static void handle_ompss_opencl_allocate_intrinsic( Nodecl::FunctionCall function_call, std::map<std::pair<TL::Type, std::pair<int, bool> > , Symbol> &declared_ocl_allocate_functions, Nodecl::NodeclBase expr_stmt) { Nodecl::List arguments = function_call.get_arguments().as<Nodecl::List>(); ERROR_CONDITION(arguments.size() != 1, "More than one argument in 'ompss_opencl_allocate' call\n", 0); Nodecl::NodeclBase actual_argument = arguments[0]; ERROR_CONDITION(!actual_argument.is<Nodecl::FortranActualArgument>(), "Unexpected tree\n", 0); Nodecl::NodeclBase arg = actual_argument.as<Nodecl::FortranActualArgument>().get_argument(); ERROR_CONDITION(!arg.is<Nodecl::ArraySubscript>(), "Unreachable code\n", 0); Nodecl::NodeclBase subscripted = arg.as<Nodecl::ArraySubscript>().get_subscripted(); TL::Symbol subscripted_symbol = ::fortran_data_ref_get_symbol(subscripted.get_internal_nodecl()); ERROR_CONDITION( !(subscripted_symbol.get_type().is_fortran_array() && subscripted_symbol.is_allocatable()) && !(subscripted_symbol.get_type().is_pointer() && subscripted_symbol.get_type().points_to().is_fortran_array()), "The argument of 'ompss_opencl_allocate' intrinsic must be " "an allocatable array or a pointer to an array with all its bounds specified\n", 0); TL::Type array_type; int num_dimensions; bool is_allocatable; if (subscripted_symbol.is_allocatable()) { array_type = subscripted_symbol.get_type(); num_dimensions = subscripted_symbol.get_type().get_num_dimensions(); is_allocatable = true; } else { array_type = subscripted_symbol.get_type().points_to(); num_dimensions = array_type.get_num_dimensions(); is_allocatable = false; } TL::Type element_type = array_type; while (element_type.is_array()) { element_type = element_type.array_element(); } ERROR_CONDITION(!array_type.is_array(), "This type should be an array type", 0); std::pair<TL::Type, std::pair<int, bool> > key = std::make_pair(element_type, std::make_pair(num_dimensions, is_allocatable)); std::map<std::pair<TL::Type, std::pair<int, bool> > , Symbol>::iterator it_new_fun = declared_ocl_allocate_functions.find(key); // Reuse the auxiliar function if it already exists Symbol new_function_sym; if (it_new_fun != declared_ocl_allocate_functions.end()) { new_function_sym = it_new_fun->second; } else { new_function_sym = create_new_function_opencl_allocate( expr_stmt, subscripted_symbol, element_type, num_dimensions, is_allocatable); declared_ocl_allocate_functions[key] = new_function_sym; } // Replace the current intrinsic call by a call to the new function TL::Source actual_arg_array; Nodecl::NodeclBase subscripted_lvalue = subscripted.shallow_copy(); subscripted_lvalue.set_type(subscripted_symbol.get_type().no_ref().get_lvalue_reference_to()); actual_arg_array << as_expression(subscripted_lvalue); TL::Source actual_arg_bounds; Nodecl::List subscripts = arg.as<Nodecl::ArraySubscript>().get_subscripts().as<Nodecl::List>(); for (Nodecl::List::reverse_iterator it = subscripts.rbegin(); it != subscripts.rend(); it++) { Nodecl::NodeclBase subscript = *it, lower, upper; if (it != subscripts.rbegin()) actual_arg_bounds << ", "; if (subscript.is<Nodecl::Range>()) { lower = subscript.as<Nodecl::Range>().get_lower(); upper = subscript.as<Nodecl::Range>().get_upper(); } else { lower = nodecl_make_integer_literal( fortran_get_default_integer_type(), const_value_get_signed_int(1), make_locus("", 0, 0)); upper = subscript; } actual_arg_bounds << as_expression(lower) << "," << as_expression(upper); } TL::Source new_function_call; new_function_call << "CALL " << as_symbol(new_function_sym) << "(" << actual_arg_array << ", " << actual_arg_bounds << ")\n" ; expr_stmt.replace(new_function_call.parse_statement(expr_stmt)); }