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I have the following code:

struct A {
protected:
    A() {}

    A* a;
};

struct B : A {
protected:
    B() { b.a = &b; }

    A b;
};

It strangely doesn't compile. The culprit is the b.a = &b; assignment: both GCC and clang complain that A() is protected, which shouldn't be a problem because B inherits A. Which dark corner of the standard have I come into?

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3  
You can only access protected members of this' base (same instance). this and b are not the same instance. –  jrok Sep 4 '12 at 20:35
2  
@MikeSeymour nope. (but I admit I thought the exact same thing until recently) –  Luchian Grigore Sep 4 '12 at 20:37
    
I'm sure this has been asked many times before, but it's hard to locate the exact duplicate. –  dasblinkenlight Sep 4 '12 at 20:38
1  
By the way, the assignment is not the culprit, but one of them. –  eq- Sep 4 '12 at 20:38
1  
"Cannot access protected member of base class in derived class" maybe? –  jrok Sep 4 '12 at 20:45

4 Answers 4

up vote 18 down vote accepted

The meaning of protected is that the derived type will have access to that member of it's own base and not of any random object*. In your case, you care trying to modify b's member which is outside of your control (i.e. you can set this->a, but not b.a)

There is a hack to get this to work if you are interested, but a better solution would be to refactor the code and not depend on hacks. You could, for example, provide a constructor in A that takes an A* as argument (this constructor should be public) and then initialize it in the initializer list of B:

A::A( A* p ) : a(p) {}
B::B() : b(&b) {}

* protected grants you access to the base member in any instance of your own type or derived from your own type.

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+1: I always hear the saying "access-control works on a per-class basis, not a per-object basis", but it seems protected is the one exception to this rule? –  Jesse Good Sep 4 '12 at 20:53
1  
@JesseGood: Not really, it is still per-class. I was maybe too vague in the answer. You have access to the member in any object of type B or derived from B, just not in objects of type A or derived from A (that are not B) –  David Rodríguez - dribeas Sep 4 '12 at 20:56
    
Note you can also trick the compiler using a reinterpret_cast. Ugly, and may be dangerous, but... –  Macmade Sep 4 '12 at 21:04
    
@Macmade: reinterpret_cast as a general recommendation is dangerous, as it depends on the types having standard layout and the objects being aligned (i.e. will only work with the first base, and not always). A static_cast might actually be a better option, although it is still dangerous (virtual bases), it will at least adapt the offset of the base subobject (if it can) or... well, it is all undefined behavior anyway. At any rate, reinterpret_cast is a really bad recommendation for almost anything. –  David Rodríguez - dribeas Sep 4 '12 at 21:15

There are actually two separate problems here.

The first is that the line doesn't just do an assignment, but tries to initialize the base class (which works fine) and the member b. To create the b member it needs to construct it, and as a member it needs public access to a constructor, which it doesn't have.

Then the assignment also is unable to access non-public member of b because again, it's not of type B but type A instead.

Remember that protected means you can access parts of A through a B object (or child) only.

In this case tell us your real problem and we can try to help solve it. Inheriting and composing from the same type is a design smell.

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All the compilers that I tested complained about several things, and specifically the protected constructor would be a problem even if the assignment statement were removed.

You don't get to access the protected members of any instance of a type you derive from. This issue is clarified in the examples of 11.4p1.

class B {
protected:
  int i;
  static int j;
};

class D1 : public B {
};

class D2 : public B {
  void mem(B*, D1*);
};

void D2::mem(B* pb, D1* p1) {
  pb->i = 1; // ill-formed
  p1->i = 2; // ill-formed
  // ...
}
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It seems like a big limitation of the C++ language. How would you solve problem like this:

class Node
{
public:
 void Save();
protected:
 virtual void SaveState(int type) = 0;
};

class BinaryNode : public Node
{
protected:
 Node *left;
 Node *right;

 virtual void SaveState(int type) override
 {
    left->SaveState(type);
    right->SaveState(type);
 }
};

In this example I do not want to make method SaveState visible outside Node hierarchy. Only method Save should be public.

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