In this case, we have inheritance but no polymorphism:
struct SimpleBase {
int i;
int get() const { return i; }
};
struct SimpleDerived: public SimpleBase {
int get() const { return i + 7; }
};
an instance of SimpleBase (or a reference or pointer to it) is always exactly that, and the derived class can't change its behaviour. For example:
int foo(SimpleBase const &obj) { return obj.get(); }
will always call SimpleBase::get
, even if I pass in an instance of the derived type.
Conversely, with polymorphism, a derived class can override base class methods with its own versions:
struct PolyBase {
int i;
virtual int get() const { return i; }
};
struct PolyDerived {
int get() const { return i + 7; }
};
int foo(PolyBase const &obj) { return obj.get(); }
Now foo calls a different method depending on the derived type passed in, without knowing which derived type it is.
So with polymorphism, a whole family of types can share a common interface, and you can write code once that operates on the interface, without having to know about all the different derived types.
The form of polymorphism shown above is run-time polymorphism: it generates code that figures out which implementation of each virtual function to call when it runs.
There is also compile-type polymorphism, which doesn't require inheritance at all, and instead uses templates.
Say you want to write a sorted container (like std::map) - you don't want to limit it to storing a particular data type, but you do need some way to compare two elements to see which is bigger.
The run-time approach might provide an abstract base class, like
struct LessThanComparable {
virtual bool operator< (LessThanComparable const &) const = 0;
};
and require every type you want to put in your container, to derive from this and implement operator<
. Then, you can write if (a < b)
in your container code, and the right function for the type you're storing will be called (*).
// requires inheritance from abstract base class,
// uses virtual call to operator<
bool less_than(LessThanComparable const &a, LessThanComparable const &b) {
return a < b;
}
The compile-type approach actually used (**) in the STL is to state that every stored type must model the LessThanComparable concept, by providing a suitable operator<
. However, this is resolved at compile time, and no common base class is required.
// doesn't require any inheritance, doesn't use virtual function call,
template <typename T>
bool less_than(T const &a, T const &b) { return a < b; }
(*) note also that implementing operator<
isn't trivial, because a < b
can be called when a and b have different derived types. In the template version, we know they both have the same type T.
(**) ok, so the default std::less
has the LessThanComparable requirement, or you can provide an alternative StrictWeakOrdering.