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Linking external C code to Octave is relatively simple, as the C functions can easily be called directly from C++. One possible issue is that the declarations of the external C functions may need to be explicitly defined as C functions to the compiler. If the declarations of the external C functions are in the header foo.h, then the tactic to ensure that the C++ compiler treats these declarations as C code is
#ifdef __cplusplus extern "C" { #endif #include "foo.h" #ifdef __cplusplus } /* end extern "C" */ #endif
Calling Fortran code, however, can pose more difficulties. This is due to differences in the manner in which compilers treat the linking of Fortran code with C or C++ code. Octave supplies a number of macros that allow consistent behavior across a number of compilers.
The underlying Fortran code should use the XSTOPX
function to
replace the Fortran STOP
function. XSTOPX
uses the Octave
exception handler to treat failing cases in the Fortran code
explicitly. Note that Octave supplies its own replacement BLAS
XERBLA
function, which uses XSTOPX
.
If the code calls XSTOPX
, then the F77_XFCN
macro should be used to call the underlying Fortran function. The Fortran
exception state can then be checked with the global variable
f77_exception_encountered
. If XSTOPX
will not be called,
then the F77_FCN
macro should be used instead to call the Fortran
code.
There is no great harm in using F77_XFCN
in all cases, except that
for Fortran code that is short running and executes a large number of times,
there is potentially an overhead in doing so. However, if F77_FCN
is used with code that calls XSTOP
, Octave can generate a
segmentation fault.
An example of the inclusion of a Fortran function in an oct-file is given in the following example, where the C++ wrapper is
#include <octave/oct.h> #include <octave/f77-fcn.h> extern "C" { F77_RET_T F77_FUNC (fortransub, FORTSUB) (const int&, double*, F77_CHAR_ARG_DECL F77_CHAR_ARG_LEN_DECL); } DEFUN_DLD (fortrandemo, args, , "Fortran Demo") { octave_value_list retval; int nargin = args.length (); if (nargin != 1) print_usage (); else { NDArray a = args(0).array_value (); if (! error_state) { double *av = a.fortran_vec (); octave_idx_type na = a.numel (); OCTAVE_LOCAL_BUFFER (char, ctmp, 128); F77_XFCN (fortransub, FORTSUB, (na, av, ctmp F77_CHAR_ARG_LEN (128))); retval(1) = std::string (ctmp); retval(0) = a; } } return retval; }
and the Fortran function is
subroutine fortransub (n, a, s) implicit none character*(*) s real*8 a(*) integer*4 i, n, ioerr do i = 1, n if (a(i) .eq. 0d0) then call xstopx ('fortransub: divide by zero') else a(i) = 1d0 / a(i) endif enddo write (unit = s, fmt = '(a,i3,a,a)', iostat = ioerr) $ 'There are ', n, $ ' values in the input vector', char(0) if (ioerr .ne. 0) then call xstopx ('fortransub: error writing string') endif return end
This example demonstrates most of the features needed to link to an external Fortran function, including passing arrays and strings, as well as exception handling. Both the Fortran and C++ files need to be compiled in order for the example to work.
mkoctfile fortrandemo.cc fortransub.f [b, s] = fortrandemo (1:3) ⇒ b = 1.00000 0.50000 0.33333 s = There are 3 values in the input vector [b, s] = fortrandemo (0:3) error: fortrandemo: fortransub: divide by zero
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