Reading C type expressions
createClassFunction is a typedef for a function taking no arguments and returning a
With that declaration, a pointer to such a funciton can obviously act as factory for a
Class. Usage might be as follows:
// the class factory
Class * MostTrivialFactoryKnownToMan()
return new Class;
// another class factory
Class * CreateClassWithLog()
ClassWithLog * p = new ClassWithLog; // derived from Class
// code consuming the class factory
void PopulateStars(createClassFunction * factory)
// creates many instances of `Class` through `factory`
Sky * sky = GetSky();
for(int i=0; i<sky->GetStarCount(); ++i)
Class * inhabitant = (*factory)();
// code deciding which factory to use
const bool todayWeWriteALog = (rand() %2) != 0;
createClassFunction * todaysFactory = todayWeWriteALog ?
__stdcallis a compiler specific attribute changin the calling convention (how parameters and return value are passed between caller and implementation). This is often important for binary compatibility - e.g. when a Pascal program needs to call a funciton imlemented in C or C++.
The factory function returns a raw pointer. There must be an implicit contract between the factory and the consumer how to free that pointer (e.g. through
delete in or example).
Using a smart pointer (e.g. shared_ptr) for the return type would allow the factory to determine the deletion policy.
The factory, as a function pointer, may not hold state (such as the log file name, it needs to be hard coded in the function, or available globally). using a callable object instead would allow to implement configurable factories.