Simply stated, an
enum is simply a named constant value, for instance:
In the above example,
setting_number_X is simply a named constant for the value
X, as enumeration values start at 0 and increase monotonically.
Keeping these then, in some type of container gives a basic storage type of integers, but can still be somewhat typesafe.
// this works
// this is a compile time failure, even though the underlying storage
// type for Setting is an integral value. This keeps you from adding
// invalid settings types to your container (like 13 here)
// but you also cannot (directly) add valid setting values (like 1)
// as an integral, this is also a compile time failure.
Now, suppose you wanted to add additional specific setting types and keep them all in a container.
Now, if you wanted to keep all the settings in a single container, you cannot safely. You could store all the integral values in a container of
std::vector<int> or similar, but that breaks down in that you cannot determine what integral types belong to what setting enumerations. Also, since the types are different you cannot store them in a single type-safe container.
The correct way to go about this is would be to store the functionality of the setting in the container, something like this:
// This is our "base class" type so we can store lots of
// different setting types in our container
// we enable the setting by calling our function
// This is a function pointer, and we're using it to get some
// compile time polymorphism
typedef void (*setting_function_type)(setting_action* setting);
// these can only be constructed by derived types, and the derived
// type will provide the polymorhpic behavior by means of the
// above function pointer and based on the derived type's handler
// This is the derived type, and where most of the magic
// happens. This is templated on our actual setting type
// that we define below
template <class Setting>
: public setting_action
// This function catches the "enable_setting" call from
// our base class, and directs it to the handler functor
// object that we've defined
static void enable_setting(setting_action* base)
templated_setting_action<Setting>* local_this =
// this is just a shorthand way of creating the specialized types
template <class T>
setting_action* create_specialized_setting_action(T type)
// Our actual settings:
// this one displays the user name
std::cout << "Chad.\n";
// this one displays a short welcome message
std::cout << "Ahh, the magic of templates. Welcome!\n";
// now, we can have one container for ALL our application settings
// now we can add our settings to the container...
// and individually enable them
// also, need to delete each setting to avoid leaking the memory
// left as an exercise for the reader :)