Fortran派生类型，包含可从C访问的指针

Question

我有一个Fortran代码，其中包含许多包含指针的派生类型。 我正在编写一个需要访问这些变量的C ++代码。 我不能在没有指针的情况下重写这些派生类型，因为它们在Fortran代码的数百个不同的地方使用。

以下是示例代码：

module simple
use  iso_c_binding

TYPE,bind(C) :: SIMPLEF
INTEGER :: A
INTEGER, POINTER :: B, C(:)
END TYPE SIMPLEF

end module simple

我需要从C访问SIMPLEF派生类型。我知道我不能使用它，因为Fortran指针不能在派生类型中，如果它应该可以从C访问。有任何解决方法吗？

EXTENSION：作为前一个问题的扩展（由于IanH解决了），我已经派生出了具有成员派生类型的类型。 示例如下：

TYPE COMPLEXF
  INTEGER :: X
  TYPE (SIMPLEF) :: Y
END TYPE COMPLEXF

我是否需要为每个Y成员创建COMPLEXF子程序，即SETY_A，QUERYY_A，SETY_B，QUERYY_BSIZE，QUERYY_B等？ 或者有更好的方法来解决这个问题吗？

Answer 1

您可以在Fortran中编写一些可操作的访问器过程，它们对派生类型进行操作，并将必要的变量公开给C ++代码。 这与一般C ++代码与类的私有成员变量交互的方式非常相似。

您可以使用SIMPLEF类型的对象的C地址作为C ++代码中的不透明句柄 - Fortran中的类型不必具有BIND（C）属性以允许将该类型的对象传递给C_LOC（尽管对象该类型将需要具有TARGET属性）。

对于数组数据，您可能需要为数据获取器提供多个入口点，以允许适当协调用于将数据从Fortran传输到C的内存缓冲区。

MODULE simple
  IMPLICIT NONE
  ! An example of an non-interoperable type (no BIND(C)).
  TYPE :: SIMPLEF
    INTEGER :: A
    ! Note that given the problem description, the component B 
    ! appears to have value semantics.  If so, as of Fortran 2003 
    ! this should be an ALLOCATABLE component.  Because it is 
    ! a pointer component, we will default initialize it to 
    ! help avoid its pointer association status becoming 
    ! inadvertently undefined 
    INTEGER, POINTER :: B(:) => NULL()
  END TYPE SIMPLEF
CONTAINS
  FUNCTION GetHandle() RESULT(handle) BIND(C, NAME='GetHandle')
    USE, INTRINSIC :: ISO_C_BINDING, ONLY: C_PTR, C_LOC
    TYPE(C_PTR) :: handle
    TYPE(SIMPLEF), POINTER :: p
    !***
    ! For the sake of example we are exposing an interface that 
    ! allows client code to create an object.  Perhaps in your 
    ! case the object already exists and its lifetime is managed 
    ! in some other way, in which case:
    !
    !   handle = C_LOC(existing_object_with_target_attribute)
    !
    ! and you are done - no need for ReleaseHandle.
    ALLOCATE(p)
    ! Perhaps some constructory sort of stuff here?
    p%A = 666
    ! Use the C address of the object as an opaque handle.
    handle = C_LOC(p)
  END FUNCTION GetHandle

  ! If you create objects, you need to be able to destroy them.
  SUBROUTINE ReleaseHandle(handle) BIND(C, NAME='ReleaseHandle')
    USE, INTRINSIC :: ISO_C_BINDING, ONLY: C_PTR, C_F_POINTER
    TYPE(C_PTR), INTENT(IN), VALUE :: handle
    TYPE(SIMPLEF), POINTER :: p
    !***
    CALL C_F_POINTER(handle, p)
    DEALLOCATE(p)
  END SUBROUTINE ReleaseHandle

  SUBROUTINE SetA(handle, a) BIND(C, NAME='SetA')
    USE, INTRINSIC :: ISO_C_BINDING, ONLY:  &
        C_PTR, C_F_POINTER, C_INT
    TYPE(C_PTR), INTENT(IN), VALUE :: handle
    INTEGER(C_INT), INTENT(IN), VALUE :: a  
    TYPE(SIMPLEF), POINTER :: p
    !***
    CALL C_F_POINTER(handle, p)
    p%A = a
  END SUBROUTINE SetA

  FUNCTION QueryA(handle) RESULT(a) BIND(C, NAME='QueryA')
    USE, INTRINSIC :: ISO_C_BINDING, ONLY:  &
        C_PTR, C_F_POINTER, C_INT
    TYPE(C_PTR), INTENT(IN), VALUE :: handle
    INTEGER(C_INT) :: a  
    TYPE(SIMPLEF), POINTER :: p
    !***
    CALL C_F_POINTER(handle, p)
    a = p%A
  END FUNCTION QueryA

  SUBROUTINE SetB(handle, data, data_size) BIND(C, NAME='SetB')
    USE, INTRINSIC :: ISO_C_BINDING, ONLY:  &
        C_PTR, C_F_POINTER, C_INT
    TYPE(C_PTR), INTENT(IN), VALUE :: handle
    INTEGER(C_INT), INTENT(IN), VALUE :: data_size
    INTEGER(C_INT), INTENT(IN) :: data(data_size)
    TYPE(SIMPLEF), POINTER :: p
    !***
    CALL C_F_POINTER(handle, p)
    ! Allocate p%B to appropriate size.
    !
    ! Assuming here the pointer association status of p%B is always 
    ! defined or dissociated, never undefined.  This is much easier 
    ! with allocatable components.
    IF (ASSOCIATED(p%B)) THEN
      IF (SIZE(p%B) /= data_size) THEN
        DEALLOCATE(p%B)
        ALLOCATE(p%B(data_size))
      END IF
    ELSE
      ALLOCATE(p%B(data_size))
    END IF
    p%B = data
  END SUBROUTINE SetB

  SUBROUTINE QueryBSize(handle, data_size) BIND(C, NAME='QueryBSize')
    USE, INTRINSIC :: ISO_C_BINDING, ONLY:  &
        C_PTR, C_F_POINTER, C_INT
    TYPE(C_PTR), INTENT(IN), VALUE :: handle
    INTEGER(C_INT), INTENT(OUT) :: data_size
    TYPE(SIMPLEF), POINTER :: p
    !***
    CALL C_F_POINTER(handle, p)
    ! See comments about assumed association status above.
    IF (ASSOCIATED(p%B)) THEN
      data_size = SIZE(p%B, KIND=C_INT)
    ELSE
      data_size = 0_C_INT
    END IF
  END SUBROUTINE QueryBSize

  SUBROUTINE QueryBData(handle, data) BIND(C, NAME='QueryBData')
    USE, INTRINSIC :: ISO_C_BINDING, ONLY:  &
        C_PTR, C_F_POINTER, C_INT
    TYPE(C_PTR), INTENT(IN), VALUE :: handle
    INTEGER(C_INT), INTENT(OUT) :: data(*)
    TYPE(SIMPLEF), POINTER :: p
    !***
    CALL C_F_POINTER(handle, p)
    ! See comments about assumed association status above.
    IF (ASSOCIATED(p%B)) THEN
      data(:SIZE(p%B)) = p%B
    ELSE
      ! Someone is being silly.
    END IF
  END SUBROUTINE QueryBData

  ! ...etc...
END MODULE simple

//~~~~~~
#include <vector>
#include <iostream>

extern "C" void* GetHandle();
extern "C" void ReleaseHandle(void* handle);
extern "C" void SetA(void* handle, int a);
extern "C" int QueryA(void* handle);
extern "C" void SetB(void* handle, const int* data, int data_size);
extern "C" void QueryBSize(void* handle, int* data_size);
extern "C" void QueryBData(void *handle, int *data);

class SimpleF
{
private:
  void *handle;
public:
  SimpleF() 
  { 
    handle = GetHandle(); 
  }

  ~SimpleF() 
  { 
    ReleaseHandle(handle); 
  }

  void SetA(int a) 
  { 
    ::SetA(handle, a); 
  }

  int QueryA()
  { 
    return ::QueryA(handle); 
  }

  void SetB(const std::vector<int>& b)
  {
     ::SetB(handle, &b[0], b.size());
  }

  std::vector<int> QueryB()
  {
    // Get the data size, construct a suitable buffer, populate the buffer.
    int data_size;
    ::QueryBSize(handle, &data_size);
    if (data_size == 0) return std::vector<int>();

    std::vector<int> data(data_size);
    ::QueryBData(handle, &data[0]);
    return data;
  }
};

int main()
{
  SimpleF x;
  x.SetA(99);
  std::cout << x.QueryA() << std::endl;

  std::vector<int> testvector(2,100);
  x.SetB(testvector);
  std::cout << x.QueryB()[0] << ' ' << x.QueryB()[1] << std::endl;

  return 0;
}

如果您的编译器支持使用TS29113“Fortran with C的进一步互操作性”添加到该语言的功能，则可互操作的过程可以具有指针参数，这可以简化编写这些访问器。 通过该TS引入的功能将成为下一个标准版本的基本语言的一部分。