4 PL/SQL Data Types

Every PL/SQL constant, variable, parameter, and function return value has a data type that determines its storage format and its valid values and operations.

This chapter explains scalar data types, which store values with no internal components.

A scalar data type can have subtypes. A subtype is a data type that is a subset of another data type, which is its base type. A subtype has the same valid operations as its base type. A data type and its subtypes comprise a data type family.

PL/SQL predefines many types and subtypes in the package STANDARD and lets you define your own subtypes.

The PL/SQL scalar data types are:

  • The SQL data types

  • BOOLEAN

  • PLS_INTEGER

  • BINARY_INTEGER

  • REF CURSOR

  • User-defined subtypes

Topics

See Also:

4.1 SQL Data Types

The PL/SQL data types include the SQL data types.

For information about the SQL data types, see Oracle Database SQL Language Reference—all information there about data types and subtypes, data type comparison rules, data conversion, literals, and format models applies to both SQL and PL/SQL, except as noted here:

Unlike SQL, PL/SQL lets you declare variables, to which the following topics apply:

4.1.1 Different Maximum Sizes

The SQL data types listed in Table 4-1 have different maximum sizes in PL/SQL and SQL.

Table 4-1 Data Types with Different Maximum Sizes in PL/SQL and SQL

Data Type Maximum Size in PL/SQL Maximum Size in SQL

CHARFoot 1

32,767 bytes

2,000 bytes

NCHARFoot 1

32,767 bytes

2,000 bytes

RAWFoot 1

32,767 bytes

2,000 bytesFoot 2

VARCHAR2Foot 1

32,767 bytes

4,000 bytesFoot 2

NVARCHAR2Foot 1

32,767 bytes

4,000 bytesFoot 2

LONGFoot 3

32,760 bytes

2 gigabytes (GB) - 1

LONG RAWFoot 3

32,760 bytes

2 GB

BLOB

128 terabytes (TB)

(4 GB - 1) * database_block_size

CLOB

128 TB

(4 GB - 1) * database_block_size

NCLOB

128 TB

(4 GB - 1) * database_block_size

Footnote 1

When specifying the maximum size of a value of this data type in PL/SQL, use an integer literal (not a constant or variable) whose value is in the range from 1 through 32,767.

Footnote 2

To eliminate this size difference, follow the instructions in Oracle Database SQL Language Reference.

Footnote 3

Supported only for backward compatibility with existing applications.

4.1.2 Additional PL/SQL Constants for BINARY_FLOAT and BINARY_DOUBLE

The SQL data types BINARY_FLOAT and BINARY_DOUBLE represent single-precision and double-precision IEEE 754-format floating-point numbers, respectively.

BINARY_FLOAT and BINARY_DOUBLE computations do not raise exceptions, so you must check the values that they produce for conditions such as overflow and underflow by comparing them to predefined constants (for examples, see Oracle Database SQL Language Reference). PL/SQL has more of these constants than SQL does.

Table 4-2 lists and describes the predefined PL/SQL constants for BINARY_FLOAT and BINARY_DOUBLE, and identifies those that SQL also defines.

Table 4-2 Predefined PL/SQL BINARY_FLOAT and BINARY_DOUBLE Constants

Constant Description

BINARY_FLOAT_NAN (*)

BINARY_FLOAT value for which the condition IS NAN (not a number) is true

BINARY_FLOAT_INFINITY (*)

Single-precision positive infinity

BINARY_FLOAT_MAX_NORMAL

Maximum normal BINARY_FLOAT value

BINARY_FLOAT_MIN_NORMAL

Minimum normal BINARY_FLOAT value

BINARY_FLOAT_MAX_SUBNORMAL

Maximum subnormal BINARY_FLOAT value

BINARY_FLOAT_MIN_SUBNORMAL

Minimum subnormal BINARY_FLOAT value

BINARY_DOUBLE_NAN (*)

BINARY_DOUBLE value for which the condition IS NAN (not a number) is true

BINARY_DOUBLE_INFINITY (*)

Double-precision positive infinity

BINARY_DOUBLE_MAX_NORMAL

Maximum normal BINARY_DOUBLE value

BINARY_DOUBLE_MIN_NORMAL

Minimum normal BINARY_DOUBLE value

BINARY_DOUBLE_MAX_SUBNORMAL

Maximum subnormal BINARY_DOUBLE value

BINARY_DOUBLE_MIN_SUBNORMAL

Minimum subnormal BINARY_DOUBLE value

(*) SQL also predefines this constant.

4.1.3 Additional PL/SQL Subtypes of BINARY_FLOAT and BINARY_DOUBLE

PL/SQL predefines these subtypes:

  • SIMPLE_FLOAT, a subtype of SQL data type BINARY_FLOAT

  • SIMPLE_DOUBLE, a subtype of SQL data type BINARY_DOUBLE

Each subtype has the same range as its base type and has a NOT NULL constraint (explained in "NOT NULL Constraint").

If you know that a variable will never have the value NULL, declare it as SIMPLE_FLOAT or SIMPLE_DOUBLE, rather than BINARY_FLOAT or BINARY_DOUBLE. Without the overhead of checking for nullness, the subtypes provide significantly better performance than their base types. The performance improvement is greater with PLSQL_CODE_TYPE='NATIVE' than with PLSQL_CODE_TYPE='INTERPRETED' (for more information, see "Use Data Types that Use Hardware Arithmetic").

4.1.4 CHAR and VARCHAR2 Variables

Topics

4.1.4.1 Assigning or Inserting Too-Long Values

If the value that you assign to a character variable is longer than the maximum size of the variable, an error occurs. For example:

DECLARE
  c VARCHAR2(3 CHAR);
BEGIN
  c := 'abc  ';
END;
/

Result:

DECLARE
*
ERROR at line 1:
ORA-06502: PL/SQL: numeric or value error: character string buffer too small
ORA-06512: at line 4

Similarly, if you insert a character variable into a column, and the value of the variable is longer than the defined width of the column, an error occurs. For example:

DROP TABLE t;
CREATE TABLE t (c CHAR(3 CHAR));
 
DECLARE
  s VARCHAR2(5 CHAR) := 'abc  ';
BEGIN
  INSERT INTO t(c) VALUES(s);
END;
/

Result:

BEGIN
*
ERROR at line 1:
ORA-12899: value too large for column "HR"."T"."C" (actual: 5, maximum: 3)
ORA-06512: at line 4

To strip trailing blanks from a character value before assigning it to a variable or inserting it into a column, use the RTRIM function, explained in Oracle Database SQL Language Reference. For example:

DECLARE
  c VARCHAR2(3 CHAR);
BEGIN
  c := RTRIM('abc  ');
  INSERT INTO t(c) VALUES(RTRIM('abc  '));
END;
/

Result:

PL/SQL procedure successfully completed.
4.1.4.2 Declaring Variables for Multibyte Characters

The maximum size of a CHAR or VARCHAR2 variable is 32,767 bytes, whether you specify the maximum size in characters or bytes. The maximum number of characters in the variable depends on the character set type and sometimes on the characters themselves:

Character Set Type Maximum Number of Characters

Single-byte character set

32,767

n-byte fixed-width multibyte character set (for example, AL16UTF16)

FLOOR(32,767/n)

n-byte variable-width multibyte character set with character widths between 1 and n bytes (for example, JA16SJIS or AL32UTF8)

Depends on characters themselves—can be anything from 32,767 (for a string containing only 1-byte characters) through FLOOR(32,767/n) (for a string containing only n-byte characters).

When declaring a CHAR or VARCHAR2 variable, to ensure that it can always hold n characters in any multibyte character set, declare its length in characters—that is, CHAR(n CHAR) or VARCHAR2(n CHAR), where n does not exceed FLOOR(32767/4) = 8191.

See Also:

Oracle Database Globalization Support Guide for information about Oracle Database character set support

4.1.4.3 Differences Between CHAR and VARCHAR2 Data Types

CHAR and VARCHAR2 data types differ in:

4.1.4.3.1 Predefined Subtypes

The CHAR data type has one predefined subtype in both PL/SQL and SQL—CHARACTER.

The VARCHAR2 data type has one predefined subtype in both PL/SQL and SQL, VARCHAR, and an additional predefined subtype in PL/SQL, STRING.

Each subtype has the same range of values as its base type.

Note:

In a future PL/SQL release, to accommodate emerging SQL standards, VARCHAR might become a separate data type, no longer synonymous with VARCHAR2.

4.1.4.3.2 How Blank-Padding Works

This explains the differences and considerations of using blank-padding with CHAR and VARCHAR2.

Consider these situations:

  • The value that you assign to a variable is shorter than the maximum size of the variable.

  • The value that you insert into a column is shorter than the defined width of the column.

  • The value that you retrieve from a column into a variable is shorter than the maximum size of the variable.

If the data type of the receiver is CHAR, PL/SQL blank-pads the value to the maximum size. Information about trailing blanks in the original value is lost.

If the data type of the receiver is VARCHAR2, PL/SQL neither blank-pads the value nor strips trailing blanks. Character values are assigned intact, and no information is lost.

Example 4-1 CHAR and VARCHAR2 Blank-Padding Difference

In this example, both the CHAR variable and the VARCHAR2 variable have the maximum size of 10 characters. Each variable receives a five-character value with one trailing blank. The value assigned to the CHAR variable is blank-padded to 10 characters, and you cannot tell that one of the six trailing blanks in the resulting value was in the original value. The value assigned to the VARCHAR2 variable is not changed, and you can see that it has one trailing blank.

DECLARE
  first_name  CHAR(10 CHAR);
  last_name   VARCHAR2(10 CHAR);
BEGIN
  first_name := 'John ';
  last_name  := 'Chen ';
 
  DBMS_OUTPUT.PUT_LINE('*' || first_name || '*');
  DBMS_OUTPUT.PUT_LINE('*' || last_name || '*');
END;
/

Result:

*John      *
*Chen *
4.1.4.3.3 Value Comparisons

The SQL rules for comparing character values apply to PL/SQL character variables.

Whenever one or both values in the comparison have the data type VARCHAR2 or NVARCHAR2, nonpadded comparison semantics apply; otherwise, blank-padded semantics apply. For more information, see Oracle Database SQL Language Reference.

4.1.5 LONG and LONG RAW Variables

Note:

Oracle supports the LONG and LONG RAW data types only for backward compatibility with existing applications. For new applications:

  • Instead of LONG, use VARCHAR2(32760), BLOB, CLOB or NCLOB.

  • Instead of LONG RAW, use BLOB.

You can insert any LONG value into a LONG column. You can insert any LONG RAW value into a LONG RAW column. You cannot retrieve a value longer than 32,760 bytes from a LONG or LONG RAW column into a LONG or LONG RAW variable.

You can insert any CHAR or VARCHAR2 value into a LONG column. You cannot retrieve a value longer than 32,767 bytes from a LONG column into a CHAR or VARCHAR2 variable.

You can insert any RAW value into a LONG RAW column. You cannot retrieve a value longer than 32,767 bytes from a LONG RAW column into a RAW variable.

See Also:

"Trigger LONG and LONG RAW Data Type Restrictions" for restrictions on LONG and LONG RAW data types in triggers

4.1.6 ROWID and UROWID Variables

When you retrieve a rowid into a ROWID variable, use the ROWIDTOCHAR function to convert the binary value to a character value. For information about this function, see Oracle Database SQL Language Reference.

To convert the value of a ROWID variable to a rowid, use the CHARTOROWID function, explained in Oracle Database SQL Language Reference. If the value does not represent a valid rowid, PL/SQL raises the predefined exception SYS_INVALID_ROWID.

To retrieve a rowid into a UROWID variable, or to convert the value of a UROWID variable to a rowid, use an assignment statement; conversion is implicit.

Note:

  • UROWID is a more versatile data type than ROWID, because it is compatible with both logical and physical rowids.

  • When you update a row in a table compressed with Hybrid Columnar Compression (HCC), the ROWID of the row changes. HCC, a feature of certain Oracle storage systems, is described in Oracle Database Concepts.

See Also:

Oracle Database PL/SQL Packages and Types Reference for information about the DBMS_ROWID package, whose subprograms let you create and return information about ROWID values (but not UROWID values)

4.2 BOOLEAN Data Type

The PL/SQL data type BOOLEAN stores logical values, which are the boolean values TRUE and FALSE and the value NULL. NULL represents an unknown value.

The syntax for declaring an BOOLEAN variable is:

variable_name BOOLEAN

The only value that you can assign to a BOOLEAN variable is a BOOLEAN expression. For details, see "BOOLEAN Expressions".

Because SQL has no data type equivalent to BOOLEAN, you cannot:

  • Assign a BOOLEAN value to a database table column

  • Select or fetch the value of a database table column into a BOOLEAN variable

  • Use a BOOLEAN value in a SQL function

    (However, a SQL query can invoke a PL/SQL function that has a BOOLEAN parameter, as in "Example 4-3".)

  • Use a BOOLEAN expression in a SQL statement, except as an argument to a PL/SQL function invoked in a SQL query, or in a PL/SQL anonymous block.

    Note:

    An argument to a PL/SQL function invoked in a static SQL query cannot be a BOOLEAN literal. The workaround is to assign the literal to a variable and then pass the variable to the function, as in "Example 4-3".

You cannot pass a BOOLEAN value to the DBMS_OUTPUT.PUT or DBMS_OUTPUT.PUTLINE subprogram. To print a BOOLEAN value, use an IF or CASE statement to translate it to a character value (for information about these statements, see "Conditional Selection Statements").

Example 4-2 Printing BOOLEAN Values

In this example, the procedure accepts a BOOLEAN parameter and uses a CASE statement to print Unknown if the value of the parameter is NULL, Yes if it is TRUE, and No if it is FALSE.

See Also:

Example 3-34, which creates a print_boolean procedure that uses an IF statement.

PROCEDURE print_boolean (b BOOLEAN)
AS
BEGIN
  DBMS_OUTPUT.PUT_LINE (
    CASE
      WHEN b IS NULL THEN 'Unknown'
      WHEN b THEN 'Yes'
      WHEN NOT b THEN 'No'
    END
  );
END;

BEGIN
  print_boolean(TRUE);
  print_boolean(FALSE);
  print_boolean(NULL);
END;

Result:

Yes
No
Unknown

Example 4-3 SQL Statement Invokes PL/SQL Function with BOOLEAN Parameter

In this example, a SQL statement invokes a PL/SQL function that has a BOOLEAN parameter.

FUNCTION f (x BOOLEAN, y PLS_INTEGER)
  RETURN employees.employee_id%TYPE
  AUTHID CURRENT_USER AS
BEGIN
  IF x THEN
    RETURN y;
  ELSE
    RETURN 2*y;
  END IF;
END;
 
DECLARE
  name employees.last_name%TYPE;
  b BOOLEAN := TRUE;
BEGIN
  SELECT last_name INTO name
  FROM employees
  WHERE employee_id = f(b, 100);
 
  DBMS_OUTPUT.PUT_LINE(name);
 
  b := FALSE;
 
  SELECT last_name INTO name
  FROM employees
  WHERE employee_id = f(b, 100);
 
  DBMS_OUTPUT.PUT_LINE(name);
END;
/

Result:

King
Whalen

4.3 PLS_INTEGER and BINARY_INTEGER Data Types

The PL/SQL data types PLS_INTEGER and BINARY_INTEGER are identical.

For simplicity, this document uses PLS_INTEGER to mean both PLS_INTEGER and BINARY_INTEGER.

The PLS_INTEGER data type stores signed integers in the range -2,147,483,648 through 2,147,483,647, represented in 32 bits.

The PLS_INTEGER data type has these advantages over the NUMBER data type and NUMBER subtypes:

  • PLS_INTEGER values require less storage.

  • PLS_INTEGER operations use hardware arithmetic, so they are faster than NUMBER operations, which use library arithmetic.

For efficiency, use PLS_INTEGER values for all calculations in its range.

Topics

4.3.1 Preventing PLS_INTEGER Overflow

A calculation with two PLS_INTEGER values that overflows the PLS_INTEGER range raises an overflow exception.

For calculations outside the PLS_INTEGER range, use INTEGER, a predefined subtype of the NUMBER data type.

Example 4-4 PLS_INTEGER Calculation Raises Overflow Exception

This example shows that a calculation with two PLS_INTEGER values that overflows the PLS_INTEGER range raises an overflow exception, even if you assign the result to a NUMBER data type.

DECLARE
  p1 PLS_INTEGER := 2147483647;
  p2 PLS_INTEGER := 1;
  n NUMBER;
BEGIN
  n := p1 + p2;
END;
/

Result:

DECLARE
*
ERROR at line 1:
ORA-01426: numeric overflow
ORA-06512: at line 6

Example 4-5 Preventing Example 4-4 Overflow

This example shows the correct use of the INTEGER predefined subtype for calculations outside the PLS_INTEGER range.

DECLARE
  p1 PLS_INTEGER := 2147483647;
  p2 INTEGER := 1;
  n NUMBER;
BEGIN
  n := p1 + p2;
END;
/

Result:

PL/SQL procedure successfully completed.

4.3.2 Predefined PLS_INTEGER Subtypes

This summary lists the predefined subtypes of the PLS_INTEGER data type and describes the data they store.

Table 4-3 Predefined Subtypes of PLS_INTEGER Data Type

Data Type Data Description

NATURAL

Nonnegative PLS_INTEGER value

NATURALN

Nonnegative PLS_INTEGER value with NOT NULL constraint

POSITIVE

Positive PLS_INTEGER value

POSITIVEN

Positive PLS_INTEGER value with NOT NULL constraint

SIGNTYPE

PLS_INTEGER value -1, 0, or 1 (useful for programming tri-state logic)

SIMPLE_INTEGER

PLS_INTEGER value with NOT NULL constraint.

PLS_INTEGER and its subtypes can be implicitly converted to these data types:

  • CHAR

  • VARCHAR2

  • NUMBER

  • LONG

All of the preceding data types except LONG, and all PLS_INTEGER subtypes, can be implicitly converted to PLS_INTEGER.

A PLS_INTEGER value can be implicitly converted to a PLS_INTEGER subtype only if the value does not violate a constraint of the subtype.

See Also:

Example 4-6 Violating Constraint of SIMPLE_INTEGER Subtype

This example shows that casting the PLS_INTEGER value NULL to the SIMPLE_INTEGER subtype raises an exception.

DECLARE
  a SIMPLE_INTEGER := 1;
  b PLS_INTEGER := NULL;
BEGIN
  a := b;
END;
/

Result:

DECLARE
*
ERROR at line 1:
ORA-06502: PL/SQL: numeric or value error
ORA-06512: at line 5

4.3.3 SIMPLE_INTEGER Subtype of PLS_INTEGER

SIMPLE_INTEGER is a predefined subtype of the PLS_INTEGER data type.

SIMPLE_INTEGER has the same range as PLS_INTEGER and has a NOT NULL constraint. It differs significantly from PLS_INTEGER in its overflow semantics.

If you know that a variable will never have the value NULL or need overflow checking, declare it as SIMPLE_INTEGER rather than PLS_INTEGER. Without the overhead of checking for nullness and overflow, SIMPLE_INTEGER performs significantly better than PLS_INTEGER.

Topics

4.3.3.1 SIMPLE_INTEGER Overflow Semantics

If and only if all operands in an expression have the data type SIMPLE_INTEGER, PL/SQL uses two's complement arithmetic and ignores overflows.

Because overflows are ignored, values can wrap from positive to negative or from negative to positive; for example:

230 + 230 = 0x40000000 + 0x40000000 = 0x80000000 = -231

-231 + -231 = 0x80000000 + 0x80000000 = 0x00000000 = 0

For example, this block runs without errors:

DECLARE
  n SIMPLE_INTEGER := 2147483645;
BEGIN
  FOR j IN 1..4 LOOP
    n := n + 1;
    DBMS_OUTPUT.PUT_LINE(TO_CHAR(n, 'S9999999999'));
  END LOOP;
  FOR j IN 1..4 LOOP
   n := n - 1;
   DBMS_OUTPUT.PUT_LINE(TO_CHAR(n, 'S9999999999'));
  END LOOP;
END;
/

Result:

+2147483646
+2147483647
-2147483648
-2147483647
-2147483648
+2147483647
+2147483646
+2147483645

PL/SQL procedure successfully completed.
4.3.3.2 Expressions with Both SIMPLE_INTEGER and Other Operands

If an expression has both SIMPLE_INTEGER and other operands, PL/SQL implicitly converts the SIMPLE_INTEGER values to PLS_INTEGER NOT NULL.

The PL/SQL compiler issues a warning when SIMPLE_INTEGER and other values are mixed in a way that might negatively impact performance by inhibiting some optimizations.

4.3.3.3 Integer Literals in SIMPLE_INTEGER Range

Integer literals in the SIMPLE_INTEGER range have the data type SIMPLE_INTEGER.

However, to ensure backward compatibility, when all operands in an arithmetic expression are integer literals, PL/SQL treats the integer literals as if they were cast to PLS_INTEGER.

4.4 User-Defined PL/SQL Subtypes

PL/SQL lets you define your own subtypes.

The base type can be any scalar or user-defined PL/SQL data type specifier such as CHAR, DATE, or RECORD (including a previously defined user-defined subtype).

Note:

The information in this topic applies to both user-defined subtypes and the predefined subtypes listed in PL/SQL Predefined Data Types.

Subtypes can:

  • Provide compatibility with ANSI/ISO data types

  • Show the intended use of data items of that type

  • Detect out-of-range values

Topics

4.4.1 Unconstrained Subtypes

An unconstrained subtype has the same set of values as its base type, so it is only another name for the base type.

Therefore, unconstrained subtypes of the same base type are interchangeable with each other and with the base type. No data type conversion occurs.

To define an unconstrained subtype, use this syntax:

SUBTYPE subtype_name IS base_type

For information about subtype_name and base_type, see subtype.

An example of an unconstrained subtype, which PL/SQL predefines for compatibility with ANSI, is:

SUBTYPE "DOUBLE PRECISION" IS FLOAT

Example 4-7 User-Defined Unconstrained Subtypes Show Intended Use

In this example, the unconstrained subtypes Balance and Counter show the intended uses of data items of their types.

DECLARE
  SUBTYPE Balance IS NUMBER;

  checking_account        Balance(6,2);
  savings_account         Balance(8,2);
  certificate_of_deposit  Balance(8,2);
  max_insured  CONSTANT   Balance(8,2) := 250000.00;

  SUBTYPE Counter IS NATURAL;

  accounts     Counter := 1;
  deposits     Counter := 0;
  withdrawals  Counter := 0;
  overdrafts   Counter := 0;

  PROCEDURE deposit (
    account  IN OUT Balance,
    amount   IN     Balance
  ) IS
  BEGIN
    account  := account + amount;
    deposits := deposits + 1;
  END;
  
BEGIN
  NULL;
END;
/

4.4.2 Constrained Subtypes

A constrained subtype has only a subset of the values of its base type.

If the base type lets you specify size, precision and scale, or a range of values, then you can specify them for its subtypes. The subtype definition syntax is:

SUBTYPE subtype_name IS base_type
  { precision [, scale ] | RANGE low_value .. high_value } [ NOT NULL ]

Otherwise, the only constraint that you can put on its subtypes is NOT NULL:

SUBTYPE subtype_name IS base_type [ NOT NULL ]

Note:

The only base types for which you can specify a range of values are PLS_INTEGER and its subtypes (both predefined and user-defined).

A constrained subtype can be implicitly converted to its base type, but the base type can be implicitly converted to the constrained subtype only if the value does not violate a constraint of the subtype.

A constrained subtype can be implicitly converted to another constrained subtype with the same base type only if the source value does not violate a constraint of the target subtype.

See Also:

Example 4-8 User-Defined Constrained Subtype Detects Out-of-Range Values

In this example, the constrained subtype Balance detects out-of-range values.

DECLARE
  SUBTYPE Balance IS NUMBER(8,2);
 
  checking_account  Balance;
  savings_account   Balance;
 
BEGIN
  checking_account := 2000.00;
  savings_account  := 1000000.00;
END;
/

Result:

DECLARE
*
ERROR at line 1:
ORA-06502: PL/SQL: numeric or value error: number precision too large
ORA-06512: at line 9

Example 4-9 Implicit Conversion Between Constrained Subtypes with Same Base Type

In this example, the three constrained subtypes have the same base type. The first two subtypes can be implicitly converted to the third subtype, but not to each other.

DECLARE
  SUBTYPE Digit        IS PLS_INTEGER RANGE 0..9;
  SUBTYPE Double_digit IS PLS_INTEGER RANGE 10..99;
  SUBTYPE Under_100    IS PLS_INTEGER RANGE 0..99;
 
  d   Digit        :=  4;
  dd  Double_digit := 35;
  u   Under_100;
BEGIN
  u := d;   -- Succeeds; Under_100 range includes Digit range
  u := dd;  -- Succeeds; Under_100 range includes Double_digit range
  dd := d;  -- Raises error; Double_digit range does not include Digit range
END;
/

Result:

DECLARE
*
ERROR at line 1:
ORA-06502: PL/SQL: numeric or value error
ORA-06512: at line 12

4.4.3 Subtypes with Base Types in Same Data Type Family

If two subtypes have different base types in the same data type family, then one subtype can be implicitly converted to the other only if the source value does not violate a constraint of the target subtype.

For the predefined PL/SQL data types and subtypes, grouped by data type family, see PL/SQL Predefined Data Types.

Example 4-10 Implicit Conversion Between Subtypes with Base Types in Same Family

In this example, the subtypes Word and Text have different base types in the same data type family. The first assignment statement implicitly converts a Word value to Text. The second assignment statement implicitly converts a Text value to Word. The third assignment statement cannot implicitly convert the Text value to Word, because the value is too long.

DECLARE
  SUBTYPE Word IS CHAR(6);
  SUBTYPE Text IS VARCHAR2(15);
 
  verb       Word := 'run';
  sentence1  Text;
  sentence2  Text := 'Hurry!';
  sentence3  Text := 'See Tom run.';
 
BEGIN
  sentence1 := verb;  -- 3-character value, 15-character limit
  verb := sentence2;  -- 6-character value, 6-character limit
  verb := sentence3;  -- 12-character value, 6-character limit
END;
/

Result:

DECLARE
*
ERROR at line 1:
ORA-06502: PL/SQL: numeric or value error: character string buffer too small
ORA-06512: at line 13