The concept of inheritance was added in the F2003 standard and is introduced by the attribute extends.
Consider the following simple example:
module mod type base integer i end type base type, extends(base) :: extended integer j end type extended end module mod
Features
A polymorphic variable with declared type base is type compatible with the type extended; type compatibility descends through a chain of children. A type extension inherits all the components of its parent types, including a component that is the parent (accessed by extended%base). Inheriting includes type bound procedures, but this can be overridden; the non_overridable attribute blocks overriding. An extended type does not have to implement more type parameters, components, or bindings than its parent type. A type parameter or component declared in an extended type must have a different name than type parameters and components of its parent type. Type extensions are backwards compatible, because every instance of extended is also an instance of base.
Limitations
- attributes:
bind(c),sequence, excludeextends - a type may extend only one other type
A more elaborate example
In the following example, please note that the calls to the subroutines did not change upon employing inheritance.
module ExampleModuleA
implicit none
type type_a
character(len=:), allocatable :: n, m
contains
procedure sub_a, sub_m
end type type_a
contains
subroutine sub_a(self, arg_a)
class(type_a), intent(in) :: self
character(len=:), allocatable, intent(out) :: arg_a
arg_a = self%n//self%n
end subroutine
subroutine sub_m(self, arg_m)
class(type_a), intent(in) :: self
character(len=:), allocatable, intent(out) :: arg_m
arg_m = self%n//self%m
end subroutine
end module ExampleModuleA
module ExampleModuleB
implicit none
type type_b
character(len=:), allocatable :: n, o
contains
procedure sub_a, sub_o
end type type_b
contains
subroutine sub_a(self, arg_a)
class(type_b), intent(in) :: self
character(len=:), allocatable, intent(out) :: arg_a
arg_a = self%n//self%n
end subroutine
subroutine sub_o(self, arg_o)
class(type_b), intent(in) :: self
character(len=:), allocatable, intent(out) :: arg_o
arg_o = self%n//self%o
end subroutine
end module ExampleModuleB
program main
use ExampleModuleA
use ExampleModuleB
implicit none
type(type_a) :: ta
character(len=:), allocatable :: n, m, arg_a, arg_m
type(type_b) :: tb
character(len=:), allocatable :: o, arg_o
ta%n = 'Nnn'
ta%m = 'Mmm'
tb%n = 'Nnn'
tb%o = 'Ooo'
call ta%sub_a(arg_a)
print*, arg_a
call ta%sub_m(arg_m)
print*, arg_m
call tb%sub_a(arg_a)
print*, arg_a
call tb%sub_o(arg_o)
print*, arg_o
end program main
module ExampleModuleC
implicit none
type type_c
character(len=:), allocatable :: n
contains
procedure sub_a
end type type_c
type, extends(type_c) :: type_a
character(len=:), allocatable :: m
contains
procedure sub_m
end type type_a
type, extends(type_c) :: type_b
character(len=:), allocatable :: o
contains
procedure sub_o
end type type_b
contains
subroutine sub_a(self, arg_a)
class(type_c), intent(in) :: self
character(len=:), allocatable, intent(out) :: arg_a
arg_a = self%n//self%n
end subroutine
subroutine sub_m(self, arg_m)
class(type_a), intent(in) :: self
character(len=:), allocatable, intent(out) :: arg_m
arg_m = self%n//self%m
end subroutine
subroutine sub_o(self, arg_o)
class(type_b), intent(in) :: self
character(len=:), allocatable, intent(out) :: arg_o
arg_o = self%n//self%o
end subroutine
end module ExampleModuleC
program main
use ExampleModuleC
implicit none
type(type_c) :: tc
character(len=:), allocatable :: n, arg_a
type(type_a) :: ta
character(len=:), allocatable :: m, arg_m
type(type_b) :: tb
character(len=:), allocatable :: o, arg_o
ta%n = 'Nnn'
ta%m = 'Mmm'
tb%n = 'Nnn'
tb%o = 'Ooo'
call ta%sub_a(arg_a)
print*, arg_a
call ta%sub_m(arg_m)
print*, arg_m
call tb%sub_a(arg_a)
print*, arg_a
call tb%sub_o(arg_o)
print*, arg_o
end program main