0

My understanding of C++ arrays is that you can't allocate an array of abstract class objects since C++ doesn't know how to allocate memory for a yet-to-be-decided class type.

I put together a little example that confuses me a bit, so wanted to ask a bit more

#include <iostream>

class Animal {
public:
  virtual void hello() {}
};

class Dog : public Animal {
public:
  void hello() { std::cout << "woof!" << std::endl; }
};

class Cat : public Animal {
public:
  void hello() { std::cout << "meow" << std::endl; }
};

int main() {
  Dog d;
  d.hello(); // prints "woof!"

  Cat c;
  c.hello(); // prints "meow"

  // how are we allowed to create an array of abstract class?
  // doesn't c++ need to know how to allocate memory for any abstract
  // class in order to do this?
  Animal creatures[5];
  creatures[0] = d;
  creatures[1] = c;
  creatures[4] = d;

  // prints "6Animal"
  std::cout << typeid(creatures[0]).name() << std::endl;

  // this appears to call the Animal hello(), which does nothing
  creatures[1].hello();
}

Questions

  1. How is C++ able to allocate memory for this array? Why doesn't it complain?
  2. It appears something about this not failing is due to treating all the objects as Animals, ie: not properly doing polymorphism. What exactly is going on, and why? Do I just have to allocate for a list of pointers to do this properly instead?

Thanks!

  • 1
    Hint: try substituting virtual void hello() {} with virtual void hello() = 0; to observe different results. – Ron Mar 19 '20 at 20:59
  • 1
    The function is not pure virtual. – Eraklon Mar 19 '20 at 20:59
4

Animal is not abstract. It contains no pure virtual member functions. When you assign c and d to the elements of creatures you are slicing them.

If instead, Animal::hello had been declared pure-virtual, i.e.

class Animal {
public:
  virtual void hello() = 0;
};

Animal creatures[5] would fail to compile since Animal is now abstract.


As per your second question, runtime polymorphism in C++ only works with references and pointers. If you're familiar with languages like Java or Python this can seem a bit odd at first, but remember that in those languages all variables of class types are pointers (or pointer-like things, anyway).

In C++, Animal creatures[5] will be laid out in memory something like this:

creatures
+--------+--------+--------+--------+--------+
| Animal | Animal | Animal | Animal | Animal |
+--------+--------+--------+--------+--------+

In Java, Animal[] creatures = new Animal[5]; will be laid out in memory like this:

+-----------+   +---+---+---+---+---+
| creatures +-->+ 0 | 1 | 2 | 3 | 4 |
+-----------+   +-+-+-+-+-+-+-+-+-+-+
                  |   |   |   |   |
       +--------+ |   |   |   |   | +--------+
       | Object +<+   |   |   |   +>+ Object |
       +--------+     |   |   |     +--------+
                      v   |   v
               +------+-+ |  ++-------+
               | Object | |  | Object |
               +--------+ |  +--------+
                          v
                     +----+---+
                     | Object |
                     +--------+

There is no direct analogue for C++ arrays in languages like Java or Python

That means that all objects in a C++ array must be the exact same type. If you want to build something like the Java array, you must use pointers. You should use the standard smart-pointer classes std::unique_ptr and std::shared_ptr so that the allocated memory gets automatically cleaned up, since C++ does not have a garbage collector. i.e.

std::shared_ptr<Animal> creatures[5];
creatures[0] = std::make_shared<Dog>();
creatures[1] = std::make_shared<Cat>();

creatrues[0]->hello(); // prints "woof!"
creatures[1]->hello(); // prints "meow"

Live Demo

  • Ah, I see. So how do we best achieve polymorphism in this case? do we have to resort to pointers? – lollercoaster Mar 19 '20 at 21:11
  • Yes, runtime polymorphism in C++ only works with pointers and references. See my edit. – Miles Budnek Mar 19 '20 at 21:14
  • 1
    I would recommend changing the std::shared_ptr to a std::unique_ptr. The default should always be std::unique_ptr; you don't want a shared pointer unless you know for a fact that there will be a multiple ownership scenario. Even then, you might not need it. – sweenish Mar 19 '20 at 21:25
  • @sweenish I agree std::unique_ptr should be the default, but I used std::shared_ptr to be as similar to the Java example as possible (Java references work via entirely different mechanisms, but they also allow multiple-ownership). – Miles Budnek Mar 19 '20 at 21:28

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.