Visible to Intel only — GUID: GUID-07BEDE90-3838-4F6A-8A8B-BE364073FD9E
Visible to Intel only — GUID: GUID-07BEDE90-3838-4F6A-8A8B-BE364073FD9E
PUBLIC
Statement and Attribute: Specifies that entities in a module can be accessed from outside the module by specifying a USE statement.
The PUBLIC attribute can be specified in a type declaration statement or a PUBLIC statement, and takes one of the following forms:
Type Declaration Statement:
type,[att-ls,] PUBLIC [, att-ls] :: entity [, entity]...
Statement:
PUBLIC [[::] entity [, entity] ...]
type |
Is a data type specifier. |
att-ls |
Is an optional list of attribute specifiers. |
entity |
Is one of the following:
In statement form, an entity can also be one of the following:
|
Description
The PUBLIC attribute can only appear in the scoping unit of a module.
Only one PUBLIC statement without an entity list is permitted in the scoping unit of a module; it sets the default accessibility of all entities in the module and any entities accessed from a module by use association.
If no PRIVATE statements are specified in a module, the default is PUBLIC accessibility for all entities in the module and entities accessible from other modules by use association.
A module name can appear at most once in all the PUBLIC or PRIVATE statements in a scoping unit. If a module name is specified in a PUBLIC statement, the module name must have appeared in a USE statement within the same scoping unit.
A PUBLIC attribute can be specified on the TYPE statement of a derived-type definition in a module. This specifies that the derived-type definition is accessible by USE association where the module is used.
A PUBLIC attribute can be specified in the statement declaring a component or a type-bound procedure of a derived type. This specifies that the component or type-bound procedure is accessible by USE association where the module is used, even if the default accessibility of the components and type-bound procedures of the derived type has been set to PRIVATE in the definition of the derived type.
If a derived type is declared PUBLIC in a module, but its components are declared PRIVATE, any scoping unit accessing the module though use association (or host association) can access the derived-type definition, but not its components.
If a module procedure has a dummy argument or a function result of a type that has PRIVATE accessibility, the module procedure must have PRIVATE accessibility. If the module procedure has a generic identifier, it must also be declared PRIVATE.
If a procedure has a generic identifier, the accessibility of the procedure's specific name is independent of the accessibility of its generic identifier. One can be declared PRIVATE and the other PUBLIC.
The accessibility of the components of a type is independent of the accessibility of the type name. The following combinations are possible:
A private type name with a private component
A public type name with a public component
A private type name with a public component
A public type name with a private component
The accessibility of a type does not affect, and is not affected by, the accessibility of its components and type-bound procedures. If a type definition is private, then the type name, and thus the structure constructor for the type, are accessible only within the module containing the derived-type definition or in the module's descendants.
Example
The following examples show type declaration statements specifying the PUBLIC and PRIVATE attributes:
REAL, PRIVATE :: A, B, C
INTEGER, PUBLIC :: LOCAL_SUMS
The following is an example of the PUBLIC and PRIVATE statements:
MODULE SOME_DATA
REAL ALL_B
PUBLIC ALL_B
TYPE RESTRICTED_DATA
REAL LOCAL_C(50)
END TYPE RESTRICTED_DATA
PRIVATE RESTRICTED_DATA
END MODULE
The following example shows a PUBLIC type with PRIVATE components:
MODULE MATTER
TYPE ELEMENTS
PRIVATE
INTEGER C, D
END TYPE
...
END MODULE MATTER
In this case, components C and D are private to type ELEMENTS, but type ELEMENTS is not private to MODULE MATTER. Any program unit that uses the module MATTER, can declare variables of type ELEMENTS, and pass as arguments values of type ELEMENTS.
The following shows another example:
! LENGTH in module VECTRLEN calculates the length of a 2-D vector.
! The module contains both private and public procedures
MODULE VECTRLEN
PRIVATE SQUARE
PUBLIC LENGTH
CONTAINS
SUBROUTINE LENGTH(x,y,z)
REAL,INTENT(IN) x,y
REAL,INTENT(OUT) z
CALL SQUARE(x,y)
z = SQRT(x + y)
RETURN
END SUBROUTINE
SUBROUTINE SQUARE(x1,y1)
REAL x1,y1
x1 = x1**2
y1 = y1**2
RETURN
END SUBROUTINE
END MODULE