Why do std::shared_ptr<void> work
The trick is that std::shared_ptr performs type erasure. Basically, when a new shared_ptr is created it will store internally a deleter function (which can be given as argument to the constructor but if not present defaults to calling delete). When the shared_ptr is destroyed, it calls that stored function and that will call the deleter.
A simple sketch of the type erasure that is going on simplified with std::function, and avoiding all reference counting and other issues can be seen here:
template <typename T>
void delete_deleter( void * p ) {
delete static_cast<T*>(p);
}
template <typename T>
class my_unique_ptr {
std::function< void (void*) > deleter;
T * p;
template <typename U>
my_unique_ptr( U * p, std::function< void(void*) > deleter = &delete_deleter<U> )
: p(p), deleter(deleter)
{}
~my_unique_ptr() {
deleter( p );
}
};
int main() {
my_unique_ptr<void> p( new double ); // deleter == &delete_deleter<double>
}
// ~my_unique_ptr calls delete_deleter<double>(p)
When a shared_ptr is copied (or default constructed) from another the deleter is passed around, so that when you construct a shared_ptr<T> from a shared_ptr<U> the information on what destructor to call is also passed around in the deleter.
shared_ptr<T> logically[*] has (at least) two relevant data members:
- a pointer to the object being managed
- a pointer to the deleter function that will be used to destroy it.
The deleter function of your shared_ptr<Test>, given the way you constructed it, is the normal one for Test, which converts the pointer to Test* and deletes it.
When you push your shared_ptr<Test> into the vector of shared_ptr<void>, both of those are copied, although the first one is converted to void*.
So, when the vector element is destroyed taking the last reference with it, it passes the pointer to a deleter that destroys it correctly.
It's actually a little more complicated than this, because shared_ptr can take a deleter functor rather than just a function, so there might even be per-object data to be stored rather than just a function pointer. But for this case there is no such extra data, it would be sufficient just to store a pointer to an instantiation of a template function, with a template parameter that captures the type through which the pointer must be deleted.
[*] logically in the sense that it has access to them - they may not be members of the shared_ptr itself but instead of some management node that it points to.
It works because it uses type erasure.
Basically, when you build a shared_ptr, it passes one extra argument (that you can actually provide if you wish), which is the deleter functor.
This default functor accepts as argument a pointer to type you use in the shared_ptr, thus void here, casts it appropriately to the static type you used test here, and calls the destructor on this object.
Any sufficiently advanced science feels like magic, isn't it ?