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Oracle® Database PL/SQL Language Reference
11g Release 2 (11.2)

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2 PL/SQL Language Fundamentals

This chapter explains these aspects of the PL/SQL language:

Character Sets

Any character data to be processed by PL/SQL or stored in a database must be represented as a sequence of bytes. The byte representation of a single character is called a character code. A set of character codes is called a character set.

Every Oracle database supports a database character set and a national character set. PL/SQL also supports these character sets. This document explains how PL/SQL uses the database character set and national character set.

Topics

See Also:

Oracle Database Globalization Support Guide for general information about character sets

Database Character Set

PL/SQL uses the database character set to represent:

The database character set can be either single-byte, mapping each supported character to one particular byte, or multibyte-varying-width, mapping each supported character to a sequence of one, two, three, or four bytes. The maximum number of bytes in a character code depends on the particular character set.

Every database character set includes these basic characters:

  • Latin letters: A through Z and a through z

  • Decimal digits: 0 through 9

  • Punctuation characters in Table 2-1

  • Whitespace characters: space, tab, new line, and carriage return

PL/SQL source text that uses only the basic characters can be stored and compiled in any database. PL/SQL source text that uses nonbasic characters can be stored and compiled only in databases whose database character sets support those nonbasic characters.

Table 2-1 Punctuation Characters in Every Database Character Set

Symbol Name

(

Left parenthesis

)

Right parenthesis

<

Left angle bracket

>

Right angle bracket

+

Plus sign

-

Hyphen or minus sign

*

Asterisk

/

Slash

=

Equal sign

,

Comma

;

Semicolon

:

Colon

.

Period

!

Exclamation point

?

Question mark

'

Apostrophe or single quotation mark

"

Quotation mark or double quotation mark

@

At sign

%

Percent sign

#

Number sign

$

Dollar sign

_

Underscore

|

Vertical bar


See Also:

Oracle Database Globalization Support Guide for more information about the database character set

National Character Set

PL/SQL uses the national character set to represent character values of data types NCHAR, NVARCHAR2 and NCLOB. For information about these data types, see "SQL Data Types".

See Also:

Oracle Database Globalization Support Guide for more information about the national character set

Lexical Units

The lexical units of PL/SQL are its smallest individual components—delimiters, identifiers, literals, and comments.

Topics

Delimiters

A delimiter is a character, or character combination, that has a special meaning in PL/SQL. Do not embed any others characters (including whitespace characters) inside a delimiter.

Table 2-2 summarizes the PL/SQL delimiters.

Table 2-2 PL/SQL Delimiters

Delimiter Meaning

+

Addition operator

:=

Assignment operator

=>

Association operator

%

Attribute indicator

'

Character string delimiter

.

Component indicator

||

Concatenation operator

/

Division operator

**

Exponentiation operator

(

Expression or list delimiter (begin)

)

Expression or list delimiter (end)

:

Host variable indicator

,

Item separator

<<

Label delimiter (begin)

>>

Label delimiter (end)

/*

Multiline comment delimiter (begin)

*/

Multiline comment delimiter (end)

*

Multiplication operator

"

Quoted identifier delimiter

..

Range operator

=

Relational operator (equal)

<>

Relational operator (not equal)

!=

Relational operator (not equal)

~=

Relational operator (not equal)

^=

Relational operator (not equal)

<

Relational operator (less than)

>

Relational operator (greater than)

<=

Relational operator (less than or equal)

>=

Relational operator (greater than or equal)

@

Remote access indicator

--

Single-line comment indicator

;

Statement terminator

-

Subtraction or negation operator


Identifiers

Identifiers name PL/SQL elements, which include:

  • Constants

  • Cursors

  • Exceptions

  • Keywords

  • Labels

  • Packages

  • Reserved words

  • Subprograms

  • Types

  • Variables

Every character in an identifier, alphabetic or not, is significant. For example, the identifiers lastname and last_name are different.

You must separate adjacent identifiers by one or more whitespace characters or a punctuation character.

Except as explained in "Quoted User-Defined Identifiers", PL/SQL is case-insensitive for identifiers. For example, the identifiers lastname, LastName, and LASTNAME are the same.

Topics

Reserved Words and Keywords

Reserved words and keywords are identifiers that have special meaning in PL/SQL.

You cannot use reserved words as ordinary user-defined identifiers. You can use them as quoted user-defined identifiers, but it is not recommended. For more information, see "Quoted User-Defined Identifiers".

You can use keywords as ordinary user-defined identifiers, but it is not recommended.

For lists of PL/SQL reserved words and keywords, see Table D-1 and Table D-2, respectively.

Predefined Identifiers

Predefined identifiers are declared in the predefined package STANDARD. An example of a predefined identifier is the exception INVALID_NUMBER.

For a list of predefined identifiers, use this query:

SELECT TYPE_NAME FROM ALL_TYPES WHERE PREDEFINED='YES';

You can use predefined identifiers as user-defined identifiers, but it is not recommended. Your local declaration overrides the global declaration (see "Scope and Visibility of Identifiers").

User-Defined Identifiers

A user-defined identifier is:

  • Composed of characters from the database character set

  • Either ordinary or quoted

Tip:

Make user-defined identifiers meaningful. For example, the meaning of cost_per_thousand is obvious, but the meaning of cpt is not.
Ordinary User-Defined Identifiers

An ordinary user-defined identifier:

  • Begins with a letter

  • Can include letters, digits, and these symbols:

    • Dollar sign ($)

    • Number sign (#)

    • Underscore (_)

  • Is not a reserved word (listed in Table D-1).

The database character set defines which characters are classified as letters and digits. The representation of the identifier in the database character set cannot exceed 30 bytes.

Examples of acceptable ordinary user-defined identifiers:

X
t2
phone#
credit_limit
LastName
oracle$number
money$$$tree
SN##
try_again_

Examples of unacceptable ordinary user-defined identifiers:

mine&yours
debit-amount
on/off
user id
Quoted User-Defined Identifiers

A quoted user-defined identifier is enclosed in double quotation marks. Between the double quotation marks, any characters from the database character set are allowed except double quotation marks, new line characters, and null characters. For example, these identifiers are acceptable:

"X+Y"
"last name"
"on/off switch"
"employee(s)"
"*** header info ***"

The representation of the quoted identifier in the database character set cannot exceed 30 bytes (excluding the double quotation marks).

A quoted user-defined identifier is case-sensitive, with one exception: If a quoted user-defined identifier, without its enclosing double quotation marks, is a valid ordinary user-defined identifier, then the double quotation marks are optional in references to the identifier, and if you omit them, then the identifier is case-insensitive.

In Example 2-1, the quoted user-defined identifier "HELLO", without its enclosing double quotation marks, is a valid ordinary user-defined identifier. Therefore, the reference Hello is valid.

Example 2-1 Valid Case-Insensitive Reference to Quoted User-Defined Identifier

DECLARE
  "HELLO" varchar2(10) := 'hello';
BEGIN
  DBMS_Output.Put_Line(Hello);
END;
/

Result:

hello

In Example 2-2, the reference "Hello" is invalid, because the double quotation marks make the identifier case-sensitive.

Example 2-2 Invalid Case-Insensitive Reference to Quoted User-Defined Identifier

DECLARE
  "HELLO" varchar2(10) := 'hello';
BEGIN
  DBMS_Output.Put_Line("Hello");
END;
/

Result:

DBMS_Output.Put_Line("Hello");
                        *
ERROR at line 4:
ORA-06550: line 4, column 25:
PLS-00201: identifier 'Hello' must be declared
ORA-06550: line 4, column 3:
PL/SQL: Statement ignored

It is not recommended, but you can use a reserved word as a quoted user-defined identifier. Because a reserved word is not a valid ordinary user-defined identifier, you must always enclose the identifier in double quotation marks, and it is always case-sensitive.

Example 2-3 declares quoted user-defined identifiers "BEGIN", "Begin", and "begin". Although BEGIN, Begin, and begin represent the same reserved word, "BEGIN", "Begin", and "begin" represent different identifiers.

Example 2-3 Reserved Word as Quoted User-Defined Identifier

DECLARE
  "BEGIN" varchar2(15) := 'UPPERCASE';
  "Begin" varchar2(15) := 'Initial Capital';
  "begin" varchar2(15) := 'lowercase';
BEGIN
  DBMS_Output.Put_Line("BEGIN");
  DBMS_Output.Put_Line("Begin");
  DBMS_Output.Put_Line("begin");
END;
/

Result:

UPPERCASE
Initial Capital
lowercase
 
PL/SQL procedure successfully completed.

Example 2-4 references a quoted user-defined identifier that is a reserved word, neglecting to enclose it in double quotation marks.

Example 2-4 Neglecting Double Quotation Marks

DECLARE
  "HELLO" varchar2(10) := 'hello';  -- HELLO is not a reserved word
  "BEGIN" varchar2(10) := 'begin';  -- BEGIN is a reserved word
BEGIN
  DBMS_Output.Put_Line(Hello);      -- Double quotation marks are optional
  DBMS_Output.Put_Line(BEGIN);      -- Double quotation marks are required
end;
/

Result:

DBMS_Output.Put_Line(BEGIN);      -- Double quotation marks are required
                       *
ERROR at line 6:
ORA-06550: line 6, column 24:
PLS-00103: Encountered the symbol "BEGIN" when expecting one of the following:
( ) - + case mod new not null <an identifier>
<a double-quoted delimited-identifier> <a bind variable>
table continue avg count current exists max min prior sql
stddev sum variance execute multiset the both leading
trailing forall merge year month day hour minute second
timezone_hour timezone_minute timezone_region timezone_abbr
time timestamp interval date
<a string literal with character set specificat

Example 2-5 references a quoted user-defined identifier that is a reserved word, neglecting its case-sensitivity.

Example 2-5 Neglecting Case-Sensitivity

DECLARE
  "HELLO" varchar2(10) := 'hello';  -- HELLO is not a reserved word
  "BEGIN" varchar2(10) := 'begin';  -- BEGIN is a reserved word
BEGIN
  DBMS_Output.Put_Line(Hello);      -- Identifier is case-insensitive
  DBMS_Output.Put_Line("Begin");    -- Identifier is case-sensitive
END;
/

Result:

DBMS_Output.Put_Line("Begin");    -- Identifier is case-sensitive
                        *
ERROR at line 6:
ORA-06550: line 6, column 25:
PLS-00201: identifier 'Begin' must be declared
ORA-06550: line 6, column 3:
PL/SQL: Statement ignored

Literals

A literal is a value that is neither represented by an identifier nor calculated from other values. For example, 123 is an integer literal and 'abc' is a character literal, but 1+2 is not a literal.

PL/SQL literals include all SQL literals (described in Oracle Database SQL Language Reference) and BOOLEAN literals (which SQL does not have). A BOOLEAN literal is the predefined logical value TRUE, FALSE, or NULL. NULL represents an unknown value.

Note:

Like Oracle Database SQL Language Reference, this document uses the terms character literal and string interchangeably.

When using character literals in PL/SQL, remember:

  • Character literals are case-sensitive.

    For example, 'Z' and 'z' are different.

  • Whitespace characters are significant.

    For example, these literals are different:

    'abc'
    ' abc'
    'abc '
    ' abc '
    'a b c'
    
  • PL/SQL has no line-continuation character that means "this string continues on the next source line." If you continue a string on the next source line, then the string includes a line-break character.

    For example, this PL/SQL code:

    BEGIN
      DBMS_OUTPUT.PUT_LINE('This string breaks
    here.');
    END;
    /
    

    Prints this:

    This string breaks
    here.
    

    If your string does not fit on a source line and you do not want it to include a line-break character, then construct the string with the concatenation operator (||).

    For example, this PL/SQL code:

    BEGIN
      DBMS_OUTPUT.PUT_LINE('This string ' ||
                           'contains no line-break character.');
    END;
    /
    

    Prints this:

    This string contains no line-break character.
    

    For more information about the concatenation operator, see "Concatenation Operator".

  • '0' through '9' are not equivalent to the integer literals 0 through 9.

    However, because PL/SQL converts them to integers, you can use them in arithmetic expressions.

  • A character literal with zero characters has the value NULL and is called a null string.

    However, this NULL value is not the BOOLEAN value NULL.

  • An ordinary character literal is composed of characters in the database character set.

    For information about the database character set, see Oracle Database Globalization Support Guide.

  • A national character literal is composed of characters in the national character set.

    For information about the national character set, see Oracle Database Globalization Support Guide.

Comments

The PL/SQL compiler ignores comments. Their purpose is to help other application developers understand your source text. Typically, you use comments to describe the purpose and use of each code segment. You can also disable obsolete or unfinished pieces of code by turning them into comments.

Topics

See Also:

"Comment"

Single-Line Comments

A single-line comment begins with -- and extends to the end of the line.

Caution:

Do not put a single-line comment in a PL/SQL block to be processed dynamically by an Oracle Precompiler program. The Oracle Precompiler program ignores end-of-line characters, which means that a single-line comment ends when the block ends.

Example 2-6 has three single-line comments.

Example 2-6 Single-Line Comments

DECLARE
  howmany     NUMBER;
  num_tables  NUMBER;
BEGIN
  -- Begin processing
  SELECT COUNT(*) INTO howmany
  FROM USER_OBJECTS
  WHERE OBJECT_TYPE = 'TABLE'; -- Check number of tables
  num_tables := howmany;       -- Compute another value
END;
/

While testing or debugging a program, you can disable a line of code by making it a comment. For example:

-- DELETE FROM employees WHERE comm_pct IS NULL

Multiline Comments

A multiline comment begins with /*, ends with */, and can span multiple lines.

Example 2-7 has two multiline comments. (The SQL function TO_CHAR returns the character equivalent of its argument. For more information about TO_CHAR, see Oracle Database SQL Language Reference.)

Example 2-7 Multiline Comments

DECLARE
  some_condition  BOOLEAN;
  pi              NUMBER := 3.1415926;
  radius          NUMBER := 15;
  area            NUMBER;
BEGIN
  /* Perform some simple tests and assignments */
 
  IF 2 + 2 = 4 THEN
    some_condition := TRUE;
  /* We expect this THEN to always be performed */
  END IF;
 
  /* This line computes the area of a circle using pi,
  which is the ratio between the circumference and diameter.
  After the area is computed, the result is displayed. */
 
  area := pi * radius**2;
  DBMS_OUTPUT.PUT_LINE('The area is: ' || TO_CHAR(area));
END;
/
 

Result:

The area is: 706.858335

You can use multiline comment delimiters to "comment out" sections of code. When doing so, be careful not to cause nested multiline comments. One multiline comment cannot contain another multiline comment. However, a multiline comment can contain a single-line comment. For example, this causes a syntax error:

/*
  IF 2 + 2 = 4 THEN
    some_condition := TRUE;
  /* We expect this THEN to always be performed */
  END IF;
*/

This does not cause a syntax error:

/*
  IF 2 + 2 = 4 THEN
    some_condition := TRUE;
  -- We expect this THEN to always be performed
  END IF;
*/

Whitespace Characters Between Lexical Units

You can put whitespace characters between lexical units, which often makes your source text easier to read, as Example 2-8 shows.

Example 2-8 Whitespace Characters Improving Source Text Readability

DECLARE
  x    NUMBER := 10;
  y    NUMBER := 5;
  max  NUMBER;
BEGIN
  IF x>y THEN max:=x;ELSE max:=y;END IF;  -- correct but hard to read
  
  -- Easier to read:
  
  IF x > y THEN
    max:=x;
  ELSE
    max:=y;
  END IF;
END;
/

Declarations

A declaration allocates storage space for a value of a specified data type, and names the storage location so that you can reference it. You must declare objects before you can reference them. Declarations can appear in the declarative part of any block, subprogram, or package.

Topics

For information about declaring objects other than variables and constants, see the syntax of declare_section in "Block".

Variable Declarations

A variable declaration always specifies the name and data type of the variable. For most data types, a variable declaration can also specify an initial value.

The variable name must be a valid user-defined identifier (see "User-Defined Identifiers").

The data type can be any PL/SQL data type. The PL/SQL data types include the SQL data types. A data type is either scalar (without internal components) or composite (with internal components).

Example 2-9 declares several variables with scalar data types.

Example 2-9 Scalar Variable Declarations

DECLARE
  part_number       NUMBER(6);     -- SQL data type
  part_name         VARCHAR2(20);  -- SQL data type
  in_stock          BOOLEAN;       -- PL/SQL-only data type
  part_price        NUMBER(6,2);   -- SQL data type
  part_description  VARCHAR2(50);  -- SQL data type
BEGIN
  NULL;
END;
/

See Also:

Constant Declarations

The information in "Variable Declarations" also applies to constant declarations, but a constant declaration has two more requirements: the keyword CONSTANT and the initial value of the constant. (The initial value of a constant is its permanent value.)

Example 2-10 declares three constants with scalar data types.

Example 2-10 Constant Declarations

DECLARE
  credit_limit     CONSTANT REAL    := 5000.00;  -- SQL data type
  max_days_in_year CONSTANT INTEGER := 366;      -- SQL data type
  urban_legend     CONSTANT BOOLEAN := FALSE;    -- PL/SQL-only data type
BEGIN
  NULL;
END;
/

See Also:

"Constant Declaration" for constant declaration syntax

Initial Values of Variables and Constants

In a variable declaration, the initial value is optional unless you specify the NOT NULL constraint (for details, see "NOT NULL Constraint"). In a constant declaration, the initial value is required.

If the declaration is in a block or subprogram, the initial value is assigned to the variable or constant every time control passes to the block or subprogram. If the declaration is in a package specification, the initial value is assigned to the variable or constant for each session (whether the variable or constant is public or private).

To specify the initial value, use either the assignment operator (:=) or the keyword DEFAULT, followed by an expression. The expression can include previously declared constants and previously initialized variables.

Example 2-11 assigns initial values to the constant and variables that it declares. The initial value of area depends on the previously declared constant pi and the previously initialized variable radius.

Example 2-11 Variable and Constant Declarations with Initial Values

DECLARE
  hours_worked    INTEGER := 40;
  employee_count  INTEGER := 0;

  pi     CONSTANT REAL := 3.14159;
  radius          REAL := 1;
  area            REAL := (pi * radius**2);
BEGIN
  NULL;
END;
/

If you do not specify an initial value for a variable, assign a value to it before using it in any other context.

In Example 2-12, the variable counter has the initial value NULL, by default. As the example shows (using the "IS [NOT] NULL Operator") NULL is different from zero.

Example 2-12 Variable Initialized to NULL by Default

DECLARE
  counter INTEGER;  -- initial value is NULL by default
BEGIN
  counter := counter + 1;  -- NULL + 1 is still NULL
  
  IF counter IS NULL THEN
    DBMS_OUTPUT.PUT_LINE('counter is NULL.');
  END IF;
END;
/
 

Result:

counter is NULL.

See Also:

NOT NULL Constraint

You can impose the NOT NULL constraint on a scalar variable or constant (or scalar component of a composite variable or constant). The NOT NULL constraint prevents assigning a null value to the item. The item can acquire this constraint either implicitly (from its data type) or explicitly.

A scalar variable declaration that specifies NOT NULL, either implicitly or explicitly, must assign an initial value to the variable (because the default initial value for a scalar variable is NULL).

In Example 2-13, the variable acct_id acquires the NOT NULL constraint explicitly, and the variables a, b, and c acquire it from their data types.

Example 2-13 Variable Declaration with NOT NULL Constraint

DECLARE
  acct_id INTEGER(4) NOT NULL := 9999;
  a NATURALN                  := 9999;
  b POSITIVEN                 := 9999;
  c SIMPLE_INTEGER            := 9999;
BEGIN
  NULL;
END;
/

PL/SQL treats any zero-length string as a NULL value. This includes values returned by character functions and BOOLEAN expressions.

In Example 2-14, all variables are initialized to NULL.

Example 2-14 Variables Initialized to NULL Values

DECLARE
  null_string  VARCHAR2(80) := TO_CHAR('');
  address      VARCHAR2(80);
  zip_code     VARCHAR2(80) := SUBSTR(address, 25, 0);
  name         VARCHAR2(80);
  valid        BOOLEAN      := (name != '');
BEGIN
  NULL;
END;
/

To test for a NULL value, use the "IS [NOT] NULL Operator".

%TYPE Attribute

The %TYPE attribute lets you declare a data item of the same data type as a previously declared variable or column (without knowing what that type is). If the declaration of the referenced item changes, then the declaration of the referencing item changes accordingly.

The syntax of the declaration is:

referencing_item referenced_item%TYPE;

For the kinds of items that can be referencing and referenced items, see "%TYPE Attribute".

The referencing item inherits the following from the referenced item:

  • Data type and size

  • Constraints (unless the referenced item is a column)

The referencing item does not inherit the initial value of the referenced item. Therefore, if the referencing item specifies or inherits the NOT NULL constraint, you must specify an initial value for it.

The %TYPE attribute is particularly useful when declaring variables to hold database values. The syntax for declaring a variable of the same type as a column is:

variable_name table_name.column_name%TYPE;

In Example 2-15, the variable surname inherits the data type and size of the column employees.last_name, which has a NOT NULL constraint. Because surname does not inherit the NOT NULL constraint, its declaration does not need an initial value.

Example 2-15 Declaring Variable of Same Type as Column

DECLARE
  surname  employees.last_name%TYPE;
BEGIN
  DBMS_OUTPUT.PUT_LINE('surname=' || surname);
END;
/

Result:

surname=

In Example 2-16, the variable surname inherits the data type, size, and NOT NULL constraint of the variable name. Because surname does not inherit the initial value of name, its declaration needs an initial value (which cannot exceed 25 characters).

Example 2-16 Declaring Variable of Same Type as Another Variable

DECLARE
  name     VARCHAR(25) NOT NULL := 'Smith';
  surname  name%TYPE := 'Jones';
BEGIN
  DBMS_OUTPUT.PUT_LINE('name=' || name);
  DBMS_OUTPUT.PUT_LINE('surname=' || surname);
END;
/

Result:

name=Smith
surname=Jones

See Also:

"%ROWTYPE Attribute", which lets you declare a record variable that represents either a full or partial row of a database table or view

References to Identifiers

When referencing an identifier, you use a name that is either simple, qualified, remote, or both qualified and remote.

The simple name of an identifier is the name in its declaration. For example:

DECLARE
  a INTEGER;  -- Declaration
BEGIN
  a := 1;     -- Reference with simple name
END;
/

If an identifier is declared in a named PL/SQL unit, you can (and sometimes must) reference it with its qualified name. The syntax (called dot notation) is:

unit_name.simple_identifier_name

For example, if package p declares identifier a, you can reference the identifier with the qualified name p.a. The unit name also can (and sometimes must) be qualified. You must qualify an identifier when it is not visible (see "Scope and Visibility of Identifiers").

If the identifier names an object on a remote database, you must reference it with its remote name. The syntax is:

simple_identifier_name@link_to_remote_database

If the identifier is declared in a PL/SQL unit on a remote database, you must reference it with its qualified remote name. The syntax is:

unit_name.simple_identifier_name@link_to_remote_database

You can create synonyms for remote schema objects, but you cannot create synonyms for objects declared in PL/SQL subprograms or packages. To create a synonym, use the SQL statement CREATE SYNONYM, explained in Oracle Database SQL Language Reference.

For information about how PL/SQL resolves ambiguous names, see Appendix B, "PL/SQL Name Resolution".

Note:

You can reference identifiers declared in the packages STANDARD and DBMS_STANDARD without qualifying them with the package names, unless you have declared a local identifier with the same name (see "Scope and Visibility of Identifiers").

Scope and Visibility of Identifiers

The scope of an identifier is the region of a PL/SQL unit from which you can reference the identifier. The visibility of an identifier is the region of a PL/SQL unit from which you can reference the identifier without qualifying it. An identifier is local to the PL/SQL unit that declares it. If that unit has subunits, the identifier is global to them.

If a subunit redeclares a global identifier, then inside the subunit, both identifiers are in scope, but only the local identifier is visible. To reference the global identifier, the subunit must qualify it with the name of the unit that declared it. If that unit has no name, then the subunit cannot reference the global identifier.

A PL/SQL unit cannot reference identifiers declared in other units at the same level, because those identifiers are neither local nor global to the block.

Example 2-17 shows the scope and visibility of several identifiers. The first sub-block redeclares the global identifier a. To reference the global variable a, the first sub-block would have to qualify it with the name of the outer block—but the outer block has no name. Therefore, the first sub-block cannot reference the global variable a; it can reference only its local variable a. Because the sub-blocks are at the same level, the first sub-block cannot reference d, and the second sub-block cannot reference c.

Example 2-17 Scope and Visibility of Identifiers

-- Outer block:
DECLARE
  a CHAR;  -- Scope of a (CHAR) begins
  b REAL;    -- Scope of b begins
BEGIN
  -- Visible: a (CHAR), b
  
  -- First sub-block:
  DECLARE
    a INTEGER;  -- Scope of a (INTEGER) begins
    c REAL;       -- Scope of c begins
  BEGIN
    -- Visible: a (INTEGER), b, c
    NULL;
  END;          -- Scopes of a (INTEGER) and c end

  -- Second sub-block:
  DECLARE
    d REAL;     -- Scope of d begins
  BEGIN
    -- Visible: a (CHAR), b, d
    NULL;
  END;          -- Scope of d ends

-- Visible: a (CHAR), b
END;            -- Scopes of a (CHAR) and b end
/

Example 2-18 labels the outer block with the name outer. Therefore, after the sub-block redeclares the global variable birthdate, it can reference that global variable by qualifying its name with the block label. The sub-block can also reference its local variable birthdate, by its simple name.

Example 2-18 Qualifying Redeclared Global Identifier with Block Label

<<outer>>  -- label
DECLARE
  birthdate DATE := '09-AUG-70';
BEGIN
  DECLARE
    birthdate DATE := '29-SEP-70';
  BEGIN
    IF birthdate = outer.birthdate THEN
      DBMS_OUTPUT.PUT_LINE ('Same Birthday');
    ELSE
      DBMS_OUTPUT.PUT_LINE ('Different Birthday');
    END IF;
  END;
END;
/
 

Result:

Different Birthday

In Example 2-19, the procedure check_credit declares a variable, rating, and a function, check_rating. The function redeclares the variable. Then the function references the global variable by qualifying it with the procedure name.

Example 2-19 Qualifying Identifier with Subprogram Name

CREATE OR REPLACE PROCEDURE check_credit (credit_limit NUMBER) AS
  rating NUMBER := 3;
  
  FUNCTION check_rating RETURN BOOLEAN IS
    rating  NUMBER := 1;
    over_limit  BOOLEAN;
  BEGIN
    IF check_credit.rating <= credit_limit THEN  -- reference global variable
      over_limit := FALSE;
    ELSE
      over_limit := TRUE;
      rating := credit_limit;                    -- reference local variable
    END IF;
    RETURN over_limit;
  END check_rating;
BEGIN
  IF check_rating THEN
    DBMS_OUTPUT.PUT_LINE
      ('Credit rating over limit (' || TO_CHAR(credit_limit) || ').  '
      || 'Rating: ' || TO_CHAR(rating));
  ELSE
    DBMS_OUTPUT.PUT_LINE
      ('Credit rating OK.  ' || 'Rating: ' || TO_CHAR(rating));
  END IF;
END;
/
 
BEGIN
  check_credit(1);
END;
/
 

Result:

Credit rating over limit (1).  Rating: 3

You cannot declare the same identifier twice in the same PL/SQL unit. If you do, an error occurs when you reference the duplicate identifier, as Example 2-20 shows.

Example 2-20 Duplicate Identifiers in Same Scope

DECLARE
  id  BOOLEAN;
  id  VARCHAR2(5);  -- duplicate identifier
BEGIN
  id := FALSE;
END;
/
 

Result:

id := FALSE;
  *
ERROR at line 5:
ORA-06550: line 5, column 3:
PLS-00371: at most one declaration for 'ID' is permitted
ORA-06550: line 5, column 3:
PL/SQL: Statement ignored

You can declare the same identifier in two different units. The two objects represented by the identifier are distinct. Changing one does not affect the other, as Example 2-21 shows.

Example 2-21 Declaring Same Identifier in Different Units

DECLARE
  PROCEDURE p
  IS
    x VARCHAR2(1);
  BEGIN
    x := 'a';  -- Assign the value 'a' to x
    DBMS_OUTPUT.PUT_LINE('In procedure p, x = ' || x);
  END;
 
  PROCEDURE q
  IS
    x VARCHAR2(1);
  BEGIN
    x := 'b';  -- Assign the value 'b' to x
    DBMS_OUTPUT.PUT_LINE('In procedure q, x = ' || x);
  END;
 
BEGIN
  p;
  q;
END;
/

Result:

In procedure p, x = a
In procedure q, x = b

In the same scope, give labels and subprograms unique names to avoid confusion and unexpected results.

In Example 2-22, echo is the name of both a block and a subprogram. Both the block and the subprogram declare a variable named x. In the subprogram, echo.x refers to the local variable x, not to the global variable x.

Example 2-22 Label and Subprogram with Same Name in Same Scope

<<echo>>
DECLARE
  x  NUMBER := 5;
  
  PROCEDURE echo AS
    x  NUMBER := 0;
  BEGIN
    DBMS_OUTPUT.PUT_LINE('x = ' || x);
    DBMS_OUTPUT.PUT_LINE('echo.x = ' || echo.x);
  END;
 
BEGIN
  echo;
END;
/
 

Result:

x = 0
echo.x = 0

Example 2-23 has two labels for the outer block, compute_ratio and another_label. The second label appears again in the inner block. In the inner block, another_label.denominator refers to the local variable denominator, not to the global variable denominator, which results in the error ZERO_DIVIDE.

Example 2-23 Block with Multiple and Duplicate Labels

<<compute_ratio>>
<<another_label>>
DECLARE
  numerator   NUMBER := 22;
  denominator NUMBER := 7;
BEGIN
  <<another_label>>
  DECLARE
    denominator NUMBER := 0;
  BEGIN
    DBMS_OUTPUT.PUT_LINE('Ratio with compute_ratio.denominator = ');
    DBMS_OUTPUT.PUT_LINE(numerator/compute_ratio.denominator);
 
    DBMS_OUTPUT.PUT_LINE('Ratio with another_label.denominator = ');
    DBMS_OUTPUT.PUT_LINE(numerator/another_label.denominator);
 
  EXCEPTION
    WHEN ZERO_DIVIDE THEN
      DBMS_OUTPUT.PUT_LINE('Divide-by-zero error: can''t divide '
        || numerator || ' by ' || denominator);
    WHEN OTHERS THEN
      DBMS_OUTPUT.PUT_LINE('Unexpected error.');
  END another_label;
END compute_ratio;
/
 

Result:

Ratio with compute_ratio.denominator =
3.14285714285714285714285714285714285714
Ratio with another_label.denominator =
Divide-by-zero error: cannot divide 22 by 0

Assigning Values to Variables

After declaring a variable, you can assign a value to it in these ways:

The variable and the value must have compatible data types. One data type is compatible with another data type if it can be implicitly converted to that type. For information about implicit data conversion, see Oracle Database SQL Language Reference.

Topics

Assigning Values to Variables with the Assignment Statement

To assign the value of an expression to a variable, use this form of the assignment statement:

variable_name := expression;

For the complete syntax of the assignment statement, see "Assignment Statement". For the syntax of an expression, see "Expression".

Example 2-24 declares several variables (specifying initial values for some) and then uses assignment statements to assign the values of expressions to them.

Example 2-24 Assigning Values to Variables with Assignment Statement

DECLARE  -- You can assign initial values here
  wages          NUMBER;
  hours_worked   NUMBER := 40;
  hourly_salary  NUMBER := 22.50;
  bonus          NUMBER := 150;
  country        VARCHAR2(128);
  counter        NUMBER := 0;
  done           BOOLEAN;
  valid_id       BOOLEAN;
  emp_rec1       employees%ROWTYPE;
  emp_rec2       employees%ROWTYPE;
  TYPE commissions IS TABLE OF NUMBER INDEX BY PLS_INTEGER;
  comm_tab       commissions;
 
BEGIN  -- You can assign values here too
  wages := (hours_worked * hourly_salary) + bonus;
  country := 'France';
  country := UPPER('Canada');
  done := (counter > 100);
  valid_id := TRUE;
  emp_rec1.first_name := 'Antonio';
  emp_rec1.last_name := 'Ortiz';
  emp_rec1 := emp_rec2;
  comm_tab(5) := 20000 * 0.15;
END;
/

Assigning Values to Variables with the SELECT INTO Statement

A simple form of the SELECT INTO statement is:

SELECT select_item [, select_item ]... 
INTO variable_name [, variable_name ]...
FROM table_name;

For each select_item, there must be a corresponding, type-compatible variable_name. Because SQL does not have a BOOLEAN type, variable_name cannot be a BOOLEAN variable. For the complete syntax of the SELECT INTO statement, see "SELECT INTO Statement".

Example 2-25 uses a SELECT INTO statement to assign to the variable bonus the value that is 10% of the salary of the employee whose employee_id is 100.

Example 2-25 Assigning Value to Variable with SELECT INTO Statement

DECLARE
  bonus   NUMBER(8,2);
BEGIN
  SELECT salary * 0.10 INTO bonus
  FROM employees
  WHERE employee_id = 100;
END;

DBMS_OUTPUT.PUT_LINE('bonus = ' || TO_CHAR(bonus));
/

Result:

bonus = 2646

Assigning Values to Variables as Parameters of a Subprogram

If you pass a variable to a subprogram as an OUT or IN OUT parameter, and the subprogram assigns a value to the parameter, the variable retains that value after the subprogram finishes running. For more information, see "Subprogram Parameters".

Example 2-26 passes the variable new_sal to the procedure adjust_salary. The procedure assigns a value to the corresponding formal parameter, sal. Because sal is an IN OUT parameter, the variable new_sal retains the assigned value after the procedure finishes running.

Example 2-26 Assigning Value to Variable as IN OUT Subprogram Parameter

DECLARE
  emp_salary  NUMBER(8,2);
 
  PROCEDURE adjust_salary (
    emp        NUMBER, 
    sal IN OUT NUMBER,
    adjustment NUMBER
  ) IS
  BEGIN
    sal := sal + adjustment;
  END;
 
BEGIN
  SELECT salary INTO emp_salary
  FROM employees
  WHERE employee_id = 100;
 
  DBMS_OUTPUT.PUT_LINE
   ('Before invoking procedure, emp_salary: ' || emp_salary);
 
  adjust_salary (100, emp_salary, 1000);
 
  DBMS_OUTPUT.PUT_LINE
   ('After invoking procedure, emp_salary: ' || emp_salary);
END;
/
 

Result:

Before invoking procedure, emp_salary: 24000
After invoking procedure, emp_salary: 25000

Assigning Values to BOOLEAN Variables

The only values that you can assign to a BOOLEAN variable are TRUE, FALSE, and NULL.

Example 2-27 initializes the BOOLEAN variable done to NULL by default, assigns it the literal value FALSE, compares it to the literal value TRUE, and assigns it the value of a BOOLEAN expression.

Example 2-27 Assigning Value to BOOLEAN Variable

DECLARE
  done    BOOLEAN;              -- Initial value is NULL by default
  counter NUMBER := 0;
BEGIN
  done := FALSE;                -- Assign literal value
  WHILE done != TRUE            -- Compare to literal value
    LOOP
      counter := counter + 1;
      done := (counter > 500);  -- Assign value of BOOLEAN expression
    END LOOP;
END;
/

For more information about the BOOLEAN data type, see "BOOLEAN Data Type".

Expressions

An expression always returns a single value. The simplest expressions, in order of increasing complexity, are:

  1. A single constant or variable (for example, a)

  2. A unary operator and its single operand (for example, -a)

  3. A binary operator and its two operands (for example, a+b)

An operand can be a variable, constant, literal, operator, function invocation, or placeholder—or another expression. Therefore, expressions can be arbitrarily complex. For expression syntax, see "Expression".

The data types of the operands determine the data type of the expression. Every time the expression is evaluated, a single value of that data type results. The data type of that result is the data type of the expression.

Topics

Concatenation Operator

The concatenation operator (||) appends one string operand to another, as Example 2-28 shows.

Example 2-28 Concatenation Operator

DECLARE
  x VARCHAR2(4) := 'suit';
  y VARCHAR2(4) := 'case';
BEGIN
  DBMS_OUTPUT.PUT_LINE (x || y);
END;
/
 

Result:

suitcase

The concatenation operator ignores null operands, as Example 2-29 shows.

Example 2-29 Concatenation Operator with NULL Operands

BEGIN
  DBMS_OUTPUT.PUT_LINE ('apple' || NULL || NULL || 'sauce');
END;
/
 

Result:

applesauce

For more information about the syntax of the concatenation operator, see "character_expression ::=".

Operator Precedence

An operation is either a unary operator and its single operand or a binary operator and its two operands. The operations in an expression are evaluated in order of operator precedence.

Table 2-3 shows operator precedence from highest to lowest. Operators with equal precedence are evaluated in no particular order.

Table 2-3 Operator Precedence

Operator Operation

**

exponentiation

+, -

identity, negation

*, /

multiplication, division

+, -, ||

addition, subtraction, concatenation

=, <, >, <=, >=, <>, !=, ~=, ^=, IS NULL, LIKE, BETWEEN, IN

comparison

NOT

negation

AND

conjunction

OR

inclusion


To control the order of evaluation, enclose operations in parentheses, as in Example 2-30.

Example 2-30 Controlling Evaluation Order with Parentheses

DECLARE
  a INTEGER := 1+2**2;
  b INTEGER := (1+2)**2;
BEGIN
  DBMS_OUTPUT.PUT_LINE('a = ' || TO_CHAR(a));
  DBMS_OUTPUT.PUT_LINE('b = ' || TO_CHAR(b));
END;
/

Result:

a = 5
b = 9

When parentheses are nested, the most deeply nested operations are evaluated first.

In Example 2-31, the operations (1+2) and (3+4) are evaluated first, producing the values 3 and 7, respectively. Next, the operation 3*7 is evaluated, producing the result 21. Finally, the operation 21/7 is evaluated, producing the final value 3.

Example 2-31 Expression with Nested Parentheses

DECLARE
  a INTEGER := ((1+2)*(3+4))/7;
BEGIN
  DBMS_OUTPUT.PUT_LINE('a = ' || TO_CHAR(a));
END;
/

Result:

a = 3

You can also use parentheses to improve readability, as in Example 2-32, where the parentheses do not affect evaluation order.

Example 2-32 Improving Readability with Parentheses

DECLARE
  a INTEGER := 2**2*3**2;
  b INTEGER := (2**2)*(3**2);
BEGIN
  DBMS_OUTPUT.PUT_LINE('a = ' || TO_CHAR(a));
  DBMS_OUTPUT.PUT_LINE('b = ' || TO_CHAR(b));
END;
/

Result:

a = 36
b = 36

Example 2-33 shows the effect of operator precedence and parentheses in several more complex expressions.

Example 2-33 Operator Precedence

DECLARE
  salary      NUMBER := 60000;
  commission  NUMBER := 0.10;
BEGIN
  -- Division has higher precedence than addition:
  
  DBMS_OUTPUT.PUT_LINE('5 + 12 / 4 = ' || TO_CHAR(5 + 12 / 4));
  DBMS_OUTPUT.PUT_LINE('12 / 4 + 5 = ' || TO_CHAR(12 / 4 + 5));
  
 -- Parentheses override default operator precedence:
 
  DBMS_OUTPUT.PUT_LINE('8 + 6 / 2 = ' || TO_CHAR(8 + 6 / 2));
  DBMS_OUTPUT.PUT_LINE('(8 + 6) / 2 = ' || TO_CHAR((8 + 6) / 2));
 
  -- Most deeply nested operation is evaluated first:
 
  DBMS_OUTPUT.PUT_LINE('100 + (20 / 5 + (7 - 3)) = '
                      || TO_CHAR(100 + (20 / 5 + (7 - 3))));
 
  -- Parentheses, even when unnecessary, improve readability:
 
  DBMS_OUTPUT.PUT_LINE('(salary * 0.05) + (commission * 0.25) = '
    || TO_CHAR((salary * 0.05) + (commission * 0.25))
  );
 
  DBMS_OUTPUT.PUT_LINE('salary * 0.05 + commission * 0.25 = '
    || TO_CHAR(salary * 0.05 + commission * 0.25)
  );
END;
/
 

Result:

5 + 12 / 4 = 8
12 / 4 + 5 = 8
8 + 6 / 2 = 11
(8 + 6) / 2 = 7
100 + (20 / 5 + (7 - 3)) = 108
(salary * 0.05) + (commission * 0.25) = 3000.025
salary * 0.05 + commission * 0.25 = 3000.025

Logical Operators

The logical operators AND, OR, and NOT follow the tri-state logic shown in Table 2-4. AND and OR are binary operators; NOT is a unary operator.

Table 2-4 Logical Truth Table

x y x AND y x OR y NOT x

TRUE

TRUE

TRUE

TRUE

FALSE

TRUE

FALSE

FALSE

TRUE

FALSE

TRUE

NULL

NULL

TRUE

FALSE

FALSE

TRUE

FALSE

TRUE

TRUE

FALSE

FALSE

FALSE

FALSE

TRUE

FALSE

NULL

FALSE

NULL

TRUE

NULL

TRUE

NULL

TRUE

NULL

NULL

FALSE

FALSE

NULL

NULL

NULL

NULL

NULL

NULL

NULL


Example 2-34 creates a procedure, print_boolean, that prints the value of a BOOLEAN variable. The procedure uses the "IS [NOT] NULL Operator". Several examples in this chapter invoke print_boolean.

Example 2-34 Procedure Prints BOOLEAN Variable

CREATE OR REPLACE PROCEDURE print_boolean (
  b_name   VARCHAR2,
  b_value  BOOLEAN
) IS
BEGIN
  IF b_value IS NULL THEN
    DBMS_OUTPUT.PUT_LINE (b_name || ' = NULL');
  ELSIF b_value = TRUE THEN
    DBMS_OUTPUT.PUT_LINE (b_name || ' = TRUE');
  ELSE
    DBMS_OUTPUT.PUT_LINE (b_name || ' = FALSE');
  END IF;
END;
/
 

As Table 2-4 and Example 2-35 show, AND returns TRUE if and only if both operands are TRUE.

Example 2-35 AND Operator

DECLARE
  PROCEDURE print_x_and_y (
    x  BOOLEAN,
    y  BOOLEAN
  ) IS
  BEGIN
   print_boolean ('x', x);
   print_boolean ('y', y);
   print_boolean ('x AND y', x AND y);
 END print_x_and_y;
 
BEGIN
 print_x_and_y (FALSE, FALSE);
 print_x_and_y (TRUE, FALSE);
 print_x_and_y (FALSE, TRUE);
 print_x_and_y (TRUE, TRUE);
 
 print_x_and_y (TRUE, NULL);
 print_x_and_y (FALSE, NULL);
 print_x_and_y (NULL, TRUE);
 print_x_and_y (NULL, FALSE);
END;
/
 

Result:

x = FALSE
y = FALSE
x AND y = FALSE
x = TRUE
y = FALSE
x AND y = FALSE
x = FALSE
y = TRUE
x AND y = FALSE
x = TRUE
y = TRUE
x AND y = TRUE
x = TRUE
y = NULL
x AND y = NULL
x = FALSE
y = NULL
x AND y = FALSE
x = NULL
y = TRUE
x AND y = NULL
x = NULL
y = FALSE
x AND y = FALSE

As Table 2-4 and Example 2-36 show, OR returns TRUE if either operand is TRUE. (Example 2-36 invokes the print_boolean procedure from Example 2-35.)

Example 2-36 OR Operator

DECLARE
  PROCEDURE print_x_or_y (
    x  BOOLEAN,
    y  BOOLEAN
  ) IS
  BEGIN
    print_boolean ('x', x);
    print_boolean ('y', y);
    print_boolean ('x OR y', x OR y);
  END print_x_or_y;
 
BEGIN
  print_x_or_y (FALSE, FALSE);
  print_x_or_y (TRUE, FALSE);
  print_x_or_y (FALSE, TRUE);
  print_x_or_y (TRUE, TRUE);
 
  print_x_or_y (TRUE, NULL);
  print_x_or_y (FALSE, NULL);
  print_x_or_y (NULL, TRUE);
  print_x_or_y (NULL, FALSE);
END;
/
 

Result:

x = FALSE
y = FALSE
x OR y = FALSE
x = TRUE
y = FALSE
x OR y = TRUE
x = FALSE
y = TRUE
x OR y = TRUE
x = TRUE
y = TRUE
x OR y = TRUE
x = TRUE
y = NULL
x OR y = TRUE
x = FALSE
y = NULL
x OR y = NULL
x = NULL
y = TRUE
x OR y = TRUE
x = NULL
y = FALSE
x OR y = NULL

As Table 2-4 and Example 2-37 show, NOT returns the opposite of its operand, unless the operand is NULL. NOT NULL returns NULL, because NULL is an indeterminate value. (Example 2-37 invokes the print_boolean procedure from Example 2-35.)

Example 2-37 NOT Operator

DECLARE
  PROCEDURE print_not_x (
    x  BOOLEAN
  ) IS
  BEGIN
    print_boolean ('x', x);
    print_boolean ('NOT x', NOT x);
  END print_not_x;
 
BEGIN
  print_not_x (TRUE);
  print_not_x (FALSE);
  print_not_x (NULL);
END;
/
 

Result:

x = TRUE
NOT x = FALSE
x = FALSE
NOT x = TRUE
x = NULL
NOT x = NULL

In Example 2-38, you might expect the sequence of statements to run because x and y seem unequal. But, NULL values are indeterminate. Whether x equals y is unknown. Therefore, the IF condition yields NULL and the sequence of statements is bypassed.

Example 2-38 NULL Value in Unequal Comparison

DECLARE
  x NUMBER := 5;
  y NUMBER := NULL;
BEGIN
  IF x != y THEN  -- yields NULL, not TRUE
    DBMS_OUTPUT.PUT_LINE('x != y');  -- not run
  ELSIF x = y THEN -- also yields NULL
    DBMS_OUTPUT.PUT_LINE('x = y');
  ELSE
    DBMS_OUTPUT.PUT_LINE
      ('Can''t tell if x and y are equal or not.');
  END IF;
END;
/
 

Result:

Can't tell if x and y are equal or not.

In Example 2-39, you might expect the sequence of statements to run because a and b seem equal. But, again, that is unknown, so the IF condition yields NULL and the sequence of statements is bypassed.

Example 2-39 NULL Value in Equal Comparison

DECLARE
  a NUMBER := NULL;
  b NUMBER := NULL;
BEGIN
  IF a = b THEN  -- yields NULL, not TRUE
    DBMS_OUTPUT.PUT_LINE('a = b');  -- not run
  ELSIF a != b THEN  -- yields NULL, not TRUE
    DBMS_OUTPUT.PUT_LINE('a != b');  -- not run
  ELSE
    DBMS_OUTPUT.PUT_LINE('Can''t tell if two NULLs are equal');
  END IF;
END;
/
 

Result:

Can't tell if two NULLs are equal

In Example 2-40, the two IF statements appear to be equivalent. However, if either x or y is NULL, then the first IF statement assigns the value of y to high and the second IF statement assigns the value of x to high.

Example 2-40 NOT NULL Equals NULL

DECLARE
  x    INTEGER := 2;
  Y    INTEGER := 5;
  high INTEGER;
BEGIN
  IF (x > y)       -- If x or y is NULL, then (x > y) is NULL
    THEN high := x;  -- run if (x > y) is TRUE
    ELSE high := y;  -- run if (x > y) is FALSE or NULL
  END IF;
  
  IF NOT (x > y)   -- If x or y is NULL, then NOT (x > y) is NULL
    THEN high := y;  -- run if NOT (x > y) is TRUE
    ELSE high := x;  -- run if NOT (x > y) is FALSE or NULL
  END IF;
END;
/

Example 2-41 invokes the print_boolean procedure from Example 2-35 three times. The third and first invocation are logically equivalent—the parentheses in the third invocation only improve readability. The parentheses in the second invocation change the order of operation.

Example 2-41 Changing Evaluation Order of Logical Operators

DECLARE
  x  BOOLEAN := FALSE;
  y  BOOLEAN := FALSE;
  
BEGIN
  print_boolean ('NOT x AND y', NOT x AND y);
  print_boolean ('NOT (x AND y)', NOT (x AND y));
  print_boolean ('(NOT x) AND y', (NOT x) AND y);
END;
/
 

Result:

NOT x AND y = FALSE
NOT (x AND y) = TRUE
(NOT x) AND y = FALSE

Short-Circuit Evaluation

When evaluating a logical expression, PL/SQL uses short-circuit evaluation. That is, PL/SQL stops evaluating the expression as soon as it can determine the result. Therefore, you can write expressions that might otherwise cause errors.

In Example 2-42, short-circuit evaluation prevents the OR expression from causing a divide-by-zero error. When the value of on_hand is zero, the value of the left operand is TRUE, so PL/SQL does not evaluate the right operand. If PL/SQL evaluated both operands before applying the OR operator, the right operand would cause a division by zero error.

Example 2-42 Short-Circuit Evaluation

DECLARE
  on_hand  INTEGER := 0;
  on_order INTEGER := 100;
BEGIN
  -- Does not cause divide-by-zero error;
  -- evaluation stops after first expression
  
  IF (on_hand = 0) OR ((on_order / on_hand) < 5) THEN
    DBMS_OUTPUT.PUT_LINE('On hand quantity is zero.');
  END IF;
END;
/
 

Result:

On hand quantity is zero.

Comparison Operators

Comparison operators compare one expression to another. The result is always either TRUE, FALSE, or NULL. If the value of one expression is NULL, then the result of the comparison is also NULL.

The comparison operators are:

Note:

Using CLOB values with comparison operators can create temporary LOB values. Ensure that your temporary tablespace is large enough to handle them.

Relational Operators

Example 2-42 summarizes the relational operators.

Table 2-5 Relational Operators

Operator Meaning

=

equal to

<>, !=, ~=, ^=

not equal to

<

less than

>

greater than

<=

less than or equal to

>=

greater than or equal to


Topics

Arithmetic Comparisons

One number is greater than another if it represents a larger quantity. Real numbers are stored as approximate values, so Oracle recommends comparing them for equality or inequality.

Example 2-43 invokes the print_boolean procedure from Example 2-35 to print the values of expressions that use relational operators to compare arithmetic values.

Example 2-43 Relational Operators in Expressions

BEGIN
  print_boolean ('(2 + 2 =  4)', 2 + 2 = 4);
  
  print_boolean ('(2 + 2 <> 4)', 2 + 2 <> 4);
  print_boolean ('(2 + 2 != 4)', 2 + 2 != 4);
  print_boolean ('(2 + 2 ~= 4)', 2 + 2 ~= 4);
  print_boolean ('(2 + 2 ^= 4)', 2 + 2 ^= 4);
  
  print_boolean ('(1 < 2)', 1 < 2);
 
  print_boolean ('(1 > 2)', 1 > 2);
 
  print_boolean ('(1 <= 2)', 1 <= 2);
 
  print_boolean ('(1 >= 1)', 1 >= 1);
END;
/
 

Result:

(2 + 2 =  4) = TRUE
(2 + 2 <> 4) = FALSE
(2 + 2 != 4) = FALSE
(2 + 2 ~= 4) = FALSE
(2 + 2 ^= 4) = FALSE
(1 < 2) = TRUE
(1 > 2) = FALSE
(1 <= 2) = TRUE
(1 >= 1) = TRUE
BOOLEAN Comparisons

By definition, TRUE is greater than FALSE. Any comparison with NULL returns NULL.

Character Comparisons

By default, one character is greater than another if its binary value is larger. For example, this expression is true:

'y' > 'r'

Strings are compared character by character. For example, this expression is true:

'Kathy' > 'Kathryn'

If you set the initialization parameter NLS_COMP=ANSI, string comparisons use the collating sequence identified by the NLS_SORT initialization parameter.

A collating sequence is an internal ordering of the character set in which a range of numeric codes represents the individual characters. One character value is greater than another if its internal numeric value is larger. Each language might have different rules about where such characters occur in the collating sequence. For example, an accented letter might be sorted differently depending on the database character set, even though the binary value is the same in each case.

By changing the value of the NLS_SORT parameter, you can perform comparisons that are case-insensitive and accent-insensitive.

A case-insensitive comparison treats corresponding uppercase and lowercase letters as the same letter. For example, these expressions are true:

'a' = 'A'
'Alpha' = 'ALPHA'

To make comparisons case-insensitive, append _CI to the value of the NLS_SORT parameter (for example, BINARY_CI or XGERMAN_CI).

An accent-insensitive comparison is case-insensitive, and also treats letters that differ only in accents or punctuation characters as the same letter. For example, these expressions are true:

'Cooperate' = 'Co-Operate'
'Co-Operate' = 'coöperate'

To make comparisons both case-insensitive and accent-insensitive, append _AI to the value of the NLS_SORT parameter (for example, BINARY_AI or FRENCH_M_AI).

Semantic differences between the CHAR and VARCHAR2 data types affect character comparisons. For more information, see "Value Comparisons".

Date Comparisons

One date is greater than another if it is more recent. For example, this expression is true:

'01-JAN-91' > '31-DEC-90'

IS [NOT] NULL Operator

The IS NULL operator returns the BOOLEAN value TRUE if its operand is NULL or FALSE if it is not NULL. The IS NOT NULL operator does the opposite. Comparisons involving NULL values always yield NULL.

To test whether a value is NULL, use IF value IS NULL, as in these examples:

LIKE Operator

The LIKE operator compares a character, string, or CLOB value to a pattern and returns TRUE if the value matches the pattern and FALSE if it does not.

The pattern can include the two wildcard characters underscore (_) and percent sign (%). Underscore matches exactly one character. Percent sign (%) matches zero or more characters.

Case is significant. The string 'Johnson' matches the pattern 'J%s_n' but not 'J%S_N', as Example 2-44 shows.

Example 2-44 LIKE Operator in Expression

DECLARE
  PROCEDURE compare (
    value   VARCHAR2,
    pattern VARCHAR2
  ) IS
  BEGIN
    IF value LIKE pattern THEN
      DBMS_OUTPUT.PUT_LINE ('TRUE');
    ELSE
      DBMS_OUTPUT.PUT_LINE ('FALSE');
    END IF;
  END;
BEGIN
  compare('Johnson', 'J%s_n');
  compare('Johnson', 'J%S_N');
END;
/
 

Result:

TRUE
FALSE

To search for the percent sign or underscore, define an escape character and put it before the percent sign or underscore.

Example 2-45 uses the backslash as the escape character, so that the percent sign in the string does not act as a wildcard.

Example 2-45 Escape Character in Pattern

DECLARE
  PROCEDURE half_off (sale_sign VARCHAR2) IS
  BEGIN
    IF sale_sign LIKE '50\% off!' ESCAPE '\' THEN
      DBMS_OUTPUT.PUT_LINE ('TRUE');
    ELSE
      DBMS_OUTPUT.PUT_LINE ('FALSE');
    END IF;
  END;
BEGIN
  half_off('Going out of business!');
  half_off('50% off!');
END;
/
 

Result:

FALSE
TRUE

BETWEEN Operator

The BETWEEN operator tests whether a value lies in a specified range. x BETWEEN a AND b returns the same value as (x>=a) AND (x<=b).

Example 2-46 invokes the print_boolean procedure from Example 2-35 to print the values of expressions that include the BETWEEN operator.

Example 2-46 BETWEEN Operator in Expressions

BEGIN
  print_boolean ('2 BETWEEN 1 AND 3', 2 BETWEEN 1 AND 3);
  print_boolean ('2 BETWEEN 2 AND 3', 2 BETWEEN 2 AND 3);
  print_boolean ('2 BETWEEN 1 AND 2', 2 BETWEEN 1 AND 2);
  print_boolean ('2 BETWEEN 3 AND 4', 2 BETWEEN 3 AND 4);
END;
/
 

Result:

2 BETWEEN 1 AND 3 = TRUE
2 BETWEEN 2 AND 3 = TRUE
2 BETWEEN 1 AND 2 = TRUE
2 BETWEEN 3 AND 4 = FALSE

IN Operator

The IN operator tests set membership. x IN (set) returns TRUE only if x equals a member of set.

Example 2-47 invokes the print_boolean procedure from Example 2-35 to print the values of expressions that include the IN operator.

Example 2-47 IN Operator in Expressions

DECLARE
  letter VARCHAR2(1) := 'm';
BEGIN
  print_boolean (
    'letter IN (''a'', ''b'', ''c'')',
    letter IN ('a', 'b', 'c')
  );
  print_boolean (
    'letter IN (''z'', ''m'', ''y'', ''p'')',
    letter IN ('z', 'm', 'y', 'p')
  );
END;
/
 

Result:

letter IN ('a', 'b', 'c') = FALSE
letter IN ('z', 'm', 'y', 'p') = TRUE
 

Example 2-48 shows what happens when set includes a NULL value. (Example 2-48 invokes the print_boolean procedure from Example 2-35.)

Example 2-48 IN Operator with Sets with NULL Values

DECLARE
  a INTEGER; -- Initialized to NULL by default
  b INTEGER := 10;
  c INTEGER := 100;
BEGIN
  print_boolean ('100 IN (a, b, c)', 100 IN (a, b, c));
  print_boolean ('100 NOT IN (a, b, c)', 100 NOT IN (a, b, c));
  
  print_boolean ('100 IN (a, b)', 100 IN (a, b));
  print_boolean ('100 NOT IN (a, b)', 100 NOT IN (a, b));
 
  print_boolean ('a IN (a, b)', a IN (a, b));
  print_boolean ('a NOT IN (a, b)', a NOT IN (a, b));
END;
/
 

Result:

100 IN (a, b, c) = TRUE
100 NOT IN (a, b, c) = FALSE
100 IN (a, b) = NULL
100 NOT IN (a, b) = NULL
a IN (a, b) = NULL
a NOT IN (a, b) = NULL

BOOLEAN Expressions

A BOOLEAN expression is an expression that returns a BOOLEAN value—TRUE, FALSE, or NULL. The simplest BOOLEAN expression is a BOOLEAN literal, constant, or variable. The following are also BOOLEAN expressions:

NOT boolean_expression
boolean_expression relational_operator boolean_expression
boolean_expression { AND | OR } boolean_expression

For a list of relational operators, see Table 2-5. For the complete syntax of a BOOLEAN expression, see "boolean_expression ::=".

Typically, you use BOOLEAN expressions as conditions in control statements (explained in Chapter 4, "PL/SQL Control Statements") and in WHERE clauses of DML statements.

You can use a BOOLEAN variable itself as a condition; you need not compare it to the value TRUE or FALSE. In Example 2-49, the conditions in the loops are equivalent.

Example 2-49 Equivalent BOOLEAN Expressions

DECLARE
  done BOOLEAN;
BEGIN
  -- These WHILE loops are equivalent
  
  done := FALSE;
  WHILE done = FALSE
    LOOP
      done := TRUE;
    END LOOP;
 
  done := FALSE;
  WHILE NOT (done = TRUE)
    LOOP
      done := TRUE;
    END LOOP;
 
  done := FALSE;
  WHILE NOT done
    LOOP
      done := TRUE;
    END LOOP;
END;
/

CASE Expressions

Topics

Simple CASE Expression

For this explanation, assume that a simple CASE expression has this syntax:

CASE selector
WHEN selector_value_1 THEN result_1
WHEN selector_value_2 THEN result_2
...
WHEN selector_value_n THEN result_n
[ ELSE
  else_result ]
END

The selector is an expression (typically a single variable). Each selector_value and each result can be either a literal or an expression.

The simple CASE expression returns the first result for which selector_value matches selector. Remaining expressions are not evaluated. If no selector_value matches selector, the CASE expression returns else_result if it exists and NULL otherwise.

See Also:

"simple_case_expression ::=" for the complete syntax

Example 2-50 assigns the value of a simple CASE expression to the variable appraisal. The selector is grade.

Example 2-50 Simple CASE Expression

DECLARE
  grade CHAR(1) := 'B';
  appraisal VARCHAR2(20);
BEGIN
  appraisal :=
    CASE grade
      WHEN 'A' THEN 'Excellent'
      WHEN 'B' THEN 'Very Good'
      WHEN 'C' THEN 'Good'
      WHEN 'D' THEN 'Fair'
      WHEN 'F' THEN 'Poor'
      ELSE 'No such grade'
    END;
    DBMS_OUTPUT.PUT_LINE ('Grade ' || grade || ' is ' || appraisal);
END;
/
 

Result:

Grade B is Very Good

If selector has the value NULL, it cannot be matched by WHEN NULL, as Example 2-51 shows. Instead, use a searched CASE expression with WHEN boolean_expression IS NULL, as in Example 2-53.

Example 2-51 Simple CASE Expression with WHEN NULL

DECLARE
  grade CHAR(1); -- NULL by default
  appraisal VARCHAR2(20);
BEGIN
  appraisal :=
  CASE grade
    WHEN NULL THEN 'No grade assigned'
    WHEN 'A' THEN 'Excellent'
    WHEN 'B' THEN 'Very Good'
    WHEN 'C' THEN 'Good'
    WHEN 'D' THEN 'Fair'
    WHEN 'F' THEN 'Poor'
    ELSE 'No such grade'
  END;
  DBMS_OUTPUT.PUT_LINE ('Grade ' || grade || ' is ' || appraisal);
END;
/

Result:

Grade  is No such grade

Searched CASE Expression

For this explanation, assume that a searched CASE expression has this syntax:

CASE
WHEN boolean_expression_1 THEN result_1
WHEN boolean_expression_2 THEN result_2
...
WHEN boolean_expression_n THEN result_n
[ ELSE
  else_result ]
END]

The searched CASE expression returns the first result for which boolean_expression is TRUE. Remaining expressions are not evaluated. If no boolean_expression is TRUE, the CASE expression returns else_result if it exists and NULL otherwise.

See Also:

"searched_case_expression ::=" for the complete syntax

Example 2-52 assigns the value of a searched CASE expression to the variable appraisal.

Example 2-52 Searched CASE Expression

DECLARE
  grade      CHAR(1) := 'B';
  appraisal  VARCHAR2(120);
  id         NUMBER  := 8429862;
  attendance NUMBER := 150;
  min_days   CONSTANT NUMBER := 200;
  
  FUNCTION attends_this_school (id NUMBER)
    RETURN BOOLEAN IS
  BEGIN
    RETURN TRUE;
  END;
BEGIN
  appraisal :=
  CASE
    WHEN attends_this_school(id) = FALSE
      THEN 'Student not enrolled'
    WHEN grade = 'F' OR attendance < min_days
      THEN 'Poor (poor performance or bad attendance)'
    WHEN grade = 'A' THEN 'Excellent'
    WHEN grade = 'B' THEN 'Very Good'
    WHEN grade = 'C' THEN 'Good'
    WHEN grade = 'D' THEN 'Fair'
    ELSE 'No such grade'
  END;
  DBMS_OUTPUT.PUT_LINE
    ('Result for student ' || id || ' is ' || appraisal);
END;
/
 

Result:

Result for student 8429862 is Poor (poor performance or bad attendance)

Example 2-53 uses a searched CASE expression to solve the problem in Example 2-51.

Example 2-53 Searched CASE Expression with WHEN ... IS NULL

DECLARE
  grade CHAR(1); -- NULL by default
  appraisal VARCHAR2(20);
BEGIN
  appraisal :=
    CASE
      WHEN grade IS NULL THEN 'No grade assigned'
      WHEN grade = 'A' THEN 'Excellent'
      WHEN grade = 'B' THEN 'Very Good'
      WHEN grade = 'C' THEN 'Good'
      WHEN grade = 'D' THEN 'Fair'
      WHEN grade = 'F' THEN 'Poor'
      ELSE 'No such grade'
    END;
    DBMS_OUTPUT.PUT_LINE ('Grade ' || grade || ' is ' || appraisal);
END;
/
 

Result:

Grade  is No grade assigned

SQL Functions in PL/SQL Expressions

In PL/SQL expressions, you can use all SQL functions except:

  • Aggregate functions (such as AVG and COUNT)

  • Analytic functions (such as LAG and RATIO_TO_REPORT)

  • Data mining functions (such as CLUSTER_ID and FEATURE_VALUE)

  • Encoding and decoding functions (such as DECODE and DUMP)

  • Model functions (such as ITERATION_NUMBER and PREVIOUS)

  • Object reference functions (such as REF and VALUE)

  • XML functions (such as APPENDCHILDXML and EXISTSNODE)

  • These conversion functions:

    • BIN_TO_NUM

  • These miscellaneous functions:

    • CUBE_TABLE

    • DATAOBJ_TO_PARTITION

    • LNNVL

    • NVL2

    • SYS_CONNECT_BY_PATH

    • SYS_TYPEID

    • WIDTH_BUCKET

PL/SQL supports an overload of BITAND for which the arguments and result are BINARY_INTEGER.

When used in a PL/SQL expression, the RAWTOHEX function accepts an argument of data type RAW and returns a VARCHAR2 value with the hexadecimal representation of bytes that comprise the value of the argument. Arguments of types other than RAW can be specified only if they can be implicitly converted to RAW. This conversion is possible for CHAR, VARCHAR2, and LONG values that are valid arguments of the HEXTORAW function, and for LONG RAW and BLOB values of up to 16380 bytes.

Error-Reporting Functions

PL/SQL has two error-reporting functions, SQLCODE and SQLERRM, for use in PL/SQL exception-handling code. For their descriptions, see "SQLCODE Function" and "SQLERRM Function".

You cannot use the SQLCODE and SQLERRM functions in SQL statements.

Pragmas

A pragma is an instruction to the compiler that it processes at compile time. For information about pragmas, see:

Conditional Compilation

Conditional compilation lets you customize the functionality of a PL/SQL application without removing source text. For example, you can:

Topics

How Conditional Compilation Works

Note:

The conditional compilation feature and related PL/SQL packages are available for Oracle Database 10g Release 1 (10.1.0.4) and later releases.

Conditional compilation uses selection directives, which are similar to IF statements, to select source text for compilation. The condition in a selection directive usually includes an inquiry directive. Error directives raise user-defined errors. All conditional compilation directives are built from preprocessor control tokens and PL/SQL text.

Topics

Preprocessor Control Tokens

A preprocessor control token identifies code that is processed before the PL/SQL unit is compiled.

Syntax

$plsql_identifier

There cannot be space between $ and plsql_identifier. For information about plsql_identifier, see "Identifiers". The character $ can also appear inside plsql_identifier, but it has no special meaning there.

These preprocessor control tokens are reserved:

  • $IF

  • $THEN

  • $ELSE

  • $ELSIF

  • $ERROR

Selection Directives

A selection directive selects source text to compile.

Syntax

$IF boolean_static_expression $THEN
   text
[ $ELSIF boolean_static_expression $THEN
   text
]...
[ $ELSE
   text
$END
]

For the syntax of boolean_static_expression, see "BOOLEAN Static Expressions". The text can be anything, but typically, it is either a statement (see "statement ::=") or an error directive (explained in "Error Directives").

The selection directive evaluates the BOOLEAN static expressions in the order that they appear until either one expression has the value TRUE or the list of expressions is exhausted. If one expression has the value TRUE, its text is compiled, the remaining expressions are not evaluated, and their text is not analyzed. If no expression has the value TRUE, then if $ELSE is present, its text is compiled; otherwise, no text is compiled.

For examples of selection directives, see "Conditional Compilation Examples".

See Also:

"Conditional Selection Statements" for information about the IF statement, which has the same logic as the selection directive

Error Directives

An error directive produces a user-defined error message during compilation.

Syntax

$ERROR varchar2_static_expression $END

It produces this compile-time error message, where string is the value of varchar2_static_expression:

PLS-00179: $ERROR: string

For the syntax of varchar2_static_expression, see "VARCHAR2 Static Expressions".

For an example of an error directive, see Example 2-58.

Inquiry Directives

An inquiry directive provides information about the compilation environment.

Syntax

$$name

For information about name, which is an unquoted PL/SQL identifier, see "Identifiers".

An inquiry directive typically appears in the boolean_static_expression of a selection directive, but it can appear anywhere that a variable or literal of its type can appear. Moreover, it can appear where regular PL/SQL allows only a literal (not a variable)— for example, to specify the size of a VARCHAR2 variable.

Topics

Predefined Inquiry Directives

The predefined inquiry directives are:

  • $$PLSQL_LINE

    A PLS_INTEGER literal whose value is the number of the source line on which the directive appears in the current PL/SQL unit. An example of $$PLSQL_LINE in a selection directive is:

    $IF $$PLSQL_LINE = 32 $THEN ...
    
  • $$PLSQL_UNIT

    A VARCHAR2 literal that contains the name of the current PL/SQL unit. If the current PL/SQL unit is an anonymous block, $$PLSQL_UNIT contains a NULL value. An example of $$PLSQL_UNIT in a selection directive is:

    $IF $$PLSQL_UNIT IS NULL $THEN ...
    

    Because a selection directive needs a BOOLEAN static expression, you cannot use a VARCHAR2 comparison such as:

    $IF $$PLSQL_UNIT = 'AWARD_BONUS' $THEN ...
    
  • $$plsql_compilation_parameter

    The name plsql_compilation_parameter is a PL/SQL compilation parameter (for example, PLSCOPE_SETTINGS). For descriptions of these parameters, see Table 1-2.

Example 2-54, a SQL*Plus script, uses the predefined inquiry directives $$PLSQL_LINE and $$PLSQL_UNIT as ordinary PLS_INTEGER and VARCHAR2 literals, respectively, to show how their values are assigned.

Example 2-54 Predefined Inquiry Directives $$PLSQL_LINE and $$PLSQL_UNIT

SQL> CREATE OR REPLACE PROCEDURE p
  2  IS
  3    i PLS_INTEGER;
  4  BEGIN
  5    DBMS_OUTPUT.PUT_LINE('Inside p');
  6    i := $$PLSQL_LINE;
  7    DBMS_OUTPUT.PUT_LINE('i = ' || i);
  8    DBMS_OUTPUT.PUT_LINE('$$PLSQL_LINE = ' || $$PLSQL_LINE);
  9    DBMS_OUTPUT.PUT_LINE('$$PLSQL_UNIT = ' || $$PLSQL_UNIT);
 10  END;
 11  /
 
Procedure created.
 
SQL> BEGIN
  2   p;
  3   DBMS_OUTPUT.PUT_LINE('Outside p');
  4   DBMS_OUTPUT.PUT_LINE('$$PLSQL_UNIT = ' || $$PLSQL_UNIT);
  5  END;
  6  /
 

Result:

Inside p
i = 6
$$PLSQL_LINE = 8
$$PLSQL_UNIT = P
Outside p
$$PLSQL_UNIT =
 
PL/SQL procedure successfully completed.

Example 2-55 displays the current values of PL/SQL the compilation parameters.

Example 2-55 Displaying Values of PL/SQL Compilation Parameters

BEGIN
  DBMS_OUTPUT.PUT_LINE('$$PLSCOPE_SETTINGS = '     || $$PLSCOPE_SETTINGS);
  DBMS_OUTPUT.PUT_LINE('$$PLSQL_CCFLAGS = '        || $$PLSQL_CCFLAGS);
  DBMS_OUTPUT.PUT_LINE('$$PLSQL_CODE_TYPE = '      || $$PLSQL_CODE_TYPE);
  DBMS_OUTPUT.PUT_LINE('$$PLSQL_OPTIMIZE_LEVEL = ' || $$PLSQL_OPTIMIZE_LEVEL);
  DBMS_OUTPUT.PUT_LINE('$$PLSQL_WARNINGS = '       || $$PLSQL_WARNINGS);
  DBMS_OUTPUT.PUT_LINE('$$NLS_LENGTH_SEMANTICS = ' || $$NLS_LENGTH_SEMANTICS);
END;
/

Result:

$$PLSCOPE_SETTINGS =
$$PLSQL_CCFLAGS = 99
$$PLSQL_CODE_TYPE = INTERPRETED
$$PLSQL_OPTIMIZE_LEVEL = 2
$$PLSQL_WARNINGS = ENABLE:ALL
$$NLS_LENGTH_SEMANTICS = BYTE

Note:

In the SQL*Plus environment, you can display the current values of initialization parameters, including the PL/SQL compilation parameters, with the command SHOW PARAMETERS. For more information about the SHOW command and its PARAMETERS option, see SQL*Plus User's Guide and Reference.
Assigning Values to Inquiry Directives

You can assign values to inquiry directives with the PLSQL_CCFLAGS compilation parameter. For example:

ALTER SESSION SET PLSQL_CCFLAGS = 
  'name1:value1, name2:value2, ... namen:valuen'

Each value must be either a BOOLEAN literal (TRUE, FALSE, or NULL) a or PLS_INTEGER literal. The data type of value determines the data type of name.

The same name can appear multiple times, with values of the same or different data types. Later assignments override earlier assignments. For example, this command sets the value of $$flag to 5 and its data type to PLS_INTEGER:

ALTER SESSION SET PLSQL_CCFLAGS = 'flag:TRUE, flag:5'

Oracle recommends against using PLSQL_CCFLAGS to assign values to predefined inquiry directives, including compilation parameters. To assign values to compilation parameters, Oracle recommends using the ALTER SESSION statement. For more information about the ALTER SESSION statement, see Oracle Database SQL Language Reference.

Example 2-56 uses PLSQL_CCFLAGS to assign a value to the user-defined inquiry directive $$Some_Flag and (though not recommended) to itself. Because later assignments override earlier assignments, the resulting value of $$Some_Flag is 2 and the resulting value of PLSQL_CCFLAGS is the value that it assigns to itself (99), not the value that the ALTER SESSION statement assigns to it ('Some_Flag:1, Some_Flag:2, PLSQL_CCFlags:99').

Example 2-56 PLSQL_CCFLAGS Assigns Value to Itself

ALTER SESSION SET
PLSQL_CCFlags = 'Some_Flag:1, Some_Flag:2, PLSQL_CCFlags:99'
/
BEGIN
  DBMS_OUTPUT.PUT_LINE($$Some_Flag);
  DBMS_OUTPUT.PUT_LINE($$PLSQL_CCFlags);
END;
/

Result:

2
99

Note:

The compile-time value of PLSQL_CCFLAGS is stored with the metadata of stored PL/SQL units, which means that you can reuse the value when you explicitly recompile the units. For more information, see "PL/SQL Units and Compilation Parameters".

For more information about PLSQL_CCFLAGS, see Oracle Database Reference.

Unresolvable Inquiry Directives

If an inquiry directive ($$name) cannot be resolved (that is, if its value cannot be determined) and the source text is not wrapped, then PL/SQL issues the warning PLW-6003 and substitutes NULL for the value of the unresolved inquiry directive. If the source text is wrapped, the warning message is disabled, so that the unresolved inquiry directive is not revealed. For information about wrapping PL/SQL source text, see Appendix A, "PL/SQL Source Text Wrapping".

Static Expressions

A static expression is an expression whose value can be determined at compilation time (that is, it does not include references to variables or functions). Static expressions are the only expressions that can appear in conditional compilation directives.

Topics

See Also:

"Expressions" for general information about expressions
PLS_INTEGER Static Expressions

PLS_INTEGER static expressions are:

  • PLS_INTEGER literals

    For information about literals, see "Literals".

  • PLS_INTEGER static constants

    For information about static constants, see "Static Constants".

  • NULL

See Also:

"PLS_INTEGER and BINARY_INTEGER Data Types" for information about the PLS_INTEGER data type
BOOLEAN Static Expressions

BOOLEAN static expressions are:

  • BOOLEAN literals (TRUE, FALSE, or NULL)

  • BOOLEAN static constants

    For information about static constants, see "Static Constants".

  • Where x and y are PLS_INTEGER static expressions:

    • x > y

    • x < y

    • x >= y

    • x <= y

    • x = y

    • x <> y

    For information about PLS_INTEGER static expressions, see "PLS_INTEGER Static Expressions".

  • Where x and y are BOOLEAN expressions:

    • NOT y

    • x AND y

    • x OR y

    • x > y

    • x >= y

    • x = y

    • x <= y

    • x <> y

    For information about BOOLEAN expressions, see "BOOLEAN Expressions".

  • Where x is a static expression:

    • x IS NULL

    • x IS NOT NULL

    For information about static expressions, see "Static Expressions".

See Also:

"BOOLEAN Data Type" for information about the BOOLEAN data type
VARCHAR2 Static Expressions

VARCHAR2 static expressions are:

  • String literal with maximum size of 32,767 bytes

    For information about literals, see "Literals".

  • NULL

  • TO_CHAR(x), where x is a PLS_INTEGER static expression

    For information about the TO_CHAR function, see Oracle Database SQL Language Reference.

  • TO_CHAR(x, f, n) where x is a PLS_INTEGER static expression and f and n are VARCHAR2 static expressions

    For information about the TO_CHAR function, see Oracle Database SQL Language Reference.

  • x || y where x and y are VARCHAR2 or PLS_INTEGER static expressions

    For information about PLS_INTEGER static expressions, see "PLS_INTEGER Static Expressions".

See Also:

"CHAR and VARCHAR2 Variables" for information about the VARCHAR2 data type
Static Constants

A static constant is declared in a package specification with this syntax:

constant_name CONSTANT data_type := static_expression;

The type of static_expression must be the same as data_type (either BOOLEAN or PLS_INTEGER).

The static constant must always be referenced as package_name.constant_name, even in the body of the package_name package.

If you use constant_name in the BOOLEAN expression in a conditional compilation directive in a PL/SQL unit, then the PL/SQL unit depends on the package package_name. If you alter the package specification, the dependent PL/SQL unit might become invalid and need recompilation (for information about the invalidation of dependent objects, see Oracle Database Advanced Application Developer's Guide).

If you use a package with static constants to control conditional compilation in multiple PL/SQL units, Oracle recommends that you create only the package specification, and dedicate it exclusively to controlling conditional compilation. This practice minimizes invalidations caused by altering the package specification.

To control conditional compilation in a single PL/SQL unit, you can set flags in the PLSQL_CCFLAGS compilation parameter. For information about this parameter, see "Assigning Values to Inquiry Directives" and Oracle Database Reference.

In Example 2-57, the package my_debug defines the static constants debug and trace to control debugging and tracing in multiple PL/SQL units. The procedure my_proc1 uses only debug, and the procedure my_proc2 uses only trace, but both procedures depend on the package. However, the recompiled code might not be different. For example, if you only change the value of debug to FALSE and then recompile the two procedures, the compiled code for my_proc1 changes, but the compiled code for my_proc2 does not.

Example 2-57 Static Constants

CREATE PACKAGE my_debug IS
  debug CONSTANT BOOLEAN := TRUE;
  trace CONSTANT BOOLEAN := TRUE;
END my_debug;
/
 
CREATE PROCEDURE my_proc1 IS
BEGIN
  $IF my_debug.debug $THEN
    DBMS_OUTPUT.put_line('Debugging ON');
  $ELSE
    DBMS_OUTPUT.put_line('Debugging OFF');
  $END
END my_proc1;
/
 
CREATE PROCEDURE my_proc2 IS
BEGIN
  $IF my_debug.trace $THEN
    DBMS_OUTPUT.put_line('Tracing ON');
  $ELSE
    DBMS_OUTPUT.put_line('Tracing OFF');
  $END
END my_proc2;
/

See Also:

DBMS_DB_VERSION Package

The DBMS_DB_VERSION package provides these static constants:

  • The PLS_INTEGER constant VERSION identifies the current Oracle Database version.

  • The PLS_INTEGER constant RELEASE identifies the current Oracle Database release number.

  • Each BOOLEAN constant of the form VER_LE_v has the value TRUE if the database version is less than or equal to v; otherwise, it has the value FALSE.

  • Each BOOLEAN constant of the form VER_LE_v_r has the value TRUE if the database version is less than or equal to v and release is less than or equal to r; otherwise, it has the value FALSE.

  • All constants representing Oracle Database 10g or earlier have the value FALSE.

For more information about the DBMS_DB_VERSION package, see Oracle Database PL/SQL Packages and Types Reference.

Conditional Compilation Examples

Example 2-58 generates an error message if the database version and release is less than Oracle Database 10g Release 2 ; otherwise, it displays a message saying that the version and release are supported and uses a COMMIT statement that became available at Oracle Database 10g Release 2 .

Example 2-58 Code for Checking Database Version

BEGIN
  $IF DBMS_DB_VERSION.VER_LE_10_1 $THEN  -- selection directive begins
    $ERROR 'unsupported database release' $END  -- error directive
  $ELSE
    DBMS_OUTPUT.PUT_LINE (
      'Release ' || DBMS_DB_VERSION.VERSION || '.' ||
      DBMS_DB_VERSION.RELEASE || ' is supported.'
    );
  -- This COMMIT syntax is newly supported in 10.2:
  COMMIT WRITE IMMEDIATE NOWAIT;
  $END  -- selection directive ends
END;
/
 

Result:

Release 11.1 is supported.

Example 2-59 sets the values of the user-defined inquiry directives $$my_debug and $$my_tracing and then uses conditional compilation:

  • In the specification of package my_pkg, to determine the base type of the subtype my_real (BINARY_DOUBLE is available only for Oracle Database versions 10g and later.)

  • In the body of package my_pkg, to compute the values of my_pi and my_e differently for different database versions

  • In the procedure circle_area, to compile some code only if the inquiry directive $$my_debug has the value TRUE.

Example 2-59 Compiling Different Code for Different Database Versions

ALTER SESSION SET PLSQL_CCFLAGS = 'my_debug:FALSE, my_tracing:FALSE';
 
CREATE OR REPLACE PACKAGE my_pkg AS
  SUBTYPE my_real IS
    $IF DBMS_DB_VERSION.VERSION < 10 $THEN
      NUMBER;
    $ELSE
      BINARY_DOUBLE;
    $END
  
  my_pi my_real;
  my_e  my_real;
END my_pkg;
/
 
CREATE OR REPLACE PACKAGE BODY my_pkg AS
BEGIN
  $IF DBMS_DB_VERSION.VERSION < 10 $THEN
    my_pi := 3.14159265358979323846264338327950288420;
    my_e  := 2.71828182845904523536028747135266249775;
  $ELSE
    my_pi := 3.14159265358979323846264338327950288420d;
    my_e  := 2.71828182845904523536028747135266249775d;
  $END
END my_pkg;
/
 
CREATE OR REPLACE PROCEDURE circle_area(radius my_pkg.my_real) IS
  my_area       my_pkg.my_real;
  my_data_type  VARCHAR2(30);
BEGIN
  my_area := my_pkg.my_pi * (radius**2);
  
  DBMS_OUTPUT.PUT_LINE
    ('Radius: ' || TO_CHAR(radius) || ' Area: ' || TO_CHAR(my_area));
  
  $IF $$my_debug $THEN
    SELECT DATA_TYPE INTO my_data_type
    FROM USER_ARGUMENTS
    WHERE OBJECT_NAME = 'CIRCLE_AREA'
    AND ARGUMENT_NAME = 'RADIUS';
 
    DBMS_OUTPUT.PUT_LINE
      ('Data type of the RADIUS argument is: ' || my_data_type);
  $END
END;
/

Result:

PACKAGE my_pkg AS
SUBTYPE my_real IS
BINARY_DOUBLE;
my_pi my_real;
my_e my_real;
END my_pkg;
 
Call completed.

Retrieving and Printing Post-Processed Source Text

The DBMS_PREPROCESSOR package provides subprograms that retrieve and print the source text of a PL/SQL unit in its post-processed form. For information about the DBMS_PREPROCESSOR package, see Oracle Database PL/SQL Packages and Types Reference.

Example 2-60 invokes the procedure DBMS_PREPROCESSOR.PRINT_POST_PROCESSED_SOURCE to print the post-processed form of my_pkg (from Example 2-59). Lines of code in Example 2-59 that are not included in the post-processed text appear as blank lines.

Example 2-60 Displaying Post-Processed Source Textsource text

CALL DBMS_PREPROCESSOR.PRINT_POST_PROCESSED_SOURCE (
  'PACKAGE', 'HR', 'MY_PKG'
);

Result:

PACKAGE my_pkg AS
SUBTYPE my_real IS
BINARY_DOUBLE;
my_pi my_real;
my_e my_real;
END my_pkg;

Conditional Compilation Directive Restrictions

A conditional compilation directive cannot appear in the specification of a schema-level user-defined type (created with the "CREATE TYPE Statement"). This type specification specifies the attribute structure of the type, which determines the attribute structure of dependent types and the column structure of dependent tables.

Caution:

Using a conditional compilation directive to change the attribute structure of a type can cause dependent objects to "go out of sync" or dependent tables to become inaccessible. Oracle recommends that you change the attribute structure of a type only with the "ALTER TYPE Statement". The ALTER TYPE statement propagates changes to dependent objects.

The SQL parser imposes these restrictions on the location of the first conditional compilation directive in a stored PL/SQL unit or anonymous block:

  • In a package specification, a package body, a type body, and in a schema-level subprogram with no formal parameters, the first conditional compilation directive cannot appear before the keyword IS or AS.

  • In a schema-level subprogram with at least one formal parameter, the first conditional compilation directive cannot appear before the left parenthesis that follows the subprogram name.

    This example is correct:

    CREATE OR REPLACE PROCEDURE my_proc (
      $IF $$xxx $THEN i IN PLS_INTEGER $ELSE i IN INTEGER $END
    ) IS BEGIN NULL; END my_proc;
    /
    
  • In a trigger or an anonymous block, the first conditional compilation directive cannot appear before the keyword DECLARE or BEGIN, whichever comes first.

The SQL parser also imposes this restriction: If an anonymous block uses a placeholder, the placeholder cannot appear in a conditional compilation directive. For example:

BEGIN
  :n := 1; -- valid use of placeholder
  $IF ... $THEN
    :n := 1; -- invalid use of placeholder
$END