Luthaf/Foo.cpp

## Foo.cpp
#include "Foo.hpp"
#include <iostream>
using namespace std;


Foo::Foo(int _a, int _b): a(_a), b(_b){
    cout << "C++ side, constructor" << endl;
}

Foo::~Foo(){
    cout << "C++ side, destructor" << endl;
}

int Foo::bar(int c) const{
    return a + c;
}

double Foo::baz(double d) const{
    return d + b;
}

void foo_speaker(string s){
    Foo f(4, 2);
    cout << s << " Foo(4, 2).bar(3) is: " <<  f.bar(3) << endl;
}

## foo.h
#ifdef __cplusplus // Are we compiling this with a C++ compiler ?
extern "C" {
    class Foo;
    typedef Foo FOO;
#else
    // From the C side, we use an opaque pointer.
    typedef struct FOO FOO;
#endif

// Constructor
FOO* create_foo(int a, int b);

// Destructor
void delete_foo(FOO* foo);

// The const qualificators maps from the member function to pointers to the
// class instances.
int foo_bar(const FOO* foo, int c);
double foo_baz(const FOO* foo, double d);

void foo_speaker(const char* s);

#ifdef __cplusplus
}
#endif

## Foo.hpp
#include <string>

class Foo {
public:
    Foo(int a, int b);
    ~Foo();

    int bar(int c) const;
    double baz(double d) const;
private:
    int a;
    int b;
};

void foo_speaker(std::string s);

## foo_capi.cpp
#include "foo.h"
#include "Foo.hpp"

#include <iostream>
using namespace std;

FOO* create_foo(int a, int b){
    cout << "C API, create_foo" << endl;
    return new Foo(a, b);
}

void delete_foo(FOO* foo){
    cout << "C API, delete_foo" << endl;
    delete foo;
}

int foo_bar(const FOO* foo, int c){
    return foo->bar(c);
}

double foo_baz(const FOO* foo, double d){
    return foo->baz(d);
}

void foo_speaker(const char* s) {
    foo_speaker(string(s));
}

## foo_cdef.f90
! C functions declaration
interface
    function create_foo_c(a, b) bind(C, name="create_foo")
        use iso_c_binding
        implicit none
        type(c_ptr) :: create_foo_c
        integer(c_int), value :: a
        integer(c_int), value :: b
    end function

    subroutine delete_foo_c(foo) bind(C, name="delete_foo")
        use iso_c_binding
        implicit none
        type(c_ptr), value :: foo
    end subroutine

    function foo_bar_c(foo, c) bind(C, name="foo_bar")
        use iso_c_binding
        implicit none
        integer(c_int) :: foo_bar_c
        ! The const qualification is translated into an intent(in)
        type(c_ptr), intent(in), value :: foo
        integer(c_int), value :: c
    end function

    function foo_baz_c(foo, c) bind(C, name="foo_baz")
        use iso_c_binding
        implicit none
        real(c_double) :: foo_baz_c
        type(c_ptr), intent(in), value :: foo
        real(c_double), value :: c
    end function

    ! void functions maps to subroutines
    subroutine foo_speaker_c(str) bind(C, name="foo_speaker")
        use iso_c_binding
        implicit none
        character(len=1, kind=C_CHAR), intent(in) :: str(*)
    end subroutine
end interface

## foo_mod.f90
module libfoo
    use iso_c_binding

    private
    public :: foo, foo_speaker

    ! Yes, include is a keyword in Fortran !
    include "foo_cdef.f90"

    ! We'll use a Fortan type to represent a C++ class here, in an opaque maner
    type foo
        private
        type(c_ptr) :: ptr ! pointer to the Foo class
    contains
        ! We can bind some functions to this type, allowing for a cleaner syntax.
#ifdef __GNUC__
        procedure :: delete => delete_foo_polymorph ! Destructor for gfortran
#else
        final :: delete_foo ! Destructor
#endif
        ! Function member
        procedure :: bar => foo_bar
        procedure :: baz => foo_baz
    end type

    ! This function will act as the constructor for foo type
    interface foo
        procedure create_foo
    end interface

contains ! Implementation of the functions. We just wrap the C function here.
    function create_foo(a, b)
        implicit none
        type(foo) :: create_foo
        integer, intent(in) :: a, b
        create_foo%ptr = create_foo_c(a, b)
    end function

    subroutine delete_foo(this)
        implicit none
        type(foo) :: this
        call delete_foo_c(this%ptr)
    end subroutine

    ! Bounds procedure needs to take a polymorphic (class) argument
    subroutine delete_foo_polymorph(this)
        implicit none
        class(foo) :: this
        call delete_foo_c(this%ptr)
    end subroutine

    integer function foo_bar(this, c)
        implicit none
        class(foo), intent(in) :: this
        integer, intent(in) :: c
        foo_bar = foo_bar_c(this%ptr, c)
    end function

    double precision function foo_baz(this, c)
        implicit none
        class(foo), intent(in) :: this
        double precision, intent(in) :: c
        foo_baz = foo_baz_c(this%ptr, c)
    end function

    subroutine foo_speaker(str)
        implicit none
        character(len=*), intent(in) :: str
        character(len=1, kind=C_CHAR) :: c_str(len_trim(str) + 1)
        integer :: N, i

        ! Converting Fortran string to C string
        N = len_trim(str)
        do i = 1, N
            c_str(i) = str(i:i)
        end do
        c_str(N + 1) = C_NULL_CHAR

        call foo_speaker_c(c_str)
    end subroutine
end module

## Makefile
FC = gfortran
CXX = g++

UNAME := $(shell uname -s)

FCFLAGS = -Wall -Wextra
CCFLAGS = -Wall -Wextra
ifeq ($(UNAME_S),Darwin)
	LDFLAGS = -lstdc++
else
	LDFLAGS = -lc++
endif

all: test.x
test.o : foo_mod.o

%.x : %.o foo_mod.o foo_capi.o Foo.o
	${FC} $^ -o $@ ${LDFLAGS}

%.o : %.f90
	${FC} ${FCFLAGS} -c $< -o $@

%.o : %.cpp
	${CXX} ${CCFLAGS} -c $^ -o $@

.PHONY : clean

clean :
	${RM} -rf *.o *.mod test.x

## test.f90
program test
    use libfoo
    implicit none
    type(foo) :: f

    ! Create an object of type foo
    f = foo(3, 4)

    ! Call bound procedures (member functions)
    write(*,*) f%bar(60), " should be ", 63
    write(*,*) f%baz(10d0), " should be ", 14.0d0

    call foo_speaker("From Fortran!")

    ! The destructor should be called automatically here, but this is not yet
    ! implemented in gfortran. So let's do it manually.
#ifdef __GNUC__
    call f%delete
#endif
end program
	#include "Foo.hpp"
	#include <iostream>
	using namespace std;


	Foo::Foo(int _a, int _b): a(_a), b(_b){
	cout << "C++ side, constructor" << endl;
	}

	Foo::~Foo(){
	cout << "C++ side, destructor" << endl;
	}

	int Foo::bar(int c) const{
	return a + c;
	}

	double Foo::baz(double d) const{
	return d + b;
	}

	void foo_speaker(string s){
	Foo f(4, 2);
	cout << s << " Foo(4, 2).bar(3) is: " << f.bar(3) << endl;
	}
	#ifdef __cplusplus // Are we compiling this with a C++ compiler ?
	extern "C" {
	class Foo;
	typedef Foo FOO;
	#else
	// From the C side, we use an opaque pointer.
	typedef struct FOO FOO;
	#endif

	// Constructor
	FOO* create_foo(int a, int b);

	// Destructor
	void delete_foo(FOO* foo);

	// The const qualificators maps from the member function to pointers to the
	// class instances.
	int foo_bar(const FOO* foo, int c);
	double foo_baz(const FOO* foo, double d);

	void foo_speaker(const char* s);

	#ifdef __cplusplus
	}
	#endif
	#include <string>

	class Foo {
	public:
	Foo(int a, int b);
	~Foo();

	int bar(int c) const;
	double baz(double d) const;
	private:
	int a;
	int b;
	};

	void foo_speaker(std::string s);
	#include "foo.h"
	#include "Foo.hpp"

	#include <iostream>
	using namespace std;

	FOO* create_foo(int a, int b){
	cout << "C API, create_foo" << endl;
	return new Foo(a, b);
	}

	void delete_foo(FOO* foo){
	cout << "C API, delete_foo" << endl;
	delete foo;
	}

	int foo_bar(const FOO* foo, int c){
	return foo->bar(c);
	}

	double foo_baz(const FOO* foo, double d){
	return foo->baz(d);
	}

	void foo_speaker(const char* s) {
	foo_speaker(string(s));
	}
	! C functions declaration
	interface
	function create_foo_c(a, b) bind(C, name="create_foo")
	use iso_c_binding
	implicit none
	type(c_ptr) :: create_foo_c
	integer(c_int), value :: a
	integer(c_int), value :: b
	end function

	subroutine delete_foo_c(foo) bind(C, name="delete_foo")
	use iso_c_binding
	implicit none
	type(c_ptr), value :: foo
	end subroutine

	function foo_bar_c(foo, c) bind(C, name="foo_bar")
	use iso_c_binding
	implicit none
	integer(c_int) :: foo_bar_c
	! The const qualification is translated into an intent(in)
	type(c_ptr), intent(in), value :: foo
	integer(c_int), value :: c
	end function

	function foo_baz_c(foo, c) bind(C, name="foo_baz")
	use iso_c_binding
	implicit none
	real(c_double) :: foo_baz_c
	type(c_ptr), intent(in), value :: foo
	real(c_double), value :: c
	end function

	! void functions maps to subroutines
	subroutine foo_speaker_c(str) bind(C, name="foo_speaker")
	use iso_c_binding
	implicit none
	character(len=1, kind=C_CHAR), intent(in) :: str(*)
	end subroutine
	end interface
	module libfoo
	use iso_c_binding

	private
	public :: foo, foo_speaker

	! Yes, include is a keyword in Fortran !
	include "foo_cdef.f90"

	! We'll use a Fortan type to represent a C++ class here, in an opaque maner
	type foo
	private
	type(c_ptr) :: ptr ! pointer to the Foo class
	contains
	! We can bind some functions to this type, allowing for a cleaner syntax.
	#ifdef __GNUC__
	procedure :: delete => delete_foo_polymorph ! Destructor for gfortran
	#else
	final :: delete_foo ! Destructor
	#endif
	! Function member
	procedure :: bar => foo_bar
	procedure :: baz => foo_baz
	end type

	! This function will act as the constructor for foo type
	interface foo
	procedure create_foo
	end interface

	contains ! Implementation of the functions. We just wrap the C function here.
	function create_foo(a, b)
	implicit none
	type(foo) :: create_foo
	integer, intent(in) :: a, b
	create_foo%ptr = create_foo_c(a, b)
	end function

	subroutine delete_foo(this)
	implicit none
	type(foo) :: this
	call delete_foo_c(this%ptr)
	end subroutine

	! Bounds procedure needs to take a polymorphic (class) argument
	subroutine delete_foo_polymorph(this)
	implicit none
	class(foo) :: this
	call delete_foo_c(this%ptr)
	end subroutine

	integer function foo_bar(this, c)
	implicit none
	class(foo), intent(in) :: this
	integer, intent(in) :: c
	foo_bar = foo_bar_c(this%ptr, c)
	end function

	double precision function foo_baz(this, c)
	implicit none
	class(foo), intent(in) :: this
	double precision, intent(in) :: c
	foo_baz = foo_baz_c(this%ptr, c)
	end function

	subroutine foo_speaker(str)
	implicit none
	character(len=*), intent(in) :: str
	character(len=1, kind=C_CHAR) :: c_str(len_trim(str) + 1)
	integer :: N, i

	! Converting Fortran string to C string
	N = len_trim(str)
	do i = 1, N
	c_str(i) = str(i:i)
	end do
	c_str(N + 1) = C_NULL_CHAR

	call foo_speaker_c(c_str)
	end subroutine
	end module
	FC = gfortran
	CXX = g++

	UNAME := $(shell uname -s)

	FCFLAGS = -Wall -Wextra
	CCFLAGS = -Wall -Wextra
	ifeq ($(UNAME_S),Darwin)
	LDFLAGS = -lstdc++
	else
	LDFLAGS = -lc++
	endif

	all: test.x
	test.o : foo_mod.o

	%.x : %.o foo_mod.o foo_capi.o Foo.o
	${FC} $^ -o $@ ${LDFLAGS}

	%.o : %.f90
	${FC} ${FCFLAGS} -c $< -o $@

	%.o : %.cpp
	${CXX} ${CCFLAGS} -c $^ -o $@

	.PHONY : clean

	clean :
	${RM} -rf .o .mod test.x
	program test
	use libfoo
	implicit none
	type(foo) :: f

	! Create an object of type foo
	f = foo(3, 4)

	! Call bound procedures (member functions)
	write(,) f%bar(60), " should be ", 63
	write(,) f%baz(10d0), " should be ", 14.0d0

	call foo_speaker("From Fortran!")

	! The destructor should be called automatically here, but this is not yet
	! implemented in gfortran. So let's do it manually.
	#ifdef __GNUC__
	call f%delete
	#endif
	end program