Oracle® Database PL/SQL User's Guide and Reference 10g Release 2 (10.2) Part Number B14261-01 |
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Run-time errors arise from design faults, coding mistakes, hardware failures, and many other sources. Although you cannot anticipate all possible errors, you can plan to handle certain kinds of errors meaningful to your PL/SQL program.
With many programming languages, unless you disable error checking, a run-time error such as stack overflow or division by zero stops normal processing and returns control to the operating system. With PL/SQL, a mechanism called exception handling lets you bulletproof your program so that it can continue operating in the presence of errors.
This chapter contains these topics:
In PL/SQL, an error condition is called an exception. Exceptions can be internally defined (by the runtime system) or user defined. Examples of internally defined exceptions include division by zero
and out of memory
. Some common internal exceptions have predefined names, such as ZERO_DIVIDE
and STORAGE_ERROR
. The other internal exceptions can be given names.
You can define exceptions of your own in the declarative part of any PL/SQL block, subprogram, or package. For example, you might define an exception named insufficient_funds
to flag overdrawn bank accounts. Unlike internal exceptions, user-defined exceptions must be given names.
When an error occurs, an exception is raised. That is, normal execution stops and control transfers to the exception-handling part of your PL/SQL block or subprogram. Internal exceptions are raised implicitly (automatically) by the run-time system. User-defined exceptions must be raised explicitly by RAISE
statements, which can also raise predefined exceptions.
To handle raised exceptions, you write separate routines called exception handlers. After an exception handler runs, the current block stops executing and the enclosing block resumes with the next statement. If there is no enclosing block, control returns to the host environment. For information on managing errors when using BULK
COLLECT
, see "Handling FORALL Exceptions with the %BULK_EXCEPTIONS Attribute".
Example 10-1 calculates a price-to-earnings ratio for a company. If the company has zero earnings, the division operation raises the predefined exception ZERO_DIVIDE
, the execution of the block is interrupted, and control is transferred to the exception handlers. The optional OTHERS
handler catches all exceptions that the block does not name specifically.
Example 10-1 Runtime Error Handling
DECLARE stock_price NUMBER := 9.73; net_earnings NUMBER := 0; pe_ratio NUMBER; BEGIN -- Calculation might cause division-by-zero error. pe_ratio := stock_price / net_earnings; DBMS_OUTPUT.PUT_LINE('Price/earnings ratio = ' || pe_ratio); EXCEPTION -- exception handlers begin -- Only one of the WHEN blocks is executed. WHEN ZERO_DIVIDE THEN -- handles 'division by zero' error DBMS_OUTPUT.PUT_LINE('Company must have had zero earnings.'); pe_ratio := NULL; WHEN OTHERS THEN -- handles all other errors DBMS_OUTPUT.PUT_LINE('Some other kind of error occurred.'); pe_ratio := NULL; END; -- exception handlers and block end here /
The last example illustrates exception handling. With some better error checking, we could have avoided the exception entirely, by substituting a null for the answer if the denominator was zero, as shown in the following example.
DECLARE stock_price NUMBER := 9.73; net_earnings NUMBER := 0; pe_ratio NUMBER; BEGIN pe_ratio := CASE net_earnings WHEN 0 THEN NULL ELSE stock_price / net_earnings end; END; /
Because reliability is crucial for database programs, use both error checking and exception handling to ensure your program can handle all possibilities:
Add exception handlers whenever there is any possibility of an error occurring. Errors are especially likely during arithmetic calculations, string manipulation, and database operations. Errors could also occur at other times, for example if a hardware failure with disk storage or memory causes a problem that has nothing to do with your code; but your code still needs to take corrective action.
Add error-checking code whenever you can predict that an error might occur if your code gets bad input data. Expect that at some time, your code will be passed incorrect or null parameters, that your queries will return no rows or more rows than you expect.
Make your programs robust enough to work even if the database is not in the state you expect. For example, perhaps a table you query will have columns added or deleted, or their types changed. You can avoid such problems by declaring individual variables with %TYPE
qualifiers, and declaring records to hold query results with %ROWTYPE
qualifiers.
Handle named exceptions whenever possible, instead of using WHEN OTHERS in exception handlers. Learn the names and causes of the predefined exceptions. If your database operations might cause particular ORA- errors, associate names with these errors so you can write handlers for them. (You will learn how to do that later in this chapter.)
Test your code with different combinations of bad data to see what potential errors arise.
Write out debugging information in your exception handlers. You might store such information in a separate table. If so, do it by making a call to a procedure declared with the PRAGMA AUTONOMOUS_TRANSACTION
, so that you can commit your debugging information, even if you roll back the work that the main procedure was doing.
Carefully consider whether each exception handler should commit the transaction, roll it back, or let it continue. Remember, no matter how severe the error is, you want to leave the database in a consistent state and avoid storing any bad data.
Using exceptions for error handling has several advantages. With exceptions, you can reliably handle potential errors from many statements with a single exception handler:
Example 10-2 Managing Multiple Errors With a Single Exception Handler
DECLARE emp_column VARCHAR2(30) := 'last_name'; table_name VARCHAR2(30) := 'emp'; temp_var VARCHAR2(30); BEGIN temp_var := emp_column; SELECT COLUMN_NAME INTO temp_var FROM USER_TAB_COLS WHERE TABLE_NAME = 'EMPLOYEES' AND COLUMN_NAME = UPPER(emp_column); -- processing here temp_var := table_name; SELECT OBJECT_NAME INTO temp_var FROM USER_OBJECTS WHERE OBJECT_NAME = UPPER(table_name) AND OBJECT_TYPE = 'TABLE'; -- processing here EXCEPTION WHEN NO_DATA_FOUND THEN -- catches all 'no data found' errors DBMS_OUTPUT.PUT_LINE ('No Data found for SELECT on ' || temp_var); END; /
Instead of checking for an error at every point it might occur, just add an exception handler to your PL/SQL block. If the exception is ever raised in that block (or any sub-block), you can be sure it will be handled.
Sometimes the error is not immediately obvious, and could not be detected until later when you perform calculations using bad data. Again, a single exception handler can trap all division-by-zero errors, bad array subscripts, and so on.
If you need to check for errors at a specific spot, you can enclose a single statement or a group of statements inside its own BEGIN-END
block with its own exception handler. You can make the checking as general or as precise as you like.
Isolating error-handling routines makes the rest of the program easier to read and understand.
An internal exception is raised automatically if your PL/SQL program violates an Oracle rule or exceeds a system-dependent limit. PL/SQL predefines some common Oracle errors as exceptions. For example, PL/SQL raises the predefined exception NO_DATA_FOUND
if a SELECT
INTO
statement returns no rows.
You can use the pragma EXCEPTION_INIT
to associate exception names with other Oracle error codes that you can anticipate. To handle unexpected Oracle errors, you can use the OTHERS
handler. Within this handler, you can call the functions SQLCODE
and SQLERRM
to return the Oracle error code and message text. Once you know the error code, you can use it with pragma EXCEPTION_INIT
and write a handler specifically for that error.
PL/SQL declares predefined exceptions globally in package STANDARD
. You need not declare them yourself. You can write handlers for predefined exceptions using the names in the following table:
PL/SQL lets you define exceptions of your own. Unlike predefined exceptions, user-defined exceptions must be declared and must be raised explicitly by RAISE
statements.
Exceptions can be declared only in the declarative part of a PL/SQL block, subprogram, or package. You declare an exception by introducing its name, followed by the keyword EXCEPTION
. In the following example, you declare an exception named past_due
:
DECLARE past_due EXCEPTION;
Exception and variable declarations are similar. But remember, an exception is an error condition, not a data item. Unlike variables, exceptions cannot appear in assignment statements or SQL statements. However, the same scope rules apply to variables and exceptions.
You cannot declare an exception twice in the same block. You can, however, declare the same exception in two different blocks.
Exceptions declared in a block are considered local to that block and global to all its sub-blocks. Because a block can reference only local or global exceptions, enclosing blocks cannot reference exceptions declared in a sub-block.
If you redeclare a global exception in a sub-block, the local declaration prevails. The sub-block cannot reference the global exception, unless the exception is declared in a labeled block and you qualify its name with the block label:
block_label.exception_name
Example 10-3 illustrates the scope rules:
Example 10-3 Scope of PL/SQL Exceptions
DECLARE past_due EXCEPTION; acct_num NUMBER; BEGIN DECLARE ---------- sub-block begins past_due EXCEPTION; -- this declaration prevails acct_num NUMBER; due_date DATE := SYSDATE - 1; todays_date DATE := SYSDATE; BEGIN IF due_date < todays_date THEN RAISE past_due; -- this is not handled END IF; END; ------------- sub-block ends EXCEPTION WHEN past_due THEN -- does not handle raised exception DBMS_OUTPUT.PUT_LINE('Handling PAST_DUE exception.'); WHEN OTHERS THEN DBMS_OUTPUT.PUT_LINE('Could not recognize PAST_DUE_EXCEPTION in this scope.'); END; /
The enclosing block does not handle the raised exception because the declaration of past_due
in the sub-block prevails. Though they share the same name, the two past_due
exceptions are different, just as the two acct_num
variables share the same name but are different variables. Thus, the RAISE
statement and the WHEN
clause refer to different exceptions. To have the enclosing block handle the raised exception, you must remove its declaration from the sub-block or define an OTHERS
handler.
To handle error conditions (typically ORA-
messages) that have no predefined name, you must use the OTHERS
handler or the pragma EXCEPTION_INIT
. A pragma is a compiler directive that is processed at compile time, not at run time.
In PL/SQL, the pragma EXCEPTION_INIT
tells the compiler to associate an exception name with an Oracle error number. That lets you refer to any internal exception by name and to write a specific handler for it. When you see an error stack, or sequence of error messages, the one on top is the one that you can trap and handle.
You code the pragma EXCEPTION_INIT
in the declarative part of a PL/SQL block, subprogram, or package using the syntax
PRAGMA EXCEPTION_INIT(exception_name, -Oracle_error_number);
where exception_name
is the name of a previously declared exception and the number is a negative value corresponding to an ORA-
error number. The pragma must appear somewhere after the exception declaration in the same declarative section, as shown in Example 10-4.
The procedure RAISE_APPLICATION_ERROR
lets you issue user-defined ORA-
error messages from stored subprograms. That way, you can report errors to your application and avoid returning unhandled exceptions.
To call RAISE_APPLICATION_ERROR
, use the syntax
raise_application_error(
error_number, message[, {TRUE | FALSE}]);
where error_number
is a negative integer in the range -20000 .. -20999 and message
is a character string up to 2048 bytes long. If the optional third parameter is TRUE
, the error is placed on the stack of previous errors. If the parameter is FALSE
(the default), the error replaces all previous errors. RAISE_APPLICATION_ERROR
is part of package DBMS_STANDARD
, and as with package STANDARD
, you do not need to qualify references to it.
An application can call raise_application_error
only from an executing stored subprogram (or method). When called, raise_application_error
ends the subprogram and returns a user-defined error number and message to the application. The error number and message can be trapped like any Oracle error.
In Example 10-5, you call raise_application_error
if an error condition of your choosing happens (in this case, if the current schema owns less than 1000 tables):
Example 10-5 Raising an Application Error With raise_application_error
DECLARE num_tables NUMBER; BEGIN SELECT COUNT(*) INTO num_tables FROM USER_TABLES; IF num_tables < 1000 THEN /* Issue your own error code (ORA-20101) with your own error message. Note that you do not need to qualify raise_application_error with DBMS_STANDARD */ raise_application_error(-20101, 'Expecting at least 1000 tables'); ELSE NULL; -- Do the rest of the processing (for the non-error case). END IF; END; /
The calling application gets a PL/SQL exception, which it can process using the error-reporting functions SQLCODE
and SQLERRM
in an OTHERS
handler. Also, it can use the pragma EXCEPTION_INIT
to map specific error numbers returned by raise_application_error
to exceptions of its own, as the following Pro*C example shows:
EXEC SQL EXECUTE
/* Execute embedded PL/SQL block using host
variables v_emp_id and v_amount, which were
assigned values in the host environment. */
DECLARE
null_salary EXCEPTION;
/* Map error number returned by raise_application_error
to user-defined exception. */
PRAGMA EXCEPTION_INIT(null_salary, -20101);
BEGIN
raise_salary(:v_emp_id, :v_amount);
EXCEPTION
WHEN null_salary THEN
INSERT INTO emp_audit VALUES (:v_emp_id, ...);
END;
END-EXEC;
This technique allows the calling application to handle error conditions in specific exception handlers.
Remember, PL/SQL declares predefined exceptions globally in package STANDARD
, so you need not declare them yourself. Redeclaring predefined exceptions is error prone because your local declaration overrides the global declaration. For example, if you declare an exception named invalid_number
and then PL/SQL raises the predefined exception INVALID_NUMBER
internally, a handler written for INVALID_NUMBER
will not catch the internal exception. In such cases, you must use dot notation to specify the predefined exception, as follows:
EXCEPTION
WHEN invalid_number OR STANDARD.INVALID_NUMBER THEN
-- handle the error
END;
Internal exceptions are raised implicitly by the run-time system, as are user-defined exceptions that you have associated with an Oracle error number using EXCEPTION_INIT
. However, other user-defined exceptions must be raised explicitly by RAISE
statements.
PL/SQL blocks and subprograms should raise an exception only when an error makes it undesirable or impossible to finish processing. You can place RAISE
statements for a given exception anywhere within the scope of that exception. In Example 10-6, you alert your PL/SQL block to a user-defined exception named out_of_stock
.
Example 10-6 Using RAISE to Force a User-Defined Exception
DECLARE out_of_stock EXCEPTION; number_on_hand NUMBER := 0; BEGIN IF number_on_hand < 1 THEN RAISE out_of_stock; -- raise an exception that we defined END IF; EXCEPTION WHEN out_of_stock THEN -- handle the error DBMS_OUTPUT.PUT_LINE('Encountered out-of-stock error.'); END; /
You can also raise a predefined exception explicitly. That way, an exception handler written for the predefined exception can process other errors, as Example 10-7 shows:
Example 10-7 Using RAISE to Force a Pre-Defined Exception
DECLARE acct_type INTEGER := 7; BEGIN IF acct_type NOT IN (1, 2, 3) THEN RAISE INVALID_NUMBER; -- raise predefined exception END IF; EXCEPTION WHEN INVALID_NUMBER THEN DBMS_OUTPUT.PUT_LINE('HANDLING INVALID INPUT BY ROLLING BACK.'); ROLLBACK; END; /
When an exception is raised, if PL/SQL cannot find a handler for it in the current block or subprogram, the exception propagates. That is, the exception reproduces itself in successive enclosing blocks until a handler is found or there are no more blocks to search. If no handler is found, PL/SQL returns an unhandled exception error to the host environment.
Exceptions cannot propagate across remote procedure calls done through database links. A PL/SQL block cannot catch an exception raised by a remote subprogram. For a workaround, see "Defining Your Own Error Messages: Procedure RAISE_APPLICATION_ERROR".
Figure 10-1, Figure 10-2, and Figure 10-3 illustrate the basic propagation rules.
An exception can propagate beyond its scope, that is, beyond the block in which it was declared, as shown in Example 10-8.
Example 10-8 Scope of an Exception
BEGIN DECLARE ---------- sub-block begins past_due EXCEPTION; due_date DATE := trunc(SYSDATE) - 1; todays_date DATE := trunc(SYSDATE); BEGIN IF due_date < todays_date THEN RAISE past_due; END IF; END; ------------- sub-block ends EXCEPTION WHEN OTHERS THEN ROLLBACK; END; /
Because the block that declares the exception past_due
has no handler for it, the exception propagates to the enclosing block. But the enclosing block cannot reference the name PAST_DUE
, because the scope where it was declared no longer exists. Once the exception name is lost, only an OTHERS
handler can catch the exception. If there is no handler for a user-defined exception, the calling application gets this error:
ORA-06510: PL/SQL: unhandled user-defined exception
Sometimes, you want to reraise an exception, that is, handle it locally, then pass it to an enclosing block. For example, you might want to roll back a transaction in the current block, then log the error in an enclosing block.
To reraise an exception, use a RAISE
statement without an exception name, which is allowed only in an exception handler:
Example 10-9 Reraising a PL/SQL Exception
DECLARE salary_too_high EXCEPTION; current_salary NUMBER := 20000; max_salary NUMBER := 10000; erroneous_salary NUMBER; BEGIN BEGIN ---------- sub-block begins IF current_salary > max_salary THEN RAISE salary_too_high; -- raise the exception END IF; EXCEPTION WHEN salary_too_high THEN -- first step in handling the error DBMS_OUTPUT.PUT_LINE('Salary ' || erroneous_salary || ' is out of range.'); DBMS_OUTPUT.PUT_LINE('Maximum salary is ' || max_salary || '.'); RAISE; -- reraise the current exception END; ------------ sub-block ends EXCEPTION WHEN salary_too_high THEN -- handle the error more thoroughly erroneous_salary := current_salary; current_salary := max_salary; DBMS_OUTPUT.PUT_LINE('Revising salary from ' || erroneous_salary || ' to ' || current_salary || '.'); END; /
When an exception is raised, normal execution of your PL/SQL block or subprogram stops and control transfers to its exception-handling part, which is formatted as follows:
EXCEPTION
WHEN exception1 THEN -- handler for exception1
sequence_of_statements1
WHEN exception2 THEN -- another handler for exception2
sequence_of_statements2
...
WHEN OTHERS THEN -- optional handler for all other errors
sequence_of_statements3
END;
To catch raised exceptions, you write exception handlers. Each handler consists of a WHEN
clause, which specifies an exception, followed by a sequence of statements to be executed when that exception is raised. These statements complete execution of the block or subprogram; control does not return to where the exception was raised. In other words, you cannot resume processing where you left off.
The optional OTHERS
exception handler, which is always the last handler in a block or subprogram, acts as the handler for all exceptions not named specifically. Thus, a block or subprogram can have only one OTHERS
handler. Use of the OTHERS
handler guarantees that no exception will go unhandled.
If you want two or more exceptions to execute the same sequence of statements, list the exception names in the WHEN
clause, separating them by the keyword OR
, as follows:
EXCEPTION
WHEN over_limit OR under_limit OR VALUE_ERROR THEN
-- handle the error
If any of the exceptions in the list is raised, the associated sequence of statements is executed. The keyword OTHERS
cannot appear in the list of exception names; it must appear by itself. You can have any number of exception handlers, and each handler can associate a list of exceptions with a sequence of statements. However, an exception name can appear only once in the exception-handling part of a PL/SQL block or subprogram.
The usual scoping rules for PL/SQL variables apply, so you can reference local and global variables in an exception handler. However, when an exception is raised inside a cursor FOR
loop, the cursor is closed implicitly before the handler is invoked. Therefore, the values of explicit cursor attributes are not available in the handler.
Exceptions can be raised in declarations by faulty initialization expressions. For example, the following declaration raises an exception because the constant credit_limit
cannot store numbers larger than 999:
Example 10-10 Raising an Exception in a Declaration
DECLARE credit_limit CONSTANT NUMBER(3) := 5000; -- raises an error BEGIN NULL; EXCEPTION WHEN OTHERS THEN -- Cannot catch the exception. This handler is never called. DBMS_OUTPUT.PUT_LINE('Can''t handle an exception in a declaration.'); END; /
Handlers in the current block cannot catch the raised exception because an exception raised in a declaration propagates immediately to the enclosing block.
When an exception occurs within an exception handler, that same handler cannot catch the exception. An exception raised inside a handler propagates immediately to the enclosing block, which is searched to find a handler for this new exception. From there on, the exception propagates normally. For example:
EXCEPTION
WHEN INVALID_NUMBER THEN
INSERT INTO ... -- might raise DUP_VAL_ON_INDEX
WHEN DUP_VAL_ON_INDEX THEN ... -- cannot catch the exception
END;
A GOTO
statement can branch from an exception handler into an enclosing block.
A GOTO
statement cannot branch into an exception handler, or from an exception handler into the current block.
In an exception handler, you can use the built-in functions SQLCODE
and SQLERRM
to find out which error occurred and to get the associated error message. For internal exceptions, SQLCODE
returns the number of the Oracle error. The number that SQLCODE
returns is negative unless the Oracle error is no data found
, in which case SQLCODE
returns +100. SQLERRM
returns the corresponding error message. The message begins with the Oracle error code.
For user-defined exceptions, SQLCODE
returns +1 and SQLERRM
returns the message User-Defined Exception
unless you used the pragma EXCEPTION_INIT
to associate the exception name with an Oracle error number, in which case SQLCODE
returns that error number and SQLERRM
returns the corresponding error message. The maximum length of an Oracle error message is 512 characters including the error code, nested messages, and message inserts such as table and column names.
If no exception has been raised, SQLCODE
returns zero and SQLERRM
returns the message: ORA-0000: normal, successful completion
.
You can pass an error number to SQLERRM
, in which case SQLERRM
returns the message associated with that error number. Make sure you pass negative error numbers to SQLERRM
.
Passing a positive number to SQLERRM
always returns the message user-defined exception
unless you pass +100
, in which case SQLERRM
returns the message no data found
. Passing a zero to SQLERRM
always returns the message normal, successful completion
.
You cannot use SQLCODE
or SQLERRM
directly in a SQL statement. Instead, you must assign their values to local variables, then use the variables in the SQL statement, as shown in Example 10-11.
Example 10-11 Displaying SQLCODE and SQLERRM
CREATE TABLE errors (code NUMBER, message VARCHAR2(64), happened TIMESTAMP); DECLARE name employees.last_name%TYPE; v_code NUMBER; v_errm VARCHAR2(64); BEGIN SELECT last_name INTO name FROM employees WHERE employee_id = -1; EXCEPTION WHEN OTHERS THEN v_code := SQLCODE; v_errm := SUBSTR(SQLERRM, 1 , 64); DBMS_OUTPUT.PUT_LINE('Error code ' || v_code || ': ' || v_errm); -- Normally we would call another procedure, declared with PRAGMA -- AUTONOMOUS_TRANSACTION, to insert information about errors. INSERT INTO errors VALUES (v_code, v_errm, SYSTIMESTAMP); END; /
The string function SUBSTR
ensures that a VALUE_ERROR
exception (for truncation) is not raised when you assign the value of SQLERRM
to err_msg
. The functions SQLCODE
and SQLERRM
are especially useful in the OTHERS
exception handler because they tell you which internal exception was raised.
When using pragma RESTRICT_REFERENCES
to assert the purity of a stored function, you cannot specify the constraints WNPS
and RNPS
if the function calls SQLCODE
or SQLERRM
.
Remember, if it cannot find a handler for a raised exception, PL/SQL returns an unhandled exception error to the host environment, which determines the outcome. For example, in the Oracle Precompilers environment, any database changes made by a failed SQL statement or PL/SQL block are rolled back.
Unhandled exceptions can also affect subprograms. If you exit a subprogram successfully, PL/SQL assigns values to OUT
parameters. However, if you exit with an unhandled exception, PL/SQL does not assign values to OUT
parameters (unless they are NOCOPY
parameters). Also, if a stored subprogram fails with an unhandled exception, PL/SQL does not roll back database work done by the subprogram.
You can avoid unhandled exceptions by coding an OTHERS
handler at the topmost level of every PL/SQL program.
In this section, you learn techniques that increase flexibility.
An exception handler lets you recover from an otherwise fatal error before exiting a block. But when the handler completes, the block is terminated. You cannot return to the current block from an exception handler. In the following example, if the SELECT
INTO
statement raises ZERO_DIVIDE
, you cannot resume with the INSERT
statement:
CREATE TABLE employees_temp AS SELECT employee_id, salary, commission_pct FROM employees; DECLARE sal_calc NUMBER(8,2); BEGIN INSERT INTO employees_temp VALUES (301, 2500, 0); SELECT salary / commission_pct INTO sal_calc FROM employees_temp WHERE employee_id = 301; INSERT INTO employees_temp VALUES (302, sal_calc/100, .1); EXCEPTION WHEN ZERO_DIVIDE THEN NULL; END; /
You can still handle an exception for a statement, then continue with the next statement. Place the statement in its own sub-block with its own exception handlers. If an error occurs in the sub-block, a local handler can catch the exception. When the sub-block ends, the enclosing block continues to execute at the point where the sub-block ends, as shown in Example 10-12.
Example 10-12 Continuing After an Exception
DECLARE sal_calc NUMBER(8,2); BEGIN INSERT INTO employees_temp VALUES (303, 2500, 0); BEGIN -- sub-block begins SELECT salary / commission_pct INTO sal_calc FROM employees_temp WHERE employee_id = 301; EXCEPTION WHEN ZERO_DIVIDE THEN sal_calc := 2500; END; -- sub-block ends INSERT INTO employees_temp VALUES (304, sal_calc/100, .1); EXCEPTION WHEN ZERO_DIVIDE THEN NULL; END; /
In this example, if the SELECT
INTO
statement raises a ZERO_DIVIDE
exception, the local handler catches it and sets sal_calc
to 2500. Execution of the handler is complete, so the sub-block terminates, and execution continues with the INSERT
statement. See also Example 5-38, "Collection Exceptions".
You can also perform a sequence of DML operations where some might fail, and process the exceptions only after the entire operation is complete, as described in "Handling FORALL Exceptions with the %BULK_EXCEPTIONS Attribute".
After an exception is raised, rather than abandon your transaction, you might want to retry it. The technique is:
Encase the transaction in a sub-block.
Place the sub-block inside a loop that repeats the transaction.
Before starting the transaction, mark a savepoint. If the transaction succeeds, commit, then exit from the loop. If the transaction fails, control transfers to the exception handler, where you roll back to the savepoint undoing any changes, then try to fix the problem.
In Example 10-13, the INSERT
statement might raise an exception because of a duplicate value in a unique column. In that case, we change the value that needs to be unique and continue with the next loop iteration. If the INSERT succeeds, we exit from the loop immediately. With this technique, you should use a FOR
or WHILE
loop to limit the number of attempts.
Example 10-13 Retrying a Transaction After an Exception
CREATE TABLE results ( res_name VARCHAR(20), res_answer VARCHAR2(3) ); CREATE UNIQUE INDEX res_name_ix ON results (res_name); INSERT INTO results VALUES ('SMYTHE', 'YES'); INSERT INTO results VALUES ('JONES', 'NO'); DECLARE name VARCHAR2(20) := 'SMYTHE'; answer VARCHAR2(3) := 'NO'; suffix NUMBER := 1; BEGIN FOR i IN 1..5 LOOP -- try 5 times BEGIN -- sub-block begins SAVEPOINT start_transaction; -- mark a savepoint /* Remove rows from a table of survey results. */ DELETE FROM results WHERE res_answer = 'NO'; /* Add a survey respondent's name and answers. */ INSERT INTO results VALUES (name, answer); -- raises DUP_VAL_ON_INDEX if two respondents have the same name COMMIT; EXIT; EXCEPTION WHEN DUP_VAL_ON_INDEX THEN ROLLBACK TO start_transaction; -- undo changes suffix := suffix + 1; -- try to fix problem name := name || TO_CHAR(suffix); END; -- sub-block ends END LOOP; END; /
Using one exception handler for a sequence of statements, such as INSERT
, DELETE
, or UPDATE
statements, can mask the statement that caused an error. If you need to know which statement failed, you can use a locator variable
:
Example 10-14 Using a Locator Variable to Identify the Location of an Exception
CREATE OR REPLACE PROCEDURE loc_var AS stmt_no NUMBER; name VARCHAR2(100); BEGIN stmt_no := 1; -- designates 1st SELECT statement SELECT table_name INTO name FROM user_tables WHERE table_name LIKE 'ABC%'; stmt_no := 2; -- designates 2nd SELECT statement SELECT table_name INTO name FROM user_tables WHERE table_name LIKE 'XYZ%'; EXCEPTION WHEN NO_DATA_FOUND THEN DBMS_OUTPUT.PUT_LINE('Table name not found in query ' || stmt_no); END; / CALL loc_var();
To make your programs more robust and avoid problems at run time, you can turn on checking for certain warning conditions. These conditions are not serious enough to produce an error and keep you from compiling a subprogram. They might point out something in the subprogram that produces an undefined result or might create a performance problem.
To work with PL/SQL warning messages, you use the PLSQL_WARNINGS
initialization parameter, the DBMS_WARNING
package, and the USER/DBA/ALL_PLSQL_OBJECT_SETTINGS
views.
PL/SQL warning messages are divided into categories, so that you can suppress or display groups of similar warnings during compilation. The categories are:
SEVERE
: Messages for conditions that might cause unexpected behavior or wrong results, such as aliasing problems with parameters.
PERFORMANCE
: Messages for conditions that might cause performance problems, such as passing a VARCHAR2
value to a NUMBER
column in an INSERT
statement.
INFORMATIONAL
: Messages for conditions that do not have an effect on performance or correctness, but that you might want to change to make the code more maintainable, such as unreachable code that can never be executed.
The keyword All
is a shorthand way to refer to all warning messages.
You can also treat particular messages as errors instead of warnings. For example, if you know that the warning message PLW-05003
represents a serious problem in your code, including 'ERROR:05003'
in the PLSQL_WARNINGS
setting makes that condition trigger an error message (PLS_05003
) instead of a warning message. An error message causes the compilation to fail.
To let the database issue warning messages during PL/SQL compilation, you set the initialization parameter PLSQL_WARNINGS
. You can enable and disable entire categories of warnings (ALL
, SEVERE
, INFORMATIONAL
, PERFORMANCE
), enable and disable specific message numbers, and make the database treat certain warnings as compilation errors so that those conditions must be corrected.
This parameter can be set at the system level or the session level. You can also set it for a single compilation by including it as part of the ALTER PROCEDURE
... COMPILE
statement. You might turn on all warnings during development, turn off all warnings when deploying for production, or turn on some warnings when working on a particular subprogram where you are concerned with some aspect, such as unnecessary code or performance.
Example 10-15 Controlling the Display of PL/SQL Warnings
-- To focus on one aspect ALTER SESSION SET PLSQL_WARNINGS='ENABLE:PERFORMANCE'; -- Recompile with extra checking ALTER PROCEDURE loc_var COMPILE PLSQL_WARNINGS='ENABLE:PERFORMANCE' REUSE SETTINGS; -- To turn off all warnings ALTER SESSION SET PLSQL_WARNINGS='DISABLE:ALL'; -- Display 'severe' warnings, don't want 'performance' warnings, and -- want PLW-06002 warnings to produce errors that halt compilation ALTER SESSION SET PLSQL_WARNINGS='ENABLE:SEVERE', 'DISABLE:PERFORMANCE', 'ERROR:06002'; -- For debugging during development ALTER SESSION SET PLSQL_WARNINGS='ENABLE:ALL';
Warning messages can be issued during compilation of PL/SQL subprograms; anonymous blocks do not produce any warnings.
The settings for the PLSQL_WARNINGS
parameter are stored along with each compiled subprogram. If you recompile the subprogram with a CREATE OR REPLACE
statement, the current settings for that session are used. If you recompile the subprogram with an ALTER
... COMPILE
statement, the current session setting might be used, or the original setting that was stored with the subprogram, depending on whether you include the REUSE SETTINGS
clause in the statement. For more information, see ALTER
FUNCTION
, ALTER
PACKAGE
, and ALTER
PROCEDURE
in Oracle Database SQL Reference.
To see any warnings generated during compilation, you use the SQL*Plus SHOW ERRORS
command or query the USER_ERRORS
data dictionary view. PL/SQL warning messages all use the prefix PLW
.
If you are writing a development environment that compiles PL/SQL subprograms, you can control PL/SQL warning messages by calling subprograms in the DBMS_WARNING
package. You might also use this package when compiling a complex application, made up of several nested SQL*Plus scripts, where different warning settings apply to different subprograms. You can save the current state of the PLSQL_WARNINGS
parameter with one call to the package, change the parameter to compile a particular set of subprograms, then restore the original parameter value.
For example, Example 10-16 is a procedure with unnecessary code that could be removed. It could represent a mistake, or it could be intentionally hidden by a debug flag, so you might or might not want a warning message for it.
Example 10-16 Using the DBMS_WARNING Package to Display Warnings
-- When warnings disabled, the following procedure compiles with no warnings CREATE OR REPLACE PROCEDURE unreachable_code AS x CONSTANT BOOLEAN := TRUE; BEGIN IF x THEN DBMS_OUTPUT.PUT_LINE('TRUE'); ELSE DBMS_OUTPUT.PUT_LINE('FALSE'); END IF; END unreachable_code; / -- enable all warning messages for this session CALL DBMS_WARNING.set_warning_setting_string('ENABLE:ALL' ,'SESSION'); -- Check the current warning setting SELECT DBMS_WARNING.get_warning_setting_string() FROM DUAL; -- Recompile the procedure and a warning about unreachable code displays ALTER PROCEDURE unreachable_code COMPILE; SHOW ERRORS;
In Example 10-16, you could have used the following ALTER
PROCEDURE
without the call to DBMS_WARNINGS.set_warning_setting_string
:
ALTER PROCEDURE unreachable_code COMPILE
PLSQL_WARNINGS = 'ENABLE:ALL' REUSE SETTINGS;
For more information, see ALTER
PROCEDURE
in Oracle Database SQL Reference, DBMS_WARNING
package in Oracle Database PL/SQL Packages and Types Reference, and PLW- messages in Oracle Database Error Messages