//--------------------------------------------------------------------- // Convert an incoming Python list to a tid_t[] array %typemap(in) tid_t[ANY](tid_t temp[$1_dim0]) { int i, len; if (!PySequence_Check($input)) { PyErr_SetString(PyExc_TypeError,"Expecting a sequence"); return NULL; } /* Cap the number of elements to copy */ len = PySequence_Length($input) < $1_dim0 ? PySequence_Length($input) : $1_dim0; for (i =0; i < len; i++) { PyObject *o = PySequence_GetItem($input,i); if (!PyLong_Check(o)) { Py_XDECREF(o); PyErr_SetString(PyExc_ValueError,"Expecting a sequence of long integers"); return NULL; } temp[i] = PyLong_AsUnsignedLong(o); Py_DECREF(o); } $1 = &temp[0]; } //--------------------------------------------------------------------- %define %cstring_output_maxstr_none(TYPEMAP, SIZE) %typemap (default) SIZE { $1 = MAXSTR; } %typemap(in,numinputs=0) (TYPEMAP, SIZE) { $1 = ($1_ltype) qalloc(MAXSTR+1); } %typemap(out) ssize_t { /* REMOVING ssize_t return value in $symname */ } %typemap(argout) (TYPEMAP,SIZE) { Py_XDECREF(resultobj); if (result > 0) { resultobj = PyString_FromString($1); } else { Py_INCREF(Py_None); resultobj = Py_None; } qfree($1); } %enddef //--------------------------------------------------------------------- %define %cstring_bounded_output_none(TYPEMAP,MAX) %typemap(in, numinputs=0) TYPEMAP(char temp[MAX+1]) { $1 = ($1_ltype) temp; } %typemap(argout,fragment="t_output_helper") TYPEMAP { PyObject *o; $1[MAX] = 0; if ($1 > 0) { o = PyString_FromString($1); } else { o = Py_None; Py_INCREF(Py_None); } $result = t_output_helper($result,o); } %enddef //--------------------------------------------------------------------- %define %binary_output_or_none(TYPEMAP, SIZE) %typemap (default) SIZE { $1 = MAXSPECSIZE; } %typemap(in,numinputs=0) (TYPEMAP, SIZE) { $1 = (char *) qalloc(MAXSPECSIZE+1); } %typemap(out) ssize_t { /* REMOVING ssize_t return value in $symname */ } %typemap(argout) (TYPEMAP,SIZE) { Py_XDECREF(resultobj); if (result > 0) { resultobj = PyString_FromStringAndSize((char *)$1, result); } else { Py_INCREF(Py_None); resultobj = Py_None; } qfree((void *)$1); } %enddef //--------------------------------------------------------------------- %define %binary_output_with_size(TYPEMAP, SIZE) %typemap (default) SIZE { size_t ressize = MAXSPECSIZE; $1 = &ressize; } %typemap(in,numinputs=0) (TYPEMAP, SIZE) { $1 = (char *) qalloc(MAXSPECSIZE+1); } %typemap(out) ssize_t { /* REMOVING ssize_t return value in $symname */ } %typemap(argout) (TYPEMAP,SIZE) { Py_XDECREF(resultobj); if (result) { resultobj = PyString_FromStringAndSize((char *)$1, *$2); } else { Py_INCREF(Py_None); resultobj = Py_None; } qfree((void *)$1); } %enddef //--------------------------------------------------------------------- // IN/OUT qstring //--------------------------------------------------------------------- %typemap(in,numinputs=0) qstring *result (qstring temp) { $1 = &temp; } %typemap(argout) qstring *result { Py_XDECREF(resultobj); if (result) { resultobj = PyString_FromStringAndSize($1->begin(), $1->length()); } else { Py_INCREF(Py_None); resultobj = Py_None; } } %typemap(freearg) qstring* result { // Nothing. We certainly don't want 'temp' to be deleted. } //--------------------------------------------------------------------- // Check that the argument is a callable Python object //--------------------------------------------------------------------- %typemap(in) PyObject *pyfunc { if (!PyCallable_Check($input)) { PyErr_SetString(PyExc_TypeError, "Expected a callable object"); return NULL; } $1 = $input; } // Convert ea_t %typemap(in) ea_t { uint64 $1_temp; if ( !PyW_GetNumber($input, &$1_temp) ) { PyErr_SetString(PyExc_TypeError, "Expected an ea_t type"); return NULL; } $1 = ea_t($1_temp); } //--------------------------------------------------------------------- // IN qstring //--------------------------------------------------------------------- // This is used to set/retrieve qstring that are structure members. %typemap(in) qstring* { char *buf; Py_ssize_t length; int success = PyString_AsStringAndSize($input, &buf, &length); if ( success > -1 ) { $1 = new qstring(buf, length); } } %typemap(freearg) qstring* { delete $1; } %typemap(out) qstring* { $result = PyString_FromStringAndSize($1->c_str(), $1->length()); } %typemap(out) qstring { $result = PyString_FromStringAndSize($1.c_str(), $1.length()); } %apply qstring { _qstring } %apply qstring* { _qstring* } #ifdef __EA64__ %apply longlong *INOUT { sval_t *value }; %apply ulonglong *INOUT { ea_t *addr }; %apply ulonglong *INOUT { sel_t *sel }; %apply ulonglong *OUTPUT { ea_t *ea1, ea_t *ea2 }; // read_selection() #else %apply int *INOUT { sval_t *value }; %apply unsigned int *INOUT { ea_t *addr }; %apply unsigned int *INOUT { sel_t *sel }; %apply unsigned int *OUTPUT { ea_t *ea1, ea_t *ea2 }; // read_selection() #endif //------------------------------------------------------------------------- // The following is to be used to expose an array of items // to IDAPython. This will not make a copy (on purpose!). //------------------------------------------------------------------------- // // (Very) heavily inspired by: // http://stackoverflow.com/questions/7713318/nested-structure-array-access-in-python-using-swig?rq=1 // %immutable; %inline %{ template struct wrapped_array_t { Type (&data)[N]; wrapped_array_t(Type (&data)[N]) : data(data) { } }; %} %mutable; %extend wrapped_array_t { inline size_t __len__() const { return N; } inline const Type& __getitem__(size_t i) const throw(std::out_of_range) { if (i >= N || i < 0) throw std::out_of_range("out of bounds access"); return $self->data[i]; } inline void __setitem__(size_t i, const Type& v) throw(std::out_of_range) { if (i >= N || i < 0) throw std::out_of_range("out of bounds access"); $self->data[i] = v; } %pythoncode { __iter__ = _bounded_getitem_iterator } } //------------------------------------------------------------------------- #if SWIG_VERSION == 0x20012 %typemap(out) tinfo_t {} %typemap(ret) tinfo_t { // ret tinfo_t tinfo_t *ni = new tinfo_t($1); til_register_python_tinfo_t_instance(ni); $result = SWIG_NewPointerObj(ni, $&1_descriptor, SWIG_POINTER_OWN | 0); } // KLUDGE: We'll let the compiler (or at worse the runtime) // decide of the flags to use, depending on the method we are currently // wrapping: at new-time, a SWIG_POINTER_NEW is required. %typemap(out) tinfo_t* {} %typemap(ret) tinfo_t* { // ret tinfo_t* tinfo_t *ni = new tinfo_t(*($1)); til_register_python_tinfo_t_instance(ni); if ( strcmp("new_tinfo_t", "$symname") == 0 ) { $result = SWIG_NewPointerObj(SWIG_as_voidptr(ni), $1_descriptor, SWIG_POINTER_NEW | 0); delete $1; } else { $result = SWIG_NewPointerObj(SWIG_as_voidptr(ni), $1_descriptor, SWIG_POINTER_OWN | 0); } } %typemap(check) tinfo_t* { if ( $1 == NULL ) SWIG_exception_fail(SWIG_ValueError, "invalid null reference " "in method '" "$symname" "', argument " "$argnum"" of type '" "$1_type""'"); } #else #error Ensure tinfo_t wrapping is compatible with this version of SWIG #endif