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I am learning inheritance in C++11, and I found that if a derived class has redefined a virtual function name but with a different prototype, a base-class pointer assigned with a pointer to the derived class can only access the base class version of the function. The derived version function cannot be accessed. I wonder why this happens.

class Enemy {
public:
  virtual void describe() { std::cout << "Enemy"; }
};
class Dragon : public Enemy {
public:
  virtual void describe(int dummy) { std::cout << "Dragon"; }
};

In main,

Dragon foo;
Enemy* pe = &foo;
pe->describe(); // Enemy
foo.describe(1); // Dragon
pe->describe(1); // no matching function, candidate is Enemy::describe()

From what I know about virtual function tables, the derived object that pe points to (i.e. foo) should have a vpointer member that points to Dragon's vtable. I also know that redefinition of a function name in the derived class will hide all the functions of the same name in the base class. So in Dragon's vtable the address of 'describe' should be the function with parameter int dummy.

But it turns out that pe can access Enemy's version of the method, which is supposed to be hided. And pe cannot access Dragon's version of the method, which is supposed to be in pe's vtable. It performs as if the Enemy's vtable is used. Why this happens?

Update: I think now I more or less understand the mechanisms behind it. Here is my hypothesis:

Since it is a pointer to Enemy, the program will first find the method name in Enemy's scope. If the name is not found, the compiler gives an error. If it is not virtual, then call it. If it is virtual, then record the method's offset in Enemy's vtable. Then the program use this offset to access the right method in the target object's vtable.

If the method is properly overrided, the function address in target object's vtable at that offset would have been changed. Otherwise, it will be the same function address as in the Enemy's vtable, as in the example.

Since Dragon's describe with int dummy is a different prototype, it is added to the Dragon's vtable after the original describe it inherited from Enemy. But the int dummy version cannot be accessed from Enemy* because Enemy's vtable doesn't even have that offset.

Is this correct?

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  • pe is using the Enemy API, and the method being accessed is not part of that API.
    – Eljay
    Oct 15, 2019 at 2:30
  • I have updated my hypothesis on what's happening in the example.
    – Elucidase
    Oct 15, 2019 at 5:44

3 Answers 3

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In fact you have:

class Enemy {
public:
  virtual void describe() { std::cout << "Enemy"; }
};

class Dragon : public Enemy {
public:
  // void describe() override { Enemy::describe(); } // Hidden
  virtual void describe(int dummy) { std::cout << "Dragon"; }
};

Selection of overload method is done statically:

  • pointers/references on Enemy only see void Enemy::describe()

  • pointers/references on Dragon only see void Dragon::describe(int) (but could explicitly have access to void Enemy::describe()).

Then virtual dispatch is done with runtime type.

So

Dragon foo;
Enemy* pe = &foo;

foo.describe();         // KO: Enemy::describe() not visible (1)
foo.Enemy::describe();  // OK: Enemy::describe()
foo.describe(1);        // OK: Dragon::describe(int)

pe->describe();         // OK: Enemy::describe()
pe->describe(1);        // KO: No Enemy::describe(int)
pe->Dragon::describe(1);// KO: Dragon is not a base class of Enemy

(1) can be fixed by changing Dragon with

class Dragon : public Enemy {
public:
  using Enemy::describe; // Unhide Enemy::describe()

  virtual void describe(int dummy) { std::cout << "Dragon"; }
};
2
  • But why pe->describe is static binding (dispatch) instead of dynamic binding? I assumed that during runtime, when the program is trying to dispatch a virtual method, it will look into the virtual function table of the object. In this case it is Dragon's vtable.
    – Elucidase
    Oct 15, 2019 at 4:05
  • void (C::*)describe() and void (C::*)describe(int) are 2 different signatures. Dragon vtable would have 2 entries, one for Enemy::describe() (which it doesn't override, so would have same value than an Enemy instance), one for Dragon::describe(int).
    – Jarod42
    Oct 15, 2019 at 7:58
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Functions with the same name but different signatures are essentially different functions.

By declaring virtual void describe(int dummy) in your Dragon class, you have declared a new virtual function, not overriding the original one (virtual void describe() in Enemy). You can only override virtual functions with the same signature.

You cannot call describe(1) on a pointer to Enemy because c++ calls function according to the instance's compile time type (although such a call can be dynamically dispatched to call the actual overrode method).

5
  • But why here the function is dispatched at compile time but not runtime? From my understanding, if the function is dispatched during runtime, the program should be able to find a describe in Dragon's vtable, though it is unrelated to the describe in Enemy. Is this true?
    – Elucidase
    Oct 15, 2019 at 4:11
  • @Elucidase The function is there in the vtable, but cannot be accessed from a pointer to Enemy, because Enemy does not have that member function (it has one with the same name, but not the same member function).
    – ph3rin
    Oct 15, 2019 at 4:41
  • @Elucidase Also, think from the perspective of the compiler. If you have another type, say, Soldier that also derives from Enemy, that has the describe method, but with signature describe() (without int). You give the compiler a pointer to Enemy, and call describe(1) on it. How would the compiler know at the compiler whether it has Dragon type or Soldier type? Virtual methods is a good way to create a solid interface for function calling, not to improvise on various parameters.
    – ph3rin
    Oct 15, 2019 at 4:47
  • But when the function is properly overrided, the program can access Dragon's vtable from a Enemy* pointer. And from what I learned, it seems vtable and dynamic dispatch are exactly the mechanisms to deal with the situations where the type is not known during compile time.
    – Elucidase
    Oct 15, 2019 at 5:01
  • @Elucidase What you are suggesting is theoretically possible (evidence: there is dynamic_cast in c++), but they are simply not permitted in your context.
    – ph3rin
    Oct 15, 2019 at 5:54
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In C++, functions that have the same name but different parameters are completely independent functions, that have nothing to do with each other. The fact that they have the same name is completely immaterial.

It is exactly the same as if you called the function in the base class "apple", and the one in the derived class "banana". Since there is no "banana" function in the base class, you cannot obviously call it in the base class. The banana function in the derived class obviously does not override the function in the base class.

I also know that redefinition of a function name in the derived class will hide all the functions of the same name in the base class.

That is incorrect. It hides it only if it has the same name, but also identical parameters (and any qualifiers, if there are or are not any).

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