variables referenced in the WHERE clause. Any other operation on a closed cursor raises the predefined exception INVALID_CURSOR.

Attributes of Explicit Cursors

Every explicit cursor and cursor variable has four attributes: %FOUND, %ISOPEN %NOTFOUND, and %ROWCOUNT. When appended to the cursor or cursor variable name, these attributes return useful information about the execution of a SQL statement. You can use cursor attributes in procedural statements but not in SQL statements.

Explicit cursor attributes return information about the execution of a multi-row query. When an explicit cursor or a cursor variable is opened, the rows that satisfy the associated query are identified and form the result set. Rows are fetched from the result set.

%FOUND Attribute: Has a Row Been Fetched?

After a cursor or cursor variable is opened but before the first fetch, %FOUND returns NULL. After any fetches, it returns TRUE if the last fetch returned a row, or FALSE if the last fetch did not return a row. Example 6-14 uses %FOUND to select an action.

Example 6-14 Using %FOUND

DECLARE
   CURSOR c1 IS SELECT last_name, salary FROM employees WHERE ROWNUM < 11;
   my_ename employees.last_name%TYPE;
   my_salary employees.salary%TYPE;
BEGIN
  OPEN c1;
  LOOP
    FETCH c1 INTO my_ename, my_salary;
    IF c1%FOUND THEN  -- fetch succeeded
      DBMS_OUTPUT.PUT_LINE('Name = ' || my_ename || ', salary = ' || my_salary);
    ELSE  -- fetch failed, so exit loop
      EXIT;
    END IF;
  END LOOP;
END;
/

If a cursor or cursor variable is not open, referencing it with %FOUND raises the predefined exception INVALID_CURSOR.

%ISOPEN Attribute: Is the Cursor Open?

%ISOPEN returns TRUE if its cursor or cursor variable is open; otherwise, %ISOPEN returns FALSE. Example 6-15 uses %ISOPEN to select an action.

Example 6-15 Using %ISOPEN

DECLARE
   CURSOR c1 IS SELECT last_name, salary FROM employees WHERE ROWNUM < 11;
   the_name employees.last_name%TYPE;
   the_salary employees.salary%TYPE;
BEGIN
   IF c1%ISOPEN = FALSE THEN  -- cursor was not already open
      OPEN c1;
   END IF;
   FETCH c1 INTO the_name, the_salary;
   CLOSE c1;
END;
/

%NOTFOUND Attribute: Has a Fetch Failed?

%NOTFOUND is the logical opposite of %FOUND. %NOTFOUND yields FALSE if the last fetch returned a row, or TRUE if the last fetch failed to return a row. In Example 6-16, you use %NOTFOUND to exit a loop when FETCH fails to return a row.

Example 6-16 Using %NOTFOUND

DECLARE
   CURSOR c1 IS SELECT last_name, salary FROM employees WHERE ROWNUM < 11;
   my_ename employees.last_name%TYPE;
   my_salary employees.salary%TYPE;
BEGIN
  OPEN c1;
  LOOP
    FETCH c1 INTO my_ename, my_salary;
    IF c1%NOTFOUND THEN -- fetch failed, so exit loop
-- Another form of this test is "EXIT WHEN c1%NOTFOUND OR c1%NOTFOUND IS NULL;"
       EXIT;
    ELSE   -- fetch succeeded
      DBMS_OUTPUT.PUT_LINE('Name = ' || my_ename || ', salary = ' || my_salary);
    END IF;
   END LOOP;
END;
/

Before the first fetch, %NOTFOUND returns NULL. If FETCH never executes successfully, the loop is never exited, because the EXIT WHEN statement executes only if its WHEN condition is true. To be safe, you might want to use the following EXIT statement instead:

EXIT WHEN c1%NOTFOUND OR c1%NOTFOUND IS NULL;

If a cursor or cursor variable is not open, referencing it with %NOTFOUND raises an INVALID_CURSOR exception.

%ROWCOUNT Attribute: How Many Rows Fetched So Far?

When its cursor or cursor variable is opened, %ROWCOUNT is zeroed. Before the first fetch, %ROWCOUNT yields 0. Thereafter, it yields the number of rows fetched so far. The number is incremented if the last fetch returned a row. Example 6-17 uses %ROWCOUNT to test if more than ten rows have been fetched.

Example 6-17 Using %ROWCOUNT

DECLARE
   CURSOR c1 IS SELECT last_name FROM employees WHERE ROWNUM < 11;
   name employees.last_name%TYPE;
BEGIN
   OPEN c1;
   LOOP
      FETCH c1 INTO name;
      EXIT WHEN c1%NOTFOUND OR c1%NOTFOUND IS NULL;
      DBMS_OUTPUT.PUT_LINE(c1%ROWCOUNT || '. ' || name);
      IF c1%ROWCOUNT = 5 THEN
         DBMS_OUTPUT.PUT_LINE('--- Fetched 5th record ---');
      END IF;
   END LOOP;
   CLOSE c1;
END;
/

If a cursor or cursor variable is not open, referencing it with %ROWCOUNT raises INVALID_CURSOR.

Table 6-1 shows what each cursor attribute returns before and after you execute an OPEN, FETCH, or CLOSE statement.

Table 6-1 Cursor Attribute Values



%FOUND %ISOPEN %NOTFOUND %ROWCOUNT
OPEN before exception FALSE exception exception

after NULL TRUE NULL 0
First FETCH before NULL TRUE NULL 0

after TRUE TRUE FALSE 1
Next FETCH(es) before TRUE TRUE FALSE 1

after TRUE TRUE FALSE data dependent
Last FETCH before TRUE TRUE FALSE data dependent

after FALSE TRUE TRUE data dependent
CLOSE before FALSE TRUE TRUE data dependent

after exception FALSE exception exception

The following applies to the information in Table 6-1:

  • Referencing %FOUND, %NOTFOUND, or %ROWCOUNT before a cursor is opened or after it is closed raises INVALID_CURSOR.

  • After the first FETCH, if the result set was empty, %FOUND yields FALSE, %NOTFOUND yields TRUE, and %ROWCOUNT yields 0.

Querying Data with PL/SQL

PL/SQL lets you perform queries (SELECT statements in SQL) and access individual fields or entire rows from the result set. In traditional database programming, you process query results using an internal data structure called a cursor. In most situations, PL/SQL can manage the cursor for you, so that code to process query results is straightforward and compact. This section discusses how to process both simple queries where PL/SQL manages everything, and complex queries where you interact with the cursor.

Selecting At Most One Row: SELECT INTO Statement

If you expect a query to only return one row, you can write a regular SQL SELECT statement with an additional INTO clause specifying the PL/SQL variable to hold the result.

If the query might return more than one row, but you do not care about values after the first, you can restrict any result set to a single row by comparing the ROWNUM value. If the query might return no rows at all, use an exception handler to specify any actions to take when no data is found.

If you just want to check whether a condition exists in your data, you might be able to code the query with the COUNT(*) operator, which always returns a number and never raises the NO_DATA_FOUND exception.

Selecting Multiple Rows: BULK COLLECT Clause

If you need to bring a large quantity of data into local PL/SQL variables, rather than looping through a result set one row at a time, you can use the BULK COLLECT clause. When you query only certain columns, you can store all the results for each column in a separate collection variable. When you query all the columns of a table, you can store the entire result set in a collection of records, which makes it convenient to loop through the results and refer to different columns. See Example 6-13, "Fetching Bulk Data With a Cursor".

This technique can be very fast, but also very memory-intensive. If you use it often, you might be able to improve your code by doing more of the work in SQL:

  • If you only need to loop once through the result set, use a FOR loop as described in the following sections. This technique avoids the memory overhead of storing a copy of the result set.

  • If you are looping through the result set to scan for certain values or filter the results into a smaller set, do this scanning or filtering in the original query instead. You can add more WHERE clauses in simple cases, or use set operators such as INTERSECT and MINUS if you are comparing two or more sets of results.

  • If you are looping through the result set and running another query or a DML statement for each result row, you can probably find a more efficient technique. For queries, look at including subqueries or EXISTS or NOT EXISTS clauses in the original query. For DML statements, look at the FORALL statement, which is much faster than coding these statements inside a regular loop.

Looping Through Multiple Rows: Cursor FOR Loop

Perhaps the most common case of a query is one where you issue the SELECT statement, then immediately loop once through the rows of the result set. PL/SQL lets you use a simple FOR loop for this kind of query:

The iterator variable for the FOR loop does not need to be declared in advance. It is a %ROWTYPE record whose field names match the column names from the query, and that exists only during the loop. When you use expressions rather than explicit column names, use column aliases so that you can refer to the corresponding values inside the loop.

Performing Complicated Query Processing: Explicit Cursors

For full control over query processing, you can use explicit cursors in combination with the OPEN, FETCH, and CLOSE statements.

You might want to specify a query in one place but retrieve the rows somewhere else, even in another subprogram. Or you might want to choose very different query parameters, such as ORDER BY or GROUP BY clauses, depending on the situation. Or you might want to process some rows differently than others, and so need more than a simple loop.

Because explicit cursors are so flexible, you can choose from different notations depending on your needs. The following sections describe all the query-processing features that explicit cursors provide.

Querying Data with PL/SQL: Implicit Cursor FOR Loop

With PL/SQL, it is very simple to issue a query, retrieve each row of the result into a %ROWTYPE record, and process each row in a loop:

  • You include the text of the query directly in the FOR loop.

  • PL/SQL creates a record variable with fields corresponding to the columns of the result set.

  • You refer to the fields of this record variable inside the loop. You can perform tests and calculations, display output, or store the results somewhere else.

Here is an example that you can run in SQL*Plus. It does a query to get the name and job Id of employees with manager Ids greater than 120.

BEGIN
  FOR item IN 
  ( SELECT last_name, job_id FROM employees WHERE job_id LIKE '%CLERK%'
       AND manager_id > 120 )
  LOOP
    DBMS_OUTPUT.PUT_LINE('Name = ' || item.last_name || ', Job = ' ||
                          item.job_id);
  END LOOP;
END;
/

Before each iteration of the FOR loop, PL/SQL fetches into the implicitly declared record. The sequence of statements inside the loop is executed once for each row that satisfies the query. When you leave the loop, the cursor is closed automatically. The cursor is closed even if you use an EXIT or GOTO statement to leave the loop before all rows are fetched, or an exception is raised inside the loop. See "LOOP Statements".

Querying Data with PL/SQL: Explicit Cursor FOR Loops

If you need to reference the same query from different parts of the same procedure, you can declare a cursor that specifies the query, and process the results using a FOR loop.

DECLARE 
 CURSOR c1 IS SELECT last_name, job_id FROM employees 
                WHERE job_id LIKE '%CLERK%' AND manager_id > 120;
BEGIN
  FOR item IN c1
  LOOP
    DBMS_OUTPUT.PUT_LINE('Name = ' || item.last_name || ', Job = ' ||
                          item.job_id);
  END LOOP;
END;
/

See also: "LOOP Statements"

Defining Aliases for Expression Values in a Cursor FOR Loop

In a cursor FOR loop, PL/SQL creates a %ROWTYPE record with fields corresponding to columns in the result set. The fields have the same names as corresponding columns in the SELECT list.

The select list might contain an expression, such as a column plus a constant, or two columns concatenated together. If so, use a column alias to give unique names to the appropriate columns.

In Example 6-18, full_name and dream_salary are aliases for expressions in the query:

Example 6-18 Using an Alias For Expressions in a Query

BEGIN
  FOR item IN
  ( SELECT first_name || ' ' || last_name AS full_name,
      salary * 10 AS dream_salary FROM employees WHERE ROWNUM <= 5 )
  LOOP
    DBMS_OUTPUT.PUT_LINE(item.full_name || ' dreams of making ' ||
                         item.dream_salary);
  END LOOP;
END;
/

Using Subqueries

A subquery is a query (usually enclosed by parentheses) that appears within another SQL data manipulation statement. The statement acts upon the single value or set of values returned by the subquery. For example:

Example 6-19 is illustrates two subqueries used in cursor declarations.

Example 6-19 Using a Subquery in a Cursor

DECLARE
  CURSOR c1 IS
-- main query returns only rows where the salary is greater than the average
    SELECT employee_id, last_name FROM employees 
      WHERE salary > (SELECT AVG(salary) FROM employees);
  CURSOR c2 IS
-- subquery returns all the rows in descending order of salary
-- main query returns just the top 10 highest-paid employees
   SELECT * FROM
     (SELECT last_name, salary FROM employees ORDER BY salary DESC, last_name)
     WHERE ROWNUM < 11;
BEGIN
  FOR person IN c1
  LOOP
    DBMS_OUTPUT.PUT_LINE('Above-average salary: ' || person.last_name);
  END LOOP;
  FOR person IN c2
  LOOP
    DBMS_OUTPUT.PUT_LINE('Highest paid: ' || person.last_name || 
                         ' $' || person.salary);
  END LOOP;
-- subquery identifies a set of rows to use with CREATE TABLE or INSERT
END;
/

Using a subquery in the FROM clause, the query in Example 6-20 returns the number and name of each department with five or more employees.

Example 6-20 Using a Subquery in a FROM Clause

DECLARE
  CURSOR c1 IS
    SELECT t1.department_id, department_name, staff
      FROM departments t1,
      ( SELECT department_id, COUNT(*) as staff
          FROM employees GROUP BY department_id) t2
    WHERE
      t1.department_id = t2.department_id
      AND staff >= 5;
BEGIN
   FOR dept IN c1
   LOOP
     DBMS_OUTPUT.PUT_LINE('Department = ' || dept.department_name ||
                          ', staff = ' || dept.staff);
   END LOOP;
END;
/

Using Correlated Subqueries

While a subquery is evaluated only once for each table, a correlated subquery is evaluated once for each row. Example 6-21 returns the name and salary of each employee whose salary exceeds the departmental average. For each row in the table, the correlated subquery computes the average salary for the corresponding department.

Example 6-21 Using a Correlated Subquery

DECLARE
-- For each department, find the average salary. Then find all the employees in
--  that department making more than that average salary.
  CURSOR c1 IS
    SELECT department_id, last_name, salary FROM employees t
    WHERE salary >
      ( SELECT AVG(salary) FROM employees WHERE t.department_id = department_id )
    ORDER BY department_id;
BEGIN
  FOR person IN c1
  LOOP
    DBMS_OUTPUT.PUT_LINE('Making above-average salary = ' || person.last_name);
  END LOOP;
END;
/

Writing Maintainable PL/SQL Queries

Instead of referring to local variables, you can declare a cursor that accepts parameters, and pass values for those parameters when you open the cursor. If the query is usually issued with certain values, you can make those values the defaults. You can use either positional notation or named notation to pass the parameter values.

Example 6-22 displays the wages paid to employees earning over a specified wage in a specified department.

Example 6-22 Passing Parameters to a Cursor FOR Loop

DECLARE
  CURSOR c1 (job VARCHAR2, max_wage NUMBER) IS
    SELECT * FROM employees WHERE job_id = job AND salary > max_wage;
BEGIN
  FOR person IN c1('CLERK', 3000)
  LOOP
     -- process data record
    DBMS_OUTPUT.PUT_LINE('Name = ' || person.last_name || ', salary = ' ||
                         person.salary || ', Job Id = ' || person.job_id );
  END LOOP;
END;
/

In Example 6-23, several ways are shown to open a cursor.

Example 6-23 Passing Parameters to Explicit Cursors

DECLARE
  emp_job      employees.job_id%TYPE := 'ST_CLERK';
  emp_salary   employees.salary%TYPE := 3000;
  my_record employees%ROWTYPE;
  CURSOR c1 (job VARCHAR2, max_wage NUMBER) IS
    SELECT * FROM employees WHERE job_id = job and salary > max_wage;
BEGIN
-- Any of the following statements opens the cursor:
-- OPEN c1('ST_CLERK', 3000); OPEN c1('ST_CLERK', emp_salary);
-- OPEN c1(emp_job, 3000); OPEN c1(emp_job, emp_salary);
  OPEN c1(emp_job, emp_salary);
  LOOP
     FETCH c1 INTO my_record;
     EXIT WHEN c1%NOTFOUND;
     -- process data record
     DBMS_OUTPUT.PUT_LINE('Name = ' || my_record.last_name || ', salary = ' ||
                      my_record.salary || ', Job Id = ' || my_record.job_id );
  END LOOP;
END;
/

To avoid confusion, use different names for cursor parameters and the PL/SQL variables that you pass into those parameters.

Formal parameters declared with a default value do not need a corresponding actual parameter. If you omit them, they assume their default values when the OPEN statement is executed.

Using Cursor Variables (REF CURSORs)

Like a cursor, a cursor variable points to the current row in the result set of a multi-row query. A cursor variable is more flexible because it is not tied to a specific query. You can open a cursor variable for any query that returns the right set of columns.

You pass a cursor variable as a parameter to local and stored subprograms. Opening the cursor variable in one subprogram, and processing it in a different subprogram, helps to centralize data retrieval. This technique is also useful for multi-language applications, where a PL/SQL subprogram might return a result set to a subprogram written in a different language, such as Java or Visual Basic.

Cursor variables are available to every PL/SQL client. For example, you can declare a cursor variable in a PL/SQL host environment such as an OCI or Pro*C program, then pass it as an input host variable (bind variable) to PL/SQL. Application development tools such as Oracle Forms, which have a PL/SQL engine, can use cursor variables entirely on the client side. Or, you can pass cursor variables back and forth between a client and the database server through remote procedure calls.

What Are Cursor Variables (REF CURSORs)?

Cursor variables are like pointers to result sets. You use them when you want to perform a query in one subprogram, and process the results in a different subprogram (possibly one written in a different language). A cursor variable has datatype REF CURSOR, and you might see them referred to informally as REF CURSORs.

Unlike an explicit cursor, which always refers to the same query work area, a cursor variable can refer to different work areas. You cannot use a cursor variable where a cursor is expected, or vice versa.

Why Use Cursor Variables?

You use cursor variables to pass query result sets between PL/SQL stored subprograms and various clients. PL/SQL and its clients share a pointer to the query work area in which the result set is stored. For example, an OCI client, Oracle Forms application, and Oracle database server can all refer to the same work area.

A query work area remains accessible as long as any cursor variable points to it, as you pass the value of a cursor variable from one scope to another. For example, if you pass a host cursor variable to a PL/SQL block embedded in a Pro*C program, the work area to which the cursor variable points remains accessible after the block completes.

If you have a PL/SQL engine on the client side, calls from client to server impose no restrictions. For example, you can declare a cursor variable on the client side, open and fetch from it on the server side, then continue to fetch from it back on the client side. You can also reduce network traffic by having a PL/SQL block open or close several host cursor variables in a single round trip.

Declaring REF CURSOR Types and Cursor Variables

To create cursor variables, you define a REF CURSOR type, then declare cursor variables of that type. You can define REF CURSOR types in any PL/SQL block, subprogram, or package. In the following example, you declare a REF CURSOR type that represents a result set from the DEPARTMENTS table:


DECLARE
  TYPE DeptCurTyp IS REF CURSOR RETURN departments%ROWTYPE;

REF CURSOR types can be strong (with a return type) or weak (with no return type). Strong REF CURSOR types are less error prone because the PL/SQL compiler lets you associate a strongly typed cursor variable only with queries that return the right set of columns. Weak REF CURSOR types are more flexible because the compiler lets you associate a weakly typed cursor variable with any query. Because there is no type checking with a weak REF CURSOR, all such types are interchangeable. Instead of creating a new type, you can use the predefined type SYS_REFCURSOR.

Once you define a REF CURSOR type, you can declare cursor variables of that type in any PL/SQL block or subprogram.

DECLARE
   TYPE empcurtyp IS REF CURSOR RETURN employees%ROWTYPE;  -- strong
   TYPE genericcurtyp IS REF CURSOR;  -- weak
   cursor1 empcurtyp;
   cursor2 genericcurtyp;
   my_cursor SYS_REFCURSOR; -- didn't need to declare a new type
   TYPE deptcurtyp IS REF CURSOR RETURN departments%ROWTYPE;
   dept_cv deptcurtyp;  -- declare cursor variable

To avoid declaring the same REF CURSOR type in each subprogram that uses it, you can put the REF CURSOR declaration in a package spec. You can declare cursor variables of that type in the corresponding package body, or within your own procedure or function.

In the RETURN clause of a REF CURSOR type definition, you can use %ROWTYPE to refer to a strongly typed cursor variable, as shown in Example 6-24.

Example 6-24 Cursor Variable Returning a %ROWTYPE Variable

DECLARE
   TYPE TmpCurTyp IS REF CURSOR RETURN employees%ROWTYPE;
   tmp_cv TmpCurTyp;  -- declare cursor variable
   TYPE EmpCurTyp IS REF CURSOR RETURN tmp_cv%ROWTYPE;
   emp_cv EmpCurTyp;  -- declare cursor variable

You can also use %ROWTYPE to provide the datatype of a record variable, as shown in Example 6-25.

Example 6-25 Using the %ROWTYPE Attribute to Provide the Datatype

DECLARE
   dept_rec departments%ROWTYPE;  -- declare record variable
   TYPE DeptCurTyp IS REF CURSOR RETURN dept_rec%TYPE;
   dept_cv DeptCurTyp;  -- declare cursor variable

Example 6-26 specifies a user-defined RECORD type in the RETURN clause:

Example 6-26 Cursor Variable Returning a Record Type

DECLARE
   TYPE EmpRecTyp IS RECORD (
      employee_id NUMBER,
      last_name VARCHAR2(25),
      salary   NUMBER(8,2));
   TYPE EmpCurTyp IS REF CURSOR RETURN EmpRecTyp;
   emp_cv EmpCurTyp;  -- declare cursor variable

Passing Cursor Variables As Parameters

You can declare cursor variables as the formal parameters of functions and procedures. Example 6-27 defines a REF CURSOR type, then declares a cursor variable of that type as a formal parameter.

Example 6-27 Passing a REF CURSOR as a Parameter

DECLARE
   TYPE empcurtyp IS REF CURSOR RETURN employees%ROWTYPE;
   emp empcurtyp;
-- after result set is built, process all the rows inside a single procedure
--  rather than calling a procedure for each row
   PROCEDURE process_emp_cv (emp_cv IN empcurtyp) IS
      person employees%ROWTYPE;
   BEGIN
      DBMS_OUTPUT.PUT_LINE('-----');
      DBMS_OUTPUT.PUT_LINE('Here are the names from the result set:');
      LOOP
         FETCH emp_cv INTO person;
         EXIT WHEN emp_cv%NOTFOUND;
         DBMS_OUTPUT.PUT_LINE('Name = ' || person.first_name ||
                              ' ' || person.last_name);
      END LOOP;
   END;
BEGIN
-- First find 10 arbitrary employees.
  OPEN emp FOR SELECT * FROM employees WHERE ROWNUM < 11;
  process_emp_cv(emp);
  CLOSE emp;
-- find employees matching a condition.
  OPEN emp FOR SELECT * FROM employees WHERE last_name LIKE 'R%';
  process_emp_cv(emp);
  CLOSE emp;
END;
/

Like all pointers, cursor variables increase the possibility of parameter aliasing. See "Overloading Subprogram Names".

Controlling Cursor Variables: OPEN-FOR, FETCH, and CLOSE

You use three statements to control a cursor variable: OPEN-FOR, FETCH, and CLOSE. First, you OPEN a cursor variable FOR a multi-row query. Then, you FETCH rows from the result set. When all the rows are processed, you CLOSE the cursor variable.

Opening a Cursor Variable

The OPEN-FOR statement associates a cursor variable with a multi-row query, executes the query, and identifies the result set. The cursor variable can be declared directly in PL/SQL, or in a PL/SQL host environment such as an OCI program. For the syntax of the OPEN-FOR statement, see "OPEN-FOR Statement".

The SELECT statement for the query can be coded directly in the statement, or can be a string variable or string literal. When you use a string as the query, it can include placeholders for bind variables, and you specify the corresponding values with a USING clause.

This section discusses the static SQL case, in which select_statement is used. For the dynamic SQL case, in which dynamic_string is used, see "OPEN-FOR Statement".

Unlike cursors, cursor variables take no parameters. Instead, you can pass whole queries (not just parameters) to a cursor variable. The query can reference host variables and PL/SQL variables, parameters, and functions.

Example 6-28 opens a cursor variable. Notice that you can apply cursor attributes (%FOUND, %NOTFOUND, %ISOPEN, and %ROWCOUNT) to a cursor variable.

Example 6-28 Checking If a Cursor Variable is Open

DECLARE
   TYPE empcurtyp IS REF CURSOR RETURN employees%ROWTYPE;
   emp_cv empcurtyp;
BEGIN
   IF NOT emp_cv%ISOPEN THEN  -- open cursor variable
      OPEN emp_cv FOR SELECT * FROM employees;
   END IF;
   CLOSE emp_cv;
END;
/

Other OPEN-FOR statements can open the same cursor variable for different queries. You need not close a cursor variable before reopening it. Note that consecutive OPENs of a static cursor raise the predefined exception CURSOR_ALREADY_OPEN. When you reopen a cursor variable for a different query, the previous query is lost.

Typically, you open a cursor variable by passing it to a stored procedure that declares an IN OUT parameter that is a cursor variable. In Example 6-29 the procedure opens a cursor variable.

Example 6-29 Stored Procedure to Open a Ref Cursor

CREATE PACKAGE emp_data AS
  TYPE empcurtyp IS REF CURSOR RETURN employees%ROWTYPE;
  PROCEDURE open_emp_cv (emp_cv IN OUT empcurtyp);
END emp_data;
/
CREATE PACKAGE BODY emp_data AS
  PROCEDURE open_emp_cv (emp_cv IN OUT EmpCurTyp) IS
  BEGIN
    OPEN emp_cv FOR SELECT * FROM employees;
  END open_emp_cv;
END emp_data;
/

You can also use a standalone stored procedure to open the cursor variable. Define the REF CURSOR type in a package, then reference that type in the parameter declaration for the stored procedure.

To centralize data retrieval, you can group type-compatible queries in a stored procedure. In Example 6-30, the packaged procedure declares a selector as one of its formal parameters. When called, the procedure opens the cursor variable emp_cv for the chosen query.

Example 6-30 Stored Procedure to Open Ref Cursors with Different Queries

CREATE PACKAGE emp_data AS
   TYPE empcurtyp IS REF CURSOR RETURN employees%ROWTYPE;
   PROCEDURE open_emp_cv (emp_cv IN OUT empcurtyp, choice INT);
END emp_data;
/
CREATE PACKAGE BODY emp_data AS
   PROCEDURE open_emp_cv (emp_cv IN OUT empcurtyp, choice INT) IS
   BEGIN
      IF choice = 1 THEN
         OPEN emp_cv FOR SELECT * FROM employees WHERE commission_pct IS NOT NULL;
      ELSIF choice = 2 THEN
         OPEN emp_cv FOR SELECT * FROM employees WHERE salary > 2500;
      ELSIF choice = 3 THEN
         OPEN emp_cv FOR SELECT * FROM employees WHERE department_id = 100;
      END IF;
   END;
END emp_data;
/

For more flexibility, a stored procedure can execute queries with different return types, shown in Example 6-31.

Example 6-31 Cursor Variable with Different Return Types

CREATE PACKAGE admin_data AS
   TYPE gencurtyp IS REF CURSOR;
   PROCEDURE open_cv (generic_cv IN OUT gencurtyp, choice INT);
END admin_data;
/
CREATE PACKAGE BODY admin_data AS
   PROCEDURE open_cv (generic_cv IN OUT gencurtyp, choice INT) IS
   BEGIN
      IF choice = 1 THEN
         OPEN generic_cv FOR SELECT * FROM employees;
      ELSIF choice = 2 THEN
         OPEN generic_cv FOR SELECT * FROM departments;
      ELSIF choice = 3 THEN
         OPEN generic_cv FOR SELECT * FROM jobs;
      END IF;
   END;
END admin_data;
/

Using a Cursor Variable as a Host Variable

You can declare a cursor variable in a PL/SQL host environment such as an OCI or Pro*C program. To use the cursor variable, you must pass it as a host variable to PL/SQL. In the following Pro*C example, you pass a host cursor variable and selector to a PL/SQL block, which opens the cursor variable for the chosen query.


EXEC SQL BEGIN DECLARE SECTION;
  ...
  /* Declare host cursor variable. */
  SQL_CURSOR generic_cv;
  int choice;
EXEC SQL END DECLARE SECTION;
...
/* Initialize host cursor variable. */
EXEC SQL ALLOCATE :generic_cv;
...
/* Pass host cursor variable and selector to PL/SQL block. */
EXEC SQL EXECUTE
BEGIN
  IF :choice = 1 THEN
    OPEN :generic_cv FOR SELECT * FROM employees;
  ELSIF :choice = 2 THEN
    OPEN :generic_cv FOR SELECT * FROM departments;
  ELSIF :choice = 3 THEN
    OPEN :generic_cv FOR SELECT * FROM jobs;
  END IF;
END;
END-EXEC;

Host cursor variables are compatible with any query return type. They behave just like weakly typed PL/SQL cursor variables.

Fetching from a Cursor Variable

The FETCH statement retrieves rows from the result set of a multi-row query. It works the same with cursor variables as with explicit cursors. Example 6-32 fetches rows one at a time from a cursor variable into a record.

Example 6-32 Fetching from a Cursor Variable into a Record

DECLARE
   TYPE empcurtyp IS REF CURSOR RETURN employees%ROWTYPE;
   emp_cv empcurtyp;
   emp_rec employees%ROWTYPE;
BEGIN
   OPEN emp_cv FOR SELECT * FROM employees WHERE employee_id < 120;
   LOOP 
      FETCH emp_cv INTO emp_rec; -- fetch from cursor variable
      EXIT WHEN emp_cv%NOTFOUND; -- exit when last row is fetched
      -- process data record
      DBMS_OUTPUT.PUT_LINE('Name = ' || emp_rec.first_name || ' ' ||
                            emp_rec.last_name);
   END LOOP;
   CLOSE emp_cv;
END;
/

Using the BULK COLLECT clause, you can bulk fetch rows from a cursor variable into one or more collections as shown in Example 6-33.

Example 6-33 Fetching from a Cursor Variable into Collections

DECLARE
   TYPE empcurtyp IS REF CURSOR;
   TYPE namelist IS TABLE OF employees.last_name%TYPE;
   TYPE sallist IS TABLE OF employees.salary%TYPE;
   emp_cv empcurtyp;
   names  namelist;
   sals   sallist;
BEGIN
   OPEN emp_cv FOR SELECT last_name, salary FROM employees 
        WHERE job_id = 'SA_REP';
   FETCH emp_cv BULK COLLECT INTO names, sals;
   CLOSE emp_cv;
-- loop through the names and sals collections
   FOR i IN names.FIRST .. names.LAST
   LOOP
      DBMS_OUTPUT.PUT_LINE('Name = ' || names(i) || ', salary = ' || sals(i));
   END LOOP;
END;
/

Any variables in the associated query are evaluated only when the cursor variable is opened. To change the result set or the values of variables in the query, reopen the cursor variable with the variables set to new values. You can use a different INTO clause on separate fetches with the same cursor variable. Each fetch retrieves another row from the same result set.

PL/SQL makes sure the return type of the cursor variable is compatible with the INTO clause of the FETCH statement. If there is a mismatch, an error occurs at compile time if the cursor variable is strongly typed, or at run time if it is weakly typed. At run time, PL/SQL raises the predefined exception ROWTYPE_MISMATCH before the first fetch. If you trap the error and execute the FETCH statement using a different (compatible) INTO clause, no rows are lost.

When you declare a cursor variable as the formal parameter of a subprogram that fetches from the cursor variable, you must specify the IN or IN OUT mode. If the subprogram also opens the cursor variable, you must specify the IN OUT mode.

If you try to fetch from a closed or never-opened cursor variable, PL/SQL raises the predefined exception INVALID_CURSOR.

Closing a Cursor Variable

The CLOSE statement disables a cursor variable and makes the associated result set undefined. Close the cursor variable after the last row is processed.

When declaring a cursor variable as the formal parameter of a subprogram that closes the cursor variable, you must specify the IN or IN OUT mode. If you try to close an already-closed or never-opened cursor variable, PL/SQL raises the predefined exception INVALID_CURSOR.

Reducing Network Traffic When Passing Host Cursor Variables to PL/SQL

When passing host cursor variables to PL/SQL, you can reduce network traffic by grouping OPEN-FOR statements. For example, the following PL/SQL block opens multiple cursor variables in a single round trip:


/* anonymous PL/SQL block in host environment */
BEGIN
  OPEN :emp_cv FOR SELECT * FROM employees;
  OPEN :dept_cv FOR SELECT * FROM departments;
  OPEN :loc_cv FOR SELECT * FROM locations;
END;
/

This technique might be useful in Oracle Forms, for instance, when you want to populate a multi-block form. When you pass host cursor variables to a PL/SQL block for opening, the query work areas to which they point remain accessible after the block completes, so your OCI or Pro*C program can use these work areas for ordinary cursor operations. For example, you open several such work areas in a single round trip:


BEGIN
  OPEN :c1 FOR SELECT 1 FROM dual;
  OPEN :c2 FOR SELECT 1 FROM dual;
  OPEN :c3 FOR SELECT 1 FROM dual;
END;
/

The cursors assigned to c1, c2, and c3 behave normally, and you can use them for any purpose. When finished, release the cursors as follows:


BEGIN
  CLOSE :c1; CLOSE :c2; CLOSE :c3;
END;
/

Avoiding Errors with Cursor Variables

If both cursor variables involved in an assignment are strongly typed, they must have exactly the same datatype (not just the same return type). If one or both cursor variables are weakly typed, they can have different datatypes.

If you try to fetch from, close, or refer to cursor attributes of a cursor variable that does not point to a query work area, PL/SQL raises the INVALID_CURSOR exception. You can make a cursor variable (or parameter) point to a query work area in two ways:

  • OPEN the cursor variable FOR the query.

  • Assign to the cursor variable the value of an already OPENed host cursor variable or PL/SQL cursor variable.

If you assign an unopened cursor variable to another cursor variable, the second one remains invalid even after you open the first one.

Be careful when passing cursor variables as parameters. At run time, PL/SQL raises ROWTYPE_MISMATCH if the return types of the actual and formal parameters are incompatible.

Restrictions on Cursor Variables

Currently, cursor variables are subject to the following restrictions:

  • You cannot declare cursor variables in a package specification, as illustrated in Example 6-34.

  • If you bind a host cursor variable into PL/SQL from an OCI client, you cannot fetch from it on the server side unless you also open it there on the same server call.

  • You cannot use comparison operators to test cursor variables for equality, inequality, or nullity.

  • Database columns cannot store the values of cursor variables. There is no equivalent type to use in a CREATE TABLE statement.

  • You cannot store cursor variables in an associative array, nested table, or varray.

  • Cursors and cursor variables are not interoperable; that is, you cannot use one where the other is expected. For example, you cannot reference a cursor variable in a cursor FOR loop.

Example 6-34 Declaration of Cursor Variables in a Package

CREATE PACKAGE emp_data AS
  TYPE EmpCurTyp IS REF CURSOR RETURN employees%ROWTYPE;
-- emp_cv EmpCurTyp; -- not allowed
  PROCEDURE open_emp_cv;
END emp_data;
/
CREATE PACKAGE BODY emp_data AS
-- emp_cv EmpCurTyp; -- not allowed
PROCEDURE open_emp_cv IS
  emp_cv EmpCurTyp; -- this is legal
  BEGIN
    OPEN emp_cv FOR SELECT * FROM employees;
  END open_emp_cv;
END emp_data;
/

Note:

  • Using a REF CURSOR variable in a server-to-server RPC results in an error. However, a REF CURSOR variable is permitted in a server-to-server RPC if the remote database is a non-Oracle database accessed through a Procedural Gateway.

  • LOB parameters are not permitted in a server-to-server RPC.

Using Cursor Expressions

A cursor expression returns a nested cursor. Each row in the result set can contain values as usual, plus cursors produced by subqueries involving the other values in the row. A single query can return a large set of related values retrieved from multiple tables. You can process the result set with nested loops that fetch first from the rows of the result set, then from any nested cursors within those rows.

PL/SQL supports queries with cursor expressions as part of cursor declarations, REF CURSOR declarations and ref cursor variables. You can also use cursor expressions in dynamic SQL queries. Here is the syntax:

CURSOR(subquery)

A nested cursor is implicitly opened when the containing row is fetched from the parent cursor. The nested cursor is closed only when:

Restrictions on Cursor Expressions

The following are restrictions on cursor expressions:

  • You cannot use a cursor expression with an implicit cursor.

  • Cursor expressions can appear only:

    • In a SELECT statement that is not nested in any other query expression, except when it is a subquery of the cursor expression itself.

    • As arguments to table functions, in the FROM clause of a SELECT statement.

  • Cursor expressions can appear only in the outermost SELECT list of the query specification.

  • Cursor expressions cannot appear in view declarations.

  • You cannot perform BIND and EXECUTE operations on cursor expressions.

Example of Cursor Expressions

In Example 6-35, we find a specified location ID, and a cursor from which we can fetch all the departments in that location. As we fetch each department's name, we also get another cursor that lets us fetch their associated employee details from another table.

Example 6-35 Using a Cursor Expression

DECLARE
   TYPE emp_cur_typ IS REF CURSOR;
   emp_cur emp_cur_typ;
   dept_name departments.department_name%TYPE;
   emp_name employees.last_name%TYPE;
   CURSOR c1 IS SELECT
      department_name,
-- second item in the result set is another result set,
-- which is represented as a ref cursor and labelled "employees".
      CURSOR
      ( SELECT e.last_name FROM employees e
         WHERE e.department_id = d.department_id) employees
      FROM departments d WHERE department_name like 'A%';
BEGIN
   OPEN c1;
   LOOP
      FETCH c1 INTO dept_name, emp_cur;
      EXIT WHEN c1%NOTFOUND;
      DBMS_OUTPUT.PUT_LINE('Department: ' || dept_name);
-- for each row in the result set, the result set from a subquery is processed
-- the set could be passed to a procedure for processing rather than the loop
      LOOP
         FETCH emp_cur INTO emp_name;
         EXIT WHEN emp_cur%NOTFOUND;
         DBMS_OUTPUT.PUT_LINE('-- Employee: ' || emp_name);
      END LOOP;
   END LOOP;
   CLOSE c1;
END;
/

Constructing REF CURSORs with Cursor Subqueries

You can use cursor subqueries, also know as cursor expressions, to pass sets of rows as parameters to functions. For example, this statement passes a parameter to the StockPivot function consisting of a REF CURSOR that represents the rows returned by the cursor subquery:


SELECT * FROM TABLE(StockPivot(
              CURSOR(SELECT * FROM StockTable)));

Cursor subqueries are often used with table functions, which are explained in "Setting Up Transformations with Pipelined Functions".

Overview of Transaction Processing in PL/SQL

This section explains transaction processing with PL/SQL using SQL COMMIT, SAVEPOINT, and ROLLBACK statements that ensure the consistency of a database. You can include these SQL statements directly in your PL/SQL programs. Transaction processing is an Oracle feature, available through all programming languages, that lets multiple users work on the database concurrently, and ensures that each user sees a consistent version of data and that all changes are applied in the right order.

You usually do not need to write extra code to prevent problems with multiple users accessing data concurrently. Oracle uses locks to control concurrent access to data, and locks only the minimum amount of data necessary, for as little time as possible. You can request locks on tables or rows if you really do need this level of control. You can choose from several modes of locking such as row share and exclusive.

For information on transactions, see Oracle Database Concepts. For information on the SQL COMMIT, SAVEPOINT, and ROLLBACK statements, see the Oracle Database SQL Reference.

Using COMMIT in PL/SQL

The COMMIT statement ends the current transaction, making any changes made during that transaction permanent, and visible to other users. Transactions are not tied to PL/SQL BEGIN-END blocks. A block can contain multiple transactions, and a transaction can span multiple blocks.

Example 6-36 illustrates a transaction that transfers money from one bank account to another. It is important that the money come out of one account, and into the other, at exactly the same moment. Otherwise, a problem partway through might make the money be lost from both accounts or be duplicated in both accounts.

Example 6-36 Using COMMIT With the WRITE Clause

CREATE TABLE accounts (account_id NUMBER(6), balance NUMBER (10,2));
INSERT INTO accounts VALUES (7715, 6350.00); 
INSERT INTO accounts VALUES (7720, 5100.50); 
DECLARE
  transfer NUMBER(8,2) := 250;
BEGIN
  UPDATE accounts SET balance = balance - transfer WHERE account_id = 7715;
  UPDATE accounts SET balance = balance + transfer WHERE account_id = 7720;
  COMMIT COMMENT 'Transfer From 7715 to 7720' WRITE IMMEDIATE NOWAIT;
END;
/

The optional COMMENT clause lets you specify a comment to be associated with a distributed transaction. If a network or machine fails during the commit, the state of the distributed transaction might be unknown or in doubt. In that case, Oracle stores the text specified by COMMENT in the data dictionary along with the transaction ID.

Asynchronous commit provides more control for the user with the WRITE clause. This option specifies the priority with which the redo information generated by the commit operation is written to the redo log.

For more information on using COMMIT, see "Committing Transactions" in Oracle Database Application Developer's Guide - Fundamentals. For information about distributed transactions, see Oracle Database Concepts. See also "COMMIT Statement".

Using ROLLBACK in PL/SQL

The ROLLBACK statement ends the current transaction and undoes any changes made during that transaction. If you make a mistake, such as deleting the wrong row from a table, a rollback restores the original data. If you cannot finish a transaction because an exception is raised or a SQL statement fails, a rollback lets you take corrective action and perhaps start over.

Example 6-37 inserts information about an employee into three different database tables. If an INSERT statement tries to store a duplicate employee number, the predefined exception DUP_VAL_ON_INDEX is raised. To make sure that changes to all three tables are undone, the exception handler executes a ROLLBACK.

Example 6-37 Using ROLLBACK

CREATE TABLE emp_name AS SELECT employee_id, last_name FROM employees;
CREATE UNIQUE INDEX empname_ix ON emp_name (employee_id);
CREATE TABLE emp_sal AS SELECT employee_id, salary FROM employees;
CREATE UNIQUE INDEX empsal_ix ON emp_sal (employee_id);
CREATE TABLE emp_job AS SELECT employee_id, job_id FROM employees;
CREATE UNIQUE INDEX empjobid_ix ON emp_job (employee_id);

DECLARE
   emp_id       NUMBER(6);
   emp_lastname VARCHAR2(25);
   emp_salary   NUMBER(8,2);
   emp_jobid    VARCHAR2(10);
BEGIN
   SELECT employee_id, last_name, salary, job_id INTO emp_id, emp_lastname,
     emp_salary, emp_jobid FROM employees WHERE employee_id = 120;
   INSERT INTO emp_name VALUES (emp_id, emp_lastname);
   INSERT INTO emp_sal VALUES (emp_id, emp_salary);
   INSERT INTO emp_job VALUES (emp_id, emp_jobid);
EXCEPTION
   WHEN DUP_VAL_ON_INDEX THEN
      ROLLBACK;
      DBMS_OUTPUT.PUT_LINE('Inserts have been rolled back');
END;
/

See also "ROLLBACK Statement".

Using SAVEPOINT in PL/SQL

SAVEPOINT names and marks the current point in the processing of a transaction. Savepoints let you roll back part of a transaction instead of the whole transaction. The number of active savepoints for each session is unlimited.

Example 6-38 marks a savepoint before doing an insert. If the INSERT statement tries to store a duplicate value in the employee_id column, the predefined exception DUP_VAL_ON_INDEX is raised. In that case, you roll back to the savepoint, undoing just the insert.

Example 6-38 Using SAVEPOINT With ROLLBACK

CREATE TABLE emp_name AS SELECT employee_id, last_name, salary FROM employees;
CREATE UNIQUE INDEX empname_ix ON emp_name (employee_id);

DECLARE
   emp_id        employees.employee_id%TYPE;
   emp_lastname  employees.last_name%TYPE;
   emp_salary    employees.salary%TYPE;
BEGIN
   SELECT employee_id, last_name, salary INTO emp_id, emp_lastname,
     emp_salary FROM employees WHERE employee_id = 120;
   UPDATE emp_name SET salary = salary * 1.1 WHERE employee_id = emp_id;
   DELETE FROM emp_name WHERE employee_id = 130;
   SAVEPOINT do_insert;
   INSERT INTO emp_name VALUES (emp_id, emp_lastname, emp_salary);
EXCEPTION
   WHEN DUP_VAL_ON_INDEX THEN
      ROLLBACK TO do_insert;
      DBMS_OUTPUT.PUT_LINE('Insert has been rolled back');
END;
/

When you roll back to a savepoint, any savepoints marked after that savepoint are erased. The savepoint to which you roll back is not erased. A simple rollback or commit erases all savepoints.

If you mark a savepoint within a recursive subprogram, new instances of the SAVEPOINT statement are executed at each level in the recursive descent, but you can only roll back to the most recently marked savepoint.

Savepoint names are undeclared identifiers. Reusing a savepoint name within a transaction moves the savepoint from its old position to the current point in the transaction. This means that a rollback to the savepoint affects only the current part of your transaction, as shown in Example 6-39.

Example 6-39 Reusing a SAVEPOINT With ROLLBACK

CREATE TABLE emp_name AS SELECT employee_id, last_name, salary FROM employees;
CREATE UNIQUE INDEX empname_ix ON emp_name (employee_id);

DECLARE
   emp_id        employees.employee_id%TYPE;
   emp_lastname  employees.last_name%TYPE;
   emp_salary    employees.salary%TYPE;
BEGIN
   SELECT employee_id, last_name, salary INTO emp_id, emp_lastname,
     emp_salary FROM employees WHERE employee_id = 120;
   SAVEPOINT my_savepoint;
   UPDATE emp_name SET salary = salary * 1.1 WHERE employee_id = emp_id;
   DELETE FROM emp_name WHERE employee_id = 130;
   SAVEPOINT my_savepoint;  -- move my_savepoint to current poin
   INSERT INTO emp_name VALUES (emp_id, emp_lastname, emp_salary);
EXCEPTION
   WHEN DUP_VAL_ON_INDEX THEN
      ROLLBACK TO my_savepoint;
      DBMS_OUTPUT.PUT_LINE('Transaction rolled back.');
END;
/

See also "SAVEPOINT Statement".

How Oracle Does Implicit Rollbacks

Before executing an INSERT, UPDATE, or DELETE statement, Oracle marks an implicit savepoint (unavailable to you). If the statement fails, Oracle rolls back to the savepoint. Usually, just the failed SQL statement is rolled back, not the whole transaction. If the statement raises an unhandled exception, the host environment determines what is rolled back.

Oracle can also roll back single SQL statements to break deadlocks. Oracle signals an error to one of the participating transactions and rolls back the current statement in that transaction.

Before executing a SQL statement, Oracle must parse it, that is, examine it to make sure it follows syntax rules and refers to valid schema objects. Errors detected while executing a SQL statement cause a rollback, but errors detected while parsing the statement do not.

If you exit a stored subprogram with an unhandled exception, PL/SQL does not assign values to OUT parameters, and does not do any rollback.

Ending Transactions

You should explicitly commit or roll back every transaction. Whether you issue the commit or rollback in your PL/SQL program or from a client program depends on the application logic. If you do not commit or roll back a transaction explicitly, the client environment determines its final state.

For example, in the SQL*Plus environment, if your PL/SQL block does not include a COMMIT or ROLLBACK statement, the final state of your transaction depends on what you do after running the block. If you execute a data definition, data control, or COMMIT statement or if you issue the EXIT, DISCONNECT, or QUIT command, Oracle commits the transaction. If you execute a ROLLBACK statement or abort the SQL*Plus session, Oracle rolls back the transaction.

Setting Transaction Properties with SET TRANSACTION

You use the SET TRANSACTION statement to begin a read-only or read-write transaction, establish an isolation level, or assign your current transaction to a specified rollback segment. Read-only transactions are useful for running multiple queries while other users update the same tables.

During a read-only transaction, all queries refer to the same snapshot of the database, providing a multi-table, multi-query, read-consistent view. Other users can continue to query or update data as usual. A commit or rollback ends the transaction. In Example 6-40 a store manager uses a read-only transaction to gather order totals for the day, the past week, and the past month. The totals are unaffected by other users updating the database during the transaction.

Example 6-40 Using SET TRANSACTION to Begin a Read-only Transaction

DECLARE
   daily_order_total   NUMBER(12,2);
   weekly_order_total  NUMBER(12,2); 
   monthly_order_total NUMBER(12,2);
BEGIN
   COMMIT; -- ends previous transaction
   SET TRANSACTION READ ONLY NAME 'Calculate Order Totals';
   SELECT SUM (order_total) INTO daily_order_total FROM orders
     WHERE order_date = SYSDATE;
   SELECT SUM (order_total) INTO weekly_order_total FROM orders
     WHERE order_date = SYSDATE - 7;
   SELECT SUM (order_total) INTO monthly_order_total FROM orders
     WHERE order_date = SYSDATE - 30;
   COMMIT; -- ends read-only transaction
END;
/

The SET TRANSACTION statement must be the first SQL statement in a read-only transaction and can only appear once in a transaction. If you set a transaction to READ ONLY, subsequent queries see only changes committed before the transaction began. The use of READ ONLY does not affect other users or transactions.

Restrictions on SET TRANSACTION

Only the SELECT INTO, OPEN, FETCH, CLOSE, LOCK TABLE, COMMIT, and ROLLBACK statements are allowed in a read-only transaction. Queries cannot be FOR UPDATE.

Overriding Default Locking

By default, Oracle locks data structures for you automatically, which is a major strength of the Oracle database: different applications can read and write to the same data without harming each other's data or coordinating with each other.

You can request data locks on specific rows or entire tables if you need to override default locking. Explicit locking lets you deny access to data for the duration of a transaction.:

  • With the LOCK TABLE statement, you can explicitly lock entire tables.

  • With the SELECT FOR UPDATE statement, you can explicitly lock specific rows of a table to make sure they do not change after you have read them. That way, you can check which or how many rows will be affected by an UPDATE or DELETE statement before issuing the statement, and no other application can change the rows in the meantime.

Using FOR UPDATE

When you declare a cursor that will be referenced in the CURRENT OF clause of an UPDATE or DELETE statement, you must use the FOR UPDATE clause to acquire exclusive row locks. An example follows:

DECLARE
   CURSOR c1 IS SELECT employee_id, salary FROM employees
      WHERE job_id = 'SA_REP' AND commission_pct > .10
      FOR UPDATE NOWAIT;

The SELECT ... FOR UPDATE statement identifies the rows that will be updated or deleted, then locks each row in the result set. This is useful when you want to base an update on the existing values in a row. In that case, you must make sure the row is not changed by another user before the update.

The optional keyword NOWAIT tells Oracle not to wait if requested rows have been locked by another user. Control is immediately returned to your program so that it can do other work before trying again to acquire the lock. If you omit the keyword NOWAIT, Oracle waits until the rows are available.

All rows are locked when you open the cursor, not as they are fetched. The rows are unlocked when you commit or roll back the transaction. Since the rows are no longer locked, you cannot fetch from a FOR UPDATE cursor after a commit. For a workaround, see "Fetching Across Commits".

When querying multiple tables, you can use the FOR UPDATE clause to confine row locking to particular tables. Rows in a table are locked only if the FOR UPDATE OF clause refers to a column in that table. For example, the following query locks rows in the employees table but not in the departments table:

DECLARE
  CURSOR c1 IS SELECT last_name, department_name FROM employees, departments
    WHERE employees.department_id = departments.department_id 
          AND job_id = 'SA_MAN'
      FOR UPDATE OF salary;

As shown in Example 6-41, you use the CURRENT OF clause in an UPDATE or DELETE statement to refer to the latest row fetched from a cursor.

Example 6-41 Using CURRENT OF to Update the Latest Row Fetched From a Cursor

DECLARE
   my_emp_id NUMBER(6);
   my_job_id VARCHAR2(10);
   my_sal    NUMBER(8,2);
   CURSOR c1 IS SELECT employee_id, job_id, salary FROM employees FOR UPDATE;
BEGIN
   OPEN c1;
   LOOP
      FETCH c1 INTO my_emp_id, my_job_id, my_sal;
      IF my_job_id = 'SA_REP' THEN
        UPDATE employees SET salary = salary * 1.02 WHERE CURRENT OF c1;
      END IF;
      EXIT WHEN c1%NOTFOUND;
   END LOOP;
END;
/

Using LOCK TABLE

You use the LOCK TABLE statement to lock entire database tables in a specified lock mode so that you can share or deny access to them. Row share locks allow concurrent access to a table; they prevent other users from locking the entire table for exclusive use. Table locks are released when your transaction issues a commit or rollback.

LOCK TABLE employees IN ROW SHARE MODE NOWAIT;

The lock mode determines what other locks can be placed on the table. For example, many users can acquire row share locks on a table at the same time, but only one user at a time can acquire an exclusive lock. While one user has an exclusive lock on a table, no other users can insert, delete, or update rows in that table. For more information about lock modes, see Oracle Database Application Developer's Guide - Fundamentals.

A table lock never keeps other users from querying a table, and a query never acquires a table lock. Only if two different transactions try to modify the same row will one transaction wait for the other to complete.

Fetching Across Commits

PL/SQL raises an exception if you try to fetch from a FOR UPDATE cursor after doing a commit. The FOR UPDATE clause locks the rows when you open the cursor, and unlocks them when you commit.

DECLARE
-- if "FOR UPDATE OF salary" is included on following line, an error is raised
   CURSOR c1 IS SELECT * FROM employees;
   emp_rec  employees%ROWTYPE;
BEGIN
   OPEN c1;
   LOOP
     FETCH c1 INTO emp_rec; -- FETCH fails on the second iteration with FOR UPDATE
     EXIT WHEN c1%NOTFOUND;
     IF emp_rec.employee_id = 105 THEN
       UPDATE employees SET salary = salary * 1.05 WHERE employee_id = 105;
     END IF;
     COMMIT;  -- releases locks
   END LOOP;
END;
/

If you want to fetch across commits, use the ROWID pseudocolumn to mimic the CURRENT OF clause. Select the rowid of each row into a UROWID variable, then use the rowid to identify the current row during subsequent updates and deletes.

Example 6-42 Fetching Across COMMITs Using ROWID

DECLARE
   CURSOR c1 IS SELECT last_name, job_id, rowid FROM employees;
   my_lastname   employees.last_name%TYPE;
   my_jobid      employees.job_id%TYPE;
   my_rowid      UROWID;
BEGIN
   OPEN c1;
   LOOP
      FETCH c1 INTO my_lastname, my_jobid, my_rowid;
      EXIT WHEN c1%NOTFOUND;
      UPDATE employees SET salary = salary * 1.02 WHERE rowid = my_rowid;
      -- this mimics WHERE CURRENT OF c1
      COMMIT;
   END LOOP;
   CLOSE c1;
END;
/

Because the fetched rows are not locked by a FOR UPDATE clause, other users might unintentionally overwrite your changes. The extra space needed for read consistency is not released until the cursor is closed, which can slow down processing for large updates.

The next example shows that you can use the %ROWTYPE attribute with cursors that reference the ROWID pseudocolumn:

DECLARE
   CURSOR c1 IS SELECT employee_id, last_name, salary, rowid FROM employees;
   emp_rec c1%ROWTYPE;
BEGIN
   OPEN c1;
   LOOP
      FETCH c1 INTO emp_rec;
      EXIT WHEN c1%NOTFOUND;
      IF emp_rec.salary = 0 THEN
         DELETE FROM employees WHERE rowid = emp_rec.rowid;
      END IF;
   END LOOP;
   CLOSE c1;
END;
/

Doing Independent Units of Work with Autonomous Transactions

An autonomous transaction is an independent transaction started by another transaction, the main transaction. Autonomous transactions do SQL operations and commit or roll back, without committing or rolling back the main transaction. For example, if you write auditing data to a log table, you want to commit the audit data even if the operation you are auditing later fails; if something goes wrong recording the audit data, you do not want the main operation to be rolled back.

Figure 6-1 shows how control flows from the main transaction (MT) to an autonomous transaction (AT) and back again.

Figure 6-1 Transaction Control Flow

Description of lnpls028.gif follows
Description of the illustration lnpls028.gif

Advantages of Autonomous Transactions

Once started, an autonomous transaction is fully independent. It shares no locks, resources, or commit-dependencies with the main transaction. You can log events, increment retry counters, and so on, even if the main transaction rolls back.

More important, autonomous transactions help you build modular, reusable software components. You can encapsulate autonomous transactions within stored procedures. A calling application does not need to know whether operations done by that stored procedure succeeded or failed.

Defining Autonomous Transactions

To define autonomous transactions, you use the pragma (compiler directive) AUTONOMOUS_TRANSACTION. The pragma instructs the PL/SQL compiler to mark a routine as autonomous (independent). In this context, the term routine includes

  • Top-level (not nested) anonymous PL/SQL blocks

  • Local, standalone, and packaged functions and procedures

  • Methods of a SQL object type

  • Database triggers

You can code the pragma anywhere in the declarative section of a routine. But, for readability, code the pragma at the top of the section. The syntax is PRAGMA AUTONOMOUS_TRANSACTION.

Example 6-43 marks a packaged function as autonomous. You cannot use the pragma to mark all subprograms in a package (or all methods in an object type) as autonomous. Only individual routines can be marked autonomous.

Example 6-43 Declaring an Autonomous Function in a Package

CREATE OR REPLACE PACKAGE emp_actions AS  -- package specification
   FUNCTION raise_salary (emp_id NUMBER, sal_raise NUMBER) RETURN NUMBER;
END emp_actions;
/
CREATE OR REPLACE PACKAGE BODY emp_actions AS  -- package body
-- code for function raise_salary
   FUNCTION raise_salary (emp_id NUMBER, sal_raise NUMBER) RETURN NUMBER IS
     PRAGMA AUTONOMOUS_TRANSACTION;
     new_sal NUMBER(8,2);
   BEGIN
     UPDATE employees SET salary = salary + sal_raise WHERE employee_id = emp_id;
     COMMIT;
     SELECT salary INTO new_sal FROM employees WHERE employee_id = emp_id;
     RETURN new_sal;
   END raise_salary;
END emp_actions;
/

Example 6-44 marks a standalone procedure as autonomous.

Example 6-44 Declaring an Autonomous Standalone Procedure

CREATE PROCEDURE lower_salary (emp_id NUMBER, amount NUMBER) AS
  PRAGMA AUTONOMOUS_TRANSACTION;
BEGIN
  UPDATE employees SET salary = salary - amount WHERE employee_id = emp_id;
  COMMIT;
END lower_salary;
/

Example 6-45 marks a PL/SQL block as autonomous. However, you cannot mark a nested PL/SQL block as autonomous.

Example 6-45 Declaring an Autonomous PL/SQL Block

DECLARE
  PRAGMA AUTONOMOUS_TRANSACTION;
  emp_id NUMBER(6);
  amount NUMBER(6,2);
BEGIN
  emp_id := 200;
  amount := 200;
  UPDATE employees SET salary = salary - amount WHERE employee_id = emp_id;
  COMMIT;
END;
/

Example 6-46 marks a database trigger as autonomous. Unlike regular triggers, autonomous triggers can contain transaction control statements such as COMMIT and ROLLBACK.

Example 6-46 Declaring an Autonomous Trigger

CREATE TABLE emp_audit ( emp_audit_id NUMBER(6), up_date DATE, 
                         new_sal NUMBER(8,2), old_sal NUMBER(8,2) );

CREATE OR REPLACE TRIGGER audit_sal
   AFTER UPDATE OF salary ON employees FOR EACH ROW
DECLARE 
   PRAGMA AUTONOMOUS_TRANSACTION;
BEGIN
-- bind variables are used here for values
   INSERT INTO emp_audit VALUES( :old.employee_id, SYSDATE, 
                                 :new.salary, :old.salary );
  COMMIT;
END;
/

Comparison of Autonomous Transactions and Nested Transactions

Although an autonomous transaction is started by another transaction, it is not a nested transaction:

  • It does not share transactional resources (such as locks) with the main transaction.

  • It does not depend on the main transaction. For example, if the main transaction rolls back, nested transactions roll back, but autonomous transactions do not.

  • Its committed changes are visible to other transactions immediately. (A nested transaction's committed changes are not visible to other transactions until the main transaction commits.)

  • Exceptions raised in an autonomous transaction cause a transaction-level rollback, not a statement-level rollback.

Transaction Context

The main transaction shares its context with nested routines, but not with autonomous transactions. When one autonomous routine calls another (or itself recursively), the routines share no transaction context. When an autonomous routine calls a non-autonomous routine, the routines share the same transaction context.

Transaction Visibility

Changes made by an autonomous transaction become visible to other transactions when the autonomous transaction commits. These changes become visible to the main transaction when it resumes, if its isolation level is set to READ COMMITTED (the default).

If you set the isolation level of the main transaction to SERIALIZABLE, changes made by its autonomous transactions are not visible to the main transaction when it resumes:

SET TRANSACTION ISOLATION LEVEL SERIALIZABLE;

Controlling Autonomous Transactions

The first SQL statement in an autonomous routine begins a transaction. When one transaction ends, the next SQL statement begins another transaction. All SQL statements executed since the last commit or rollback make up the current transaction. To control autonomous transactions, use the following statements, which apply only to the current (active) transaction:

  • COMMIT

  • ROLLBACK [TO savepoint_name]

  • SAVEPOINT savepoint_name

  • SET TRANSACTION

Note:

  • Transaction properties set in the main transaction apply only to that transaction, not to its autonomous transactions, and vice versa.

  • Cursor attributes are not affected by autonomous transactions.

Entering and Exiting

When you enter the executable section of an autonomous routine, the main transaction suspends. When you exit the routine, the main transaction resumes.

To exit normally, you must explicitly commit or roll back all autonomous transactions. If the routine (or any routine called by it) has pending transactions, an exception is raised, and the pending transactions are rolled back.

Committing and Rolling Back

COMMIT and ROLLBACK end the active autonomous transaction but do not exit the autonomous routine. When one transaction ends, the next SQL statement begins another transaction. A single autonomous routine could contain several autonomous transactions, if it issued several COMMIT statements.

Using Savepoints

The scope of a savepoint is the transaction in which it is defined. Savepoints defined in the main transaction are unrelated to savepoints defined in its autonomous transactions. In fact, the main transaction and an autonomous transaction can use the same savepoint names.

You can roll back only to savepoints marked in the current transaction. In an autonomous transaction, you cannot roll back to a savepoint marked in the main transaction. To do so, you must resume the main transaction by exiting the autonomous routine.

When in the main transaction, rolling back to a savepoint marked before you started an autonomous transaction does not roll back the autonomous transaction. Remember, autonomous transactions are fully independent of the main transaction.

Avoiding Errors with Autonomous Transactions

To avoid some common errors, keep the following points in mind:

  • If an autonomous transaction attempts to access a resource held by the main transaction, a deadlock can occur. Oracle raises an exception in the autonomous transaction, which is rolled back if the exception goes unhandled.

  • The Oracle initialization parameter TRANSACTIONS specifies the maximum number of concurrent transactions. That number might be exceeded because an autonomous transaction runs concurrently with the main transaction.

  • If you try to exit an active autonomous transaction without committing or rolling back, Oracle raises an exception. If the exception goes unhandled, the transaction is rolled back.

Using Autonomous Triggers

Among other things, you can use database triggers to log events transparently. Suppose you want to track all inserts into a table, even those that roll back. In Example 6-47, you use a trigger to insert duplicate rows into a shadow table. Because it is autonomous, the trigger can commit changes to the shadow table whether or not you commit changes to the main table.

Example 6-47 Using Autonomous Triggers

CREATE TABLE emp_audit ( emp_audit_id NUMBER(6), up_date DATE,
                         new_sal NUMBER(8,2), old_sal NUMBER(8,2) );

-- create an autonomous trigger that inserts into the audit table before
-- each update of salary in the employees table
CREATE OR REPLACE TRIGGER audit_sal
   BEFORE UPDATE OF salary ON employees FOR EACH ROW
DECLARE 
   PRAGMA AUTONOMOUS_TRANSACTION;
BEGIN
  INSERT INTO emp_audit VALUES( :old.employee_id, SYSDATE, 
                                :new.salary, :old.salary );
  COMMIT;
END;
/
-- update the salary of an employee, and then commit the insert
UPDATE employees SET salary = salary * 1.05 WHERE employee_id = 115;
COMMIT;

-- update another salary, then roll back the update
UPDATE employees SET salary = salary * 1.05 WHERE employee_id = 116;
ROLLBACK;

-- show that both committed and rolled-back updates add rows to audit table
SELECT * FROM emp_audit WHERE emp_audit_id = 115 OR emp_audit_id = 116;

Unlike regular triggers, autonomous triggers can execute DDL statements using native dynamic SQL, discussed in Chapter 7, "Performing SQL Operations with Native Dynamic SQL". In the following example, trigger drop_temp_table drops a temporary database table after a row is inserted in table emp_audit.

CREATE TABLE emp_audit ( emp_audit_id NUMBER(6), up_date DATE,
                         new_sal NUMBER(8,2), old_sal NUMBER(8,2) );
CREATE TABLE temp_audit ( emp_audit_id NUMBER(6), up_date DATE);

CREATE OR REPLACE TRIGGER drop_temp_table
   AFTER INSERT ON emp_audit
DECLARE 
   PRAGMA AUTONOMOUS_TRANSACTION;
BEGIN
   EXECUTE IMMEDIATE 'DROP TABLE temp_audit';
   COMMIT;
END;
/

For more information about database triggers, see Oracle Database Application Developer's Guide - Fundamentals.

Calling Autonomous Functions from SQL

A function called from SQL statements must obey certain rules meant to control side effects. See "Controlling Side Effects of PL/SQL Subprograms". To check for violations of the rules, you can use the pragma RESTRICT_REFERENCES. The pragma asserts that a function does not read or write database tables or package variables. For more information, See Oracle Database Application Developer's Guide - Fundamentals.

However, by definition, autonomous routines never violate the rules read no database state (RNDS) and write no database state (WNDS) no matter what they do. This can be useful, as Example 6-48 shows. When you call the packaged function log_msg from a query, it inserts a message into database table debug_output without violating the rule write no database state.

Example 6-48 Calling an Autonomous Function

-- create the debug table
CREATE TABLE debug_output (msg VARCHAR2(200));

-- create the package spec
CREATE PACKAGE debugging AS
   FUNCTION log_msg (msg VARCHAR2) RETURN VARCHAR2;
   PRAGMA RESTRICT_REFERENCES(log_msg, WNDS, RNDS);
END debugging;
/
-- create the package body
CREATE PACKAGE BODY debugging AS
   FUNCTION log_msg (msg VARCHAR2) RETURN VARCHAR2 IS
      PRAGMA AUTONOMOUS_TRANSACTION;
   BEGIN
      -- the following insert does not violate the constraint
      -- WNDS because this is an autonomous routine
      INSERT INTO debug_output VALUES (msg);
      COMMIT;
      RETURN msg;
   END;
END debugging;
/
-- call the packaged function from a query
DECLARE
   my_emp_id    NUMBER(6);
   my_last_name VARCHAR2(25);
   my_count     NUMBER;
BEGIN
   my_emp_id := 120;
   SELECT debugging.log_msg(last_name) INTO my_last_name FROM employees
      WHERE employee_id = my_emp_id;
-- even if you roll back in this scope, the insert into 'debug_output' remains
-- committed because it is part of an autonomous transaction
   ROLLBACK;
END;
/