#include #include #include #include #include #include "trick/swig/swig_ref.hh" #include "trick/swig/swig_double.hh" #include "trick/swig/swig_int.hh" #include "trick/swig/swig_convert_units.hh" #include "trick/MemoryManager.hh" #include "trick/memorymanager_c_intf.h" #include "trick/PythonPrint.hh" #if PY_VERSION_HEX < 0x02050000 #define Py_ssize_t int #endif extern Trick::MemoryManager* trick_MM; swig_ref::swig_ref() : ref() , need_to_deref(false) { str_output = NULL ; } swig_ref::~swig_ref() { if ( ref.attr->type_name ) { free((void *)ref.attr->type_name) ; } if ( ref.attr->units ) { free((void *)ref.attr->units) ; } delete ref.attr ; if ( str_output ) { free(str_output) ; } } char * swig_ref::__str__() { std::stringstream os ; deref_address() ; REF2 ref_copy = ref; Trick::PythonPrint::write_rvalue(os , ref_copy.address , ref_copy.attr , 0 , 0) ; if ( str_output ) { free(str_output) ; } str_output = strdup(os.str().c_str()) ; return str_output ; } char * swig_ref::__repr__() { return(__str__()) ; } PyObject * swig_ref::__len__() { return PyInt_FromLong((long)ref.attr->index[0].size) ; } // If the swig_ref needs is a pointer, dereference it and determine the array size. void swig_ref::deref_address() { if ( need_to_deref ) { ref.address = *(void**)ref.address ; ref.attr->index[0].size = get_truncated_size((char *)ref.address) ; need_to_deref = false ; } } template void * assign_array( PyObject *obj1 , REF2 & ref ) { void * argp2 ; int ret ; TYPE * temp_ptr ; unsigned int jj ; // convert list to tuple so we only have to deal with tuples in code below. if ( PyList_Check(obj1) ) { obj1 = PyList_AsTuple(obj1) ; } unsigned int size = PyTuple_Size(obj1) ; temp_ptr = (TYPE *)TMM_declare_var_1d(ref.attr->type_name , size) ; for( jj = 0 ; jj < size ; jj++ ) { PyObject *o = PyTuple_GetItem( obj1 , jj ) ; if (PyFloat_Check(o)) { temp_ptr[jj] = (TYPE)(PyFloat_AsDouble(o)) ; } else if (PyInt_Check(o)) { temp_ptr[jj] = (TYPE)(PyInt_AsLong(o)) ; } else if (SWIG_IsOK(SWIG_ConvertPtr(o, &argp2,SWIG_TypeQuery("_p_swig_double"), 0 ))) { double new_value ; std::string units_ref ; swig_double * temp_m = reinterpret_cast(argp2) ; new_value = temp_m->value ; units_ref = std::string(ref.attr->units) ; ret = convert_united_value( units_ref , temp_m->units , &new_value ) ; if ( ret == 0 ) { temp_ptr[jj] = (TYPE)new_value ; } else { return NULL ; } } else if (SWIG_IsOK(SWIG_ConvertPtr(o, &argp2,SWIG_TypeQuery("_p_swig_int"), 0 ))) { long long new_value ; std::string units_ref ; swig_int * temp_m = reinterpret_cast(argp2) ; new_value = temp_m->value ; units_ref = std::string(ref.attr->units) ; ret = convert_united_value( units_ref , temp_m->units , &new_value ) ; if ( ret == 0 ) { temp_ptr[jj] = (TYPE)new_value ; } else { return NULL ; } } else { std::cout << "\033[31mHERE in swig_ref set_item with list of unknown types!!\033[0m" << std::endl ; return NULL ; } } return temp_ptr ; } void newVTreeNode( V_TREE **curr_node ) { V_TREE * next_node = ( V_TREE * )calloc( 1 , sizeof(V_TREE) ) ; (*curr_node)->next = next_node ; *curr_node = next_node ; (*curr_node)->v_data = ( V_DATA * )calloc( 1 , sizeof(V_DATA) ) ; } int setVData( V_DATA * v_data , PyObject * o , REF2 & ref_copy ) { void * argp2 ; int ret ; if (PyFloat_Check(o)) { v_data->type = TRICK_DOUBLE ; v_data->value.d = PyFloat_AsDouble(o) ; } else if (PyInt_Check(o)) { v_data->type = TRICK_LONG_LONG ; v_data->value.ll = PyInt_AsLong(o) ; } else if (SWIG_IsOK(SWIG_ConvertPtr(o, &argp2,SWIG_TypeQuery("_p_swig_double"), 0 ))) { double new_value ; std::string units_ref ; swig_double * temp_m = reinterpret_cast(argp2) ; new_value = temp_m->value ; units_ref = std::string(ref_copy.attr->units) ; ret = convert_united_value( units_ref , temp_m->units , &new_value ) ; if ( ret == 0 ) { v_data->value.d = new_value ; } else { return TRICK_UNITS_CONVERSION_ERROR ; } v_data->type = TRICK_DOUBLE ; } else if (SWIG_IsOK(SWIG_ConvertPtr(o, &argp2,SWIG_TypeQuery("_p_swig_int"), 0 ))) { long long new_value ; std::string units_ref ; swig_int * temp_m = reinterpret_cast(argp2) ; new_value = temp_m->value ; units_ref = std::string(ref_copy.attr->units) ; ret = convert_united_value( units_ref , temp_m->units , &new_value ) ; if ( ret == 0 ) { v_data->value.ll = new_value ; } else { return -1 ; } v_data->type = TRICK_LONG_LONG ; } else { //TODO: handle list items of "void *" and other pointer types std::cout << "\033[31mHERE in swig_ref set_item with list of unknown types!!\033[0m" << std::endl ; return -1 ; } return 0 ; } int swig_ref::__setitem__( int ii, PyObject * obj1 ) { V_TREE v_tree ; void * argp2 ; int ret ; int status ; V_TREE *first_node , * curr_node ; deref_address() ; REF2 ref_copy = ref; if ( ii < 0 ) { ii += ref_copy.attr->index[0].size ; } v_tree.v_data = ( V_DATA * )calloc( 1 , sizeof(V_DATA) ) ; v_tree.v_data->type = TRICK_INTEGER ; v_tree.v_data->value.i = ii ; status = trick_MM->ref_dim( &ref_copy , v_tree.v_data ) ; // Error in ref_dim if ( status != 0 ) { return status ; } v_tree.last = v_tree.next = v_tree.down = NULL ; // convert list to tuple so we only have to deal with tuples in code below. if ( PyList_Check(obj1) ) { obj1 = PyList_AsTuple(obj1) ; } if (PyFloat_Check(obj1)) { v_tree.v_data->type = TRICK_DOUBLE ; v_tree.v_data->value.d = PyFloat_AsDouble(obj1) ; } else if (PyInt_Check(obj1)) { v_tree.v_data->type = TRICK_LONG_LONG ; v_tree.v_data->value.ll = PyInt_AsLong(obj1) ; #if PY_VERSION_HEX >= 0x03000000 } else if ( PyUnicode_Check(obj1) ) { v_tree.v_data->type = TRICK_STRING ; PyObject * temp = PyUnicode_AsEncodedString(obj1, "utf-8", "Error ~"); v_tree.v_data->value.cp = strdup(PyBytes_AS_STRING(temp)) ; #else } else if (PyString_Check(obj1)) { v_tree.v_data->type = TRICK_STRING ; v_tree.v_data->value.cp = PyString_AsString(obj1) ; #endif } else if (SWIG_IsOK(SWIG_ConvertPtr(obj1, &argp2,SWIG_TypeQuery("_p_swig_double"), 0 ))) { swig_double * temp_m = reinterpret_cast< swig_double * >(argp2) ; ref_copy.units = (char *)temp_m->units.c_str() ; v_tree.v_data->type = TRICK_DOUBLE ; v_tree.v_data->value.d = temp_m->value ; } else if (SWIG_IsOK(SWIG_ConvertPtr(obj1, &argp2,SWIG_TypeQuery("_p_swig_int"), 0 ))) { swig_int * temp_m = reinterpret_cast< swig_int * >(argp2) ; ref_copy.units = (char *)temp_m->units.c_str() ; v_tree.v_data->type = TRICK_LONG_LONG ; v_tree.v_data->value.ll = temp_m->value ; } else if ( PyTuple_Check(obj1) ) { unsigned int jj ; unsigned int size = PyTuple_Size(obj1) ; int last_index ; // See if we have a list to assign to on the left side if ( ref_copy.num_index_left == 0 ) { std::cout << "\033[31mCannot assign list to a scalar value\033[0m" << std::endl ; return TRICK_PARAMETER_ARRAY_SIZE ; } //cout << "HERE in swig_ref set_item with list type!! ref->num_index " << ref.num_index << " attr->num_index = " << ref.attr->num_index << endl ; //cout << " last index size = " << ref.attr->index[ref.attr->num_index - 1].size << endl ; last_index = ref_copy.attr->index[ref_copy.attr->num_index - 1].size ; if ( last_index ) { // The LHS is an array. Fill out a V_TREE structure with the RHS data to be used with ref_assignment. first_node = curr_node = ( V_TREE * )calloc( 1 , sizeof(V_TREE) ) ; //TODO: Add 2 dimensional assignments for( jj = 0 ; jj < size ; jj++ ) { PyObject *o = PyTuple_GetItem( obj1 , jj ) ; newVTreeNode(&curr_node) ; ret = setVData( curr_node->v_data , o , ref_copy ) ; if ( ret != 0 ) { return ret ; } } v_tree.down = first_node->next ; free(first_node) ; } else { // The LHS is a pointer. Create an allocation from the data on the right to be used in ref_assignment. v_tree.v_data->type = TRICK_VOID_PTR ; switch (ref_copy.attr->type) { case TRICK_UNSIGNED_CHARACTER: v_tree.v_data->value.vp = assign_array< unsigned char > ( obj1 , ref_copy ) ; break ; case TRICK_SHORT: v_tree.v_data->value.vp = assign_array< short > ( obj1 , ref_copy ) ; break ; case TRICK_UNSIGNED_SHORT: v_tree.v_data->value.vp = assign_array< unsigned short > ( obj1 , ref_copy ) ; break ; case TRICK_INTEGER: v_tree.v_data->value.vp = assign_array< int > ( obj1 , ref_copy ) ; break ; case TRICK_UNSIGNED_INTEGER: v_tree.v_data->value.vp = assign_array< unsigned int > ( obj1 , ref_copy ) ; break ; case TRICK_LONG: v_tree.v_data->value.vp = assign_array< long > ( obj1 , ref_copy ) ; break ; case TRICK_UNSIGNED_LONG: v_tree.v_data->value.vp = assign_array< unsigned long > ( obj1 , ref_copy ) ; break ; case TRICK_LONG_LONG: v_tree.v_data->value.vp = assign_array< long long > ( obj1 , ref_copy ) ; break ; case TRICK_UNSIGNED_LONG_LONG: v_tree.v_data->value.vp = assign_array< unsigned long long > ( obj1 , ref_copy ) ; break ; case TRICK_DOUBLE: v_tree.v_data->value.vp = assign_array< double > ( obj1 , ref_copy ) ; break ; case TRICK_FLOAT: v_tree.v_data->value.vp = assign_array< float > ( obj1 , ref_copy ) ; break ; case TRICK_BOOLEAN: v_tree.v_data->value.vp = assign_array< bool > ( obj1 , ref_copy ) ; break ; default: break ; } //cout << "\033[33mGoing to set a pointer in swig_ref::set_item!!\033[0m" << endl ; } //cout << "finished making v_tree" << endl ; } else if (SWIG_IsOK(SWIG_ConvertPtr(obj1, &argp2,SWIG_TypeQuery("void *"), 0 ))) { //cout << "\033[31mHERE in swig_ref set_item with void *!!\033[0m" << endl ; v_tree.v_data->type = TRICK_VOID_PTR ; v_tree.v_data->value.vp = reinterpret_cast< void * >(argp2) ; } else { // Test and see if a the RHS is a compatible pointer to our variable. #if SWIG_VERSION >= 0x010332 SwigPyObject * swig_obj = SWIG_Python_GetSwigThis(obj1) ; #else PySwigObject * swig_obj = SWIG_Python_GetSwigThis(obj1) ; #endif if ( swig_obj != NULL ) { void *argp1 = NULL ; std::string array_type_name = std::string("_p_") + ref.attr->type_name ; if ( SWIG_IsOK(SWIG_ConvertPtr(obj1,&argp1,SWIG_TypeQuery(array_type_name.c_str()),SWIG_POINTER_DISOWN))) { v_tree.v_data->type = TRICK_VOID_PTR ; v_tree.v_data->value.vp = argp1 ; } else { std::cout << "\033[31mswig_ref::__setitem__ could not convert " << SWIG_TypePrettyName(SWIG_Python_GetSwigThis(obj1)->ty) << " to " << ref.attr->type_name << "\033[0m" << std::endl ; return TRICK_SWIG_PARAMETER_INCORRECT_TYPE ; } } else { // Cannot determine what the RHS is. std::cout << "\033[31mHERE3 in swig_ref set_item with unknown type\033[0m" << std::endl ; return -1 ; } } //cout << "HERE in swig_ref set_item!! " << ii << endl ; ret = trick_MM->ref_assignment( &ref_copy , &v_tree ) ; free(v_tree.v_data) ; curr_node = v_tree.down ; while ( curr_node != NULL ) { V_TREE * next_node = curr_node->next ; free(curr_node->v_data) ; free(curr_node) ; curr_node = next_node ; } return(ret) ; } template < class VALUE_TYPE > VALUE_TYPE getValue(void * address , Py_ssize_t index ) { VALUE_TYPE * casted_address = ( VALUE_TYPE * ) address ; return casted_address[index] ; } int copyValue( V_DATA * v_data , REF2 & ref , Py_ssize_t index ) { switch (ref.attr->type) { case TRICK_CHARACTER: v_data->value.ll = getValue< char >(ref.address , index) ; v_data->type = TRICK_LONG_LONG ; break ; case TRICK_UNSIGNED_CHARACTER: v_data->value.ll = getValue< unsigned char >(ref.address , index) ; v_data->type = TRICK_LONG_LONG ; break ; case TRICK_SHORT: v_data->value.ll = getValue< short >(ref.address , index) ; v_data->type = TRICK_LONG_LONG ; break ; case TRICK_UNSIGNED_SHORT: v_data->value.ll = getValue< unsigned short >(ref.address , index) ; v_data->type = TRICK_LONG_LONG ; break ; case TRICK_INTEGER: v_data->value.ll = getValue< int >(ref.address , index) ; v_data->type = TRICK_LONG_LONG ; break ; case TRICK_UNSIGNED_INTEGER: v_data->value.ll = getValue< unsigned int >(ref.address , index) ; v_data->type = TRICK_LONG_LONG ; break ; case TRICK_LONG: v_data->value.ll = getValue< long >(ref.address , index) ; v_data->type = TRICK_LONG_LONG ; break ; case TRICK_UNSIGNED_LONG: v_data->value.ll = getValue< unsigned long >(ref.address , index) ; v_data->type = TRICK_LONG_LONG ; break ; case TRICK_LONG_LONG: v_data->value.ll = getValue< long long >(ref.address , index) ; v_data->type = TRICK_LONG_LONG ; break ; case TRICK_UNSIGNED_LONG_LONG: v_data->value.ll = getValue< unsigned long long >(ref.address , index) ; v_data->type = TRICK_LONG_LONG ; break ; case TRICK_DOUBLE: v_data->value.d = getValue< double >(ref.address , index) ; v_data->type = TRICK_DOUBLE ; break ; case TRICK_FLOAT: v_data->value.d = getValue< float >(ref.address , index) ; v_data->type = TRICK_DOUBLE ; break ; case TRICK_BOOLEAN: v_data->value.ll = getValue< bool >(ref.address , index) ; v_data->type = TRICK_LONG_LONG ; break ; default: break ; } return 0 ; } int swig_ref::__setitem__( PyObject * index , PyObject * obj1 ) { int ret = 0 ; void * argp2 ; /* Index types of ints, floats, swig_ints, and swig_doubles sent to __setitem__(int, PyObject *) */ if ( PyInt_Check(index)) { ret = __setitem__((int)PyInt_AsLong(index), obj1) ; } else if ( PyFloat_Check(index)) { ret = __setitem__((int)PyFloat_AsDouble(index), obj1) ; } else if (SWIG_IsOK(SWIG_ConvertPtr(index, &argp2,SWIG_TypeQuery("_p_swig_int"), 0 ))) { swig_int * temp_m = reinterpret_cast(argp2) ; ret = __setitem__((int)(temp_m->value), obj1) ; } else if (SWIG_IsOK(SWIG_ConvertPtr(index, &argp2,SWIG_TypeQuery("_p_swig_double"), 0 ))) { swig_double * temp_m = reinterpret_cast(argp2) ; ret = __setitem__((int)(temp_m->value), obj1) ; } else if ( PySlice_Check(index)) { Py_ssize_t ii , start , stop , step ; int status ; // TODO: make sure obj1 is list or tuple. Handle singular values on RHS // get the start, stop, and step value of the slice #if PY_VERSION_HEX >= 0x03000000 status = PySlice_GetIndices( index , ref.attr->index[0].size , &start , &stop , &step ) ; #else status = PySlice_GetIndices( (PySliceObject *)index , ref.attr->index[0].size , &start , &stop , &step ) ; #endif if ( status == 0 ) { V_TREE v_tree ; V_TREE * first_node , * curr_node ; unsigned int size ; unsigned int expected_slice_size ; if ( PyList_Check(obj1) ) { obj1 = PyList_AsTuple(obj1) ; } if ( PyTuple_Check(obj1) ) { size = PyTuple_Size(obj1) ; } else { size = 1 ; } expected_slice_size = ( stop - start + 1 ) / step ; if ( (step == 1) or (expected_slice_size == size) ) { // create a dummy first node. This simplifys code underneath. We will throw this first node away. first_node = curr_node = ( V_TREE * )calloc( 1 , sizeof(V_TREE) ) ; // copy the current data before replacement slice for ( ii = 0 ; ii < start ; ii++ ) { newVTreeNode(&curr_node) ; copyValue( curr_node->v_data , ref , ii ) ; } // insert slice data if ( step == 1 ) { // normal slice insertion, copy the whole list from RHS to vtree structure. if ( PyTuple_Check(obj1) ) { #if PY_VERSION_HEX < 0x02050000 for( ii = 0 ; ii < (int)size ; ii++ ) { #else for( ii = 0 ; ii < size ; ii++ ) { #endif newVTreeNode(&curr_node) ; PyObject *o = PyTuple_GetItem( obj1 , ii ) ; ret = setVData( curr_node->v_data , o , ref ) ; } } else { newVTreeNode(&curr_node) ; ret = setVData( curr_node->v_data , obj1 , ref ) ; } } else { // extended slice insertion where step != 1. Replace each element in existing data for( ii = 0 ; ii < stop - start ; ii++ ) { newVTreeNode(&curr_node) ; if ( ii % step == 0 ) { if ( PyTuple_Check(obj1) ) { PyObject *o = PyTuple_GetItem( obj1 , ii / step) ; ret = setVData( curr_node->v_data , o , ref ) ; } else { ret = setVData( curr_node->v_data , obj1 , ref ) ; } } else { copyValue( curr_node->v_data , ref , ii + start ) ; } } } // copy the current data after replacement slice for ( ii = stop ; ii < ref.attr->index[0].size ; ii++ ) { newVTreeNode(&curr_node) ; copyValue( curr_node->v_data , ref , ii ) ; } // skip first node because it has no data. v_tree.down = first_node->next ; free(first_node) ; REF2 ref_copy = ref ; ret = trick_MM->ref_assignment( &ref_copy , &v_tree ) ; // Free all of the allocations made above. curr_node = v_tree.down ; while ( curr_node != NULL ) { V_TREE * next_node = curr_node->next ; free(curr_node->v_data) ; free(curr_node) ; curr_node = next_node ; } } else { // RHS does not fit in space specified in slice ret = TRICK_SWIG_SLICE_ASSIGNMENT ; } } } else { /* Can't figure out what the index type was. */ ret = TRICK_SWIG_UNKNOWN_INDEX_TYPE ; } return ret ; } PyObject * swig_ref::__getitem__(int ii) { //cout << "In swig_ref getitem!! " << ii << " start address = " << ref.address << endl ; V_DATA v_data ; PyObject * ret = NULL ; int jj ; int status = 0 ; REF2 temp_ref ; deref_address() ; // convert python negative index to positive index temp_ref = ref ; if ( ii < 0 ) { ii += temp_ref.attr->index[0].size ; } v_data.type = TRICK_INTEGER ; v_data.value.i = ii ; /* Do a bounds check before calling ref_dim. Ref_dim would catch this error too, but it prints an error message that throws visitors off from the python error. Returining NULL will cause the input processor to die with an IndexError */ if ( (int)ii >= temp_ref.attr->index[0].size or ii < 0 ) { return NULL ; } else { status = trick_MM->ref_dim( &temp_ref , &v_data ) ; // Error in ref_dim if ( status != 0 ) { return NULL ; } } if ( temp_ref.num_index_left == 0 ) { switch ( temp_ref.attr->type ) { case TRICK_CHARACTER: { swig_int * t = new swig_int ; t->value = *(char *)temp_ref.address ; t->units = temp_ref.attr->units ; ret = SWIG_NewPointerObj(SWIG_as_voidptr(t), SWIG_TypeQuery("_p_swig_int"), SWIG_POINTER_OWN); } break ; case TRICK_UNSIGNED_CHARACTER: { swig_int * t = new swig_int ; t->value = *(unsigned char *)temp_ref.address ; t->units = temp_ref.attr->units ; ret = SWIG_NewPointerObj(SWIG_as_voidptr(t), SWIG_TypeQuery("_p_swig_int"), SWIG_POINTER_OWN); } break ; case TRICK_SHORT: { swig_int * t = new swig_int ; t->value = *(short *)temp_ref.address ; t->units = temp_ref.attr->units ; ret = SWIG_NewPointerObj(SWIG_as_voidptr(t), SWIG_TypeQuery("_p_swig_int"), SWIG_POINTER_OWN); } break ; case TRICK_UNSIGNED_SHORT: { swig_int * t = new swig_int ; t->value = *(unsigned short *)temp_ref.address ; t->units = temp_ref.attr->units ; ret = SWIG_NewPointerObj(SWIG_as_voidptr(t), SWIG_TypeQuery("_p_swig_int"), SWIG_POINTER_OWN); } break ; case TRICK_INTEGER: { swig_int * t = new swig_int ; t->value = *(int *)temp_ref.address ; t->units = temp_ref.attr->units ; ret = SWIG_NewPointerObj(SWIG_as_voidptr(t), SWIG_TypeQuery("_p_swig_int"), SWIG_POINTER_OWN); } break ; case TRICK_UNSIGNED_INTEGER: { swig_int * t = new swig_int ; t->value = *(unsigned int *)temp_ref.address ; t->units = temp_ref.attr->units ; ret = SWIG_NewPointerObj(SWIG_as_voidptr(t), SWIG_TypeQuery("_p_swig_int"), SWIG_POINTER_OWN); } break ; case TRICK_LONG: { swig_int * t = new swig_int ; t->value = *(long *)temp_ref.address ; t->units = temp_ref.attr->units ; ret = SWIG_NewPointerObj(SWIG_as_voidptr(t), SWIG_TypeQuery("_p_swig_int"), SWIG_POINTER_OWN); } break ; case TRICK_UNSIGNED_LONG: { swig_int * t = new swig_int ; t->value = *(unsigned long *)temp_ref.address ; t->units = temp_ref.attr->units ; ret = SWIG_NewPointerObj(SWIG_as_voidptr(t), SWIG_TypeQuery("_p_swig_int"), SWIG_POINTER_OWN); } break ; case TRICK_LONG_LONG: { swig_int * t = new swig_int ; t->value = *(long long *)temp_ref.address ; t->units = temp_ref.attr->units ; ret = SWIG_NewPointerObj(SWIG_as_voidptr(t), SWIG_TypeQuery("_p_swig_int"), SWIG_POINTER_OWN); } break ; case TRICK_UNSIGNED_LONG_LONG: { swig_int * t = new swig_int ; t->value = *(unsigned long long *)temp_ref.address ; t->units = temp_ref.attr->units ; ret = SWIG_NewPointerObj(SWIG_as_voidptr(t), SWIG_TypeQuery("_p_swig_int"), SWIG_POINTER_OWN); } break ; case TRICK_DOUBLE: { //cout << "swig_ref::__getitem__ returning a swig_double!! " << temp_ref.address << endl ; swig_double * t = new swig_double ; t->value = *(double *)temp_ref.address ; t->units = temp_ref.attr->units ; ret = SWIG_NewPointerObj(SWIG_as_voidptr(t), SWIG_TypeQuery("_p_swig_double"), SWIG_POINTER_OWN); } break ; case TRICK_FLOAT: { swig_double * t = new swig_double ; t->value = *(float *)temp_ref.address ; t->units = temp_ref.attr->units ; ret = SWIG_NewPointerObj(SWIG_as_voidptr(t), SWIG_TypeQuery("_p_swig_double"), SWIG_POINTER_OWN); } break ; case TRICK_BOOLEAN: { swig_int * t = new swig_int ; t->value = *(bool *)temp_ref.address ; t->units = temp_ref.attr->units ; ret = SWIG_NewPointerObj(SWIG_as_voidptr(t), SWIG_TypeQuery("_p_swig_int"), SWIG_POINTER_OWN); } break ; default: { std::string type_name ; type_name = std::string("_p_") + temp_ref.attr->type_name ; // change namespace ':' separators to '_' std::replace( type_name.begin() , type_name.end() , ':' , '_' ) ; // remove any "*" characters at the end of the type_name size_t found = type_name.find(" ") ; if ( found != std::string::npos) { type_name.erase(found) ; } ret = SWIG_NewPointerObj(SWIG_as_voidptr(temp_ref.address), SWIG_TypeQuery(type_name.c_str()), 0); } break ; } } else if ( temp_ref.attr->type == TRICK_STRUCTURED and temp_ref.attr->num_index == 2) { // Special case where we are dereferencing a double dimensional structure. // We want to return a pointer to the correct structure type, not a swig_ref. std::string type_name ; void * new_addr ; //std::cout << "double dim returing type " << temp_ref.attr->type_name << std::endl ; type_name = std::string("_p_") + temp_ref.attr->type_name ; // change namespace ':' separators to '_' std::replace( type_name.begin() , type_name.end() , ':' , '_' ) ; // remove any "*" characters at the end of the type_name size_t found = type_name.find(" ") ; if ( found != std::string::npos) { type_name.erase(found) ; } // Dereference the pointer if this was a pointer dimension if ( temp_ref.attr->index[temp_ref.num_index].size == 0 ) { new_addr = *(void**)temp_ref.address ; } else { new_addr = temp_ref.address ; } ret = SWIG_NewPointerObj(SWIG_as_voidptr(new_addr), SWIG_TypeQuery(type_name.c_str()), 0); } else { /* Takes care of non final dimensions for all cases. We have already called ref_dim to get to the correct index in the current array. Create a new swig_ref that contains the indexed address. All of the dimensional information will be shifted by one in the new swig_ref. */ /* Create a new swig_ref to hold the new dereferenced variable */ swig_ref * new_ref = new swig_ref ; /* Copy temp_ref that holds the indexed address as a result of ref_dim */ new_ref->ref = temp_ref ; /* Create a new attributes instance to because we're going to be modifying it below */ ATTRIBUTES * new_attr = new ATTRIBUTES() ; /* Start with the current attributes we have */ *new_attr = *temp_ref.attr ; new_ref->ref.attr = new_attr ; /* make copies of the strings for type_name and units */ new_ref->ref.attr->type_name = strdup(temp_ref.attr->type_name) ; new_ref->ref.attr->units = strdup(temp_ref.attr->units) ; // Shift all remaining dimension information to the left new_ref->ref.attr->num_index-- ; new_ref->ref.num_index-- ; for ( jj = 0 ; jj < new_ref->ref.attr->num_index ; jj++ ) { new_ref->ref.attr->index[jj].size = new_ref->ref.attr->index[jj + 1].size ; } // If the current index is a pointer mark this swig_ref as needing to dereference if ( new_ref->ref.attr->index[0].size == 0 ) { new_ref->need_to_deref = true ; } ret = SWIG_NewPointerObj(SWIG_as_voidptr(new_ref), SWIG_TypeQuery("_p_swig_ref"), 0); } return ret ; } template < class SWIG_TYPE , class VALUE_TYPE > PyObject * getValueAsSwigObjectByType( REF2 & temp_ref , Py_ssize_t index , const char * swig_type ) { SWIG_TYPE * t = new SWIG_TYPE ; VALUE_TYPE * casted_address = ( VALUE_TYPE * ) temp_ref.address ; t->value = *(casted_address + index ) ; t->units = temp_ref.attr->units ; return SWIG_NewPointerObj(SWIG_as_voidptr(t), SWIG_TypeQuery(swig_type), SWIG_POINTER_OWN); } PyObject * getValueAsObject( REF2 & temp_ref , Py_ssize_t index ) { switch ( temp_ref.attr->type ) { case TRICK_CHARACTER: return getValueAsSwigObjectByType< swig_int , char >(temp_ref , index , "_p_swig_int") ; case TRICK_UNSIGNED_CHARACTER: return getValueAsSwigObjectByType< swig_int , unsigned char >(temp_ref , index , "_p_swig_int") ; case TRICK_SHORT: return getValueAsSwigObjectByType< swig_int , short >(temp_ref , index , "_p_swig_int") ; case TRICK_UNSIGNED_SHORT: return getValueAsSwigObjectByType< swig_int , unsigned short >(temp_ref , index , "_p_swig_int") ; case TRICK_INTEGER: return getValueAsSwigObjectByType< swig_int , int >(temp_ref , index , "_p_swig_int") ; case TRICK_UNSIGNED_INTEGER: return getValueAsSwigObjectByType< swig_int , unsigned int >(temp_ref , index , "_p_swig_int") ; case TRICK_LONG: return getValueAsSwigObjectByType< swig_int , long >(temp_ref , index , "_p_swig_int") ; case TRICK_UNSIGNED_LONG: return getValueAsSwigObjectByType< swig_int , unsigned long >(temp_ref , index , "_p_swig_int") ; case TRICK_LONG_LONG: return getValueAsSwigObjectByType< swig_int , long long >(temp_ref , index , "_p_swig_int") ; case TRICK_UNSIGNED_LONG_LONG: return getValueAsSwigObjectByType< swig_int , unsigned long long >(temp_ref , index , "_p_swig_int") ; case TRICK_DOUBLE : return getValueAsSwigObjectByType< swig_double , double >(temp_ref , index , "_p_swig_double") ; case TRICK_FLOAT: return getValueAsSwigObjectByType< swig_double , float >(temp_ref , index , "_p_swig_double") ; case TRICK_BOOLEAN: return getValueAsSwigObjectByType< swig_int , bool >(temp_ref , index , "_p_swig_int") ; default : return NULL ; } return NULL ; } PyObject * swig_ref::__getitem__( PyObject * index ) { PyObject * ret = NULL ; int status = 0 ; deref_address() ; REF2 temp_ref = ref ; void * argp2 ; //std::cout << "In swig_ref::__getitem__( PyObject * index )!!!\n" << std::endl ; if ( PyInt_Check(index)) { ret = __getitem__((int)PyInt_AsLong(index)) ; } else if ( PyFloat_Check(index)) { ret = __getitem__((int)PyFloat_AsDouble(index)) ; } else if (SWIG_IsOK(SWIG_ConvertPtr(index, &argp2,SWIG_TypeQuery("_p_swig_int"), 0 ))) { swig_int * temp_m = reinterpret_cast(argp2) ; ret = __getitem__((int)(temp_m->value)) ; } else if (SWIG_IsOK(SWIG_ConvertPtr(index, &argp2,SWIG_TypeQuery("_p_swig_double"), 0 ))) { swig_double * temp_m = reinterpret_cast(argp2) ; ret = __getitem__((int)(temp_m->value)) ; } else if ( PySlice_Check(index)) { Py_ssize_t ii , start , stop , step ; // get the start, stop, and step value of the slice #if PY_VERSION_HEX >= 0x03000000 status = PySlice_GetIndices( index , temp_ref.attr->index[0].size , &start , &stop , &step ) ; #else status = PySlice_GetIndices( (PySliceObject *)index , temp_ref.attr->index[0].size , &start , &stop , &step ) ; #endif if ( status == 0 ) { // only work with final index of array... no pointer dims yet. (Alex) if ( temp_ref.num_index_left == 1 ) { ret = PyList_New(0) ; if ( step > 0 ) { for ( ii = start ; ii < stop ; ii += step ) { PyObject * new_obj = getValueAsObject( temp_ref , ii ) ; if ( new_obj ) { PyList_Append( ret , new_obj ) ; } } } else { for ( ii = start ; ii > stop ; ii += step ) { PyObject * new_obj = getValueAsObject( temp_ref , ii ) ; if ( new_obj ) { PyList_Append( ret , new_obj ) ; } } } } else { std::cout << "Array slices currently only work with single dimensional objects" << std::endl ; } } else { std::cout << "Slice parameters do not fit within list length of " << temp_ref.attr->index[0].size << std::endl ; } } else { std::cout << "Unknown object type as array index" << std::endl ; } return ret ; }