앞으로: Documentation and Testing of Oct-Files, 뒤로: Input Parameter Checking in Oct-Files, 위로: Oct-Files [차례][찾아보기]
Another important feature of Octave is its ability to react to the user typing
Control-C during extended calculations. This ability is based on the C++
exception handler, where memory allocated by the C++ new/delete methods is
automatically released when the exception is treated. When writing an oct-file
which may run for a long time the programmer must periodically use the macro
OCTAVE_QUIT
, in order to allow Octave to check and possibly respond
to a user typing Control-C. For example:
for (octave_idx_type i = 0; i < a.nelem (); i++) { OCTAVE_QUIT; b.elem (i) = 2. * a.elem (i); }
The presence of the OCTAVE_QUIT
macro in the inner loop allows
Octave to detect and acknowledge a Control-C key sequence. Without this
macro, the user must either wait for the oct-file function to return before the
interrupt is processed, or the user must press Control-C three times
which will force Octave to exit completely.
The OCTAVE_QUIT
macro does impose a very small performance penalty;
For loops that are known to be small it may not make sense to include
OCTAVE_QUIT
.
When creating an oct-file that uses an external library, the function might
spend a significant portion of its time in the external library. It is not
generally possible to use the OCTAVE_QUIT
macro in this case. The
alternative code in this case is
BEGIN_INTERRUPT_IMMEDIATELY_IN_FOREIGN_CODE; … some code that calls a "foreign" function … END_INTERRUPT_IMMEDIATELY_IN_FOREIGN_CODE;
The disadvantage of this is that if the foreign code allocates any memory
internally, then this memory might be lost during an interrupt, without being
deallocated. Therefore, ideally Octave itself should allocate any memory that
is needed by the foreign code, with either the fortran_vec
method or the OCTAVE_LOCAL_BUFFER
macro.
The Octave unwind_protect
mechanism (The unwind_protect Statement)
can also be used in oct-files. In conjunction with the exception handling of
Octave, it ensures that certain recovery code is always run even if an
exception occurs. An example of the use of this mechanism is
#include <octave/oct.h> #include <octave/unwind-prot.h> void my_err_handler (const char *fmt, ...) { // Do nothing!! } void my_err_with_id_handler (const char *id, const char *fmt, ...) { // Do nothing!! } DEFUN_DLD (unwinddemo, args, nargout, "Unwind Demo") { if (args.length () < 2) print_usage (); NDArray a = args(0).array_value (); NDArray b = args(1).array_value (); // Declare unwind_protect frame which lasts as long as // the variable frame has scope. octave::unwind_protect frame; frame.add_fcn (set_liboctave_warning_handler, current_liboctave_warning_handler); frame.add_fcn (set_liboctave_warning_with_id_handler, current_liboctave_warning_with_id_handler); set_liboctave_warning_handler (my_err_handler); set_liboctave_warning_with_id_handler (my_err_with_id_handler); return octave_value (quotient (a, b)); }
As can be seen in the example:
unwinddemo (1, 0) ⇒ Inf 1 / 0 ⇒ warning: division by zero Inf
The warning for division by zero (and in fact all warnings) are disabled in the
unwinddemo
function.