3

Running this C++ Source on Visual C++ 2010:

class B{
public:
    virtual void f(int a){}
    virtual void f(){}
};
class A:public B{
public:
    virtual void f(int a){}
};
int main(){
A a;
a.f();
return 0;
}

Leads to the following error:

IntelliSense: too few arguments in function call

In other words, it seems that void f() didn't inherited?

What is the problem?

3

3 Answers 3

7

it seems that void f() didn't inherited?

The name f in class A shadows name f in B. You can still access foo() from B this way

A a;
a.B::f();

Other option is to redeclare function foo of B in the scope of A:

class A : public B{
public:

    virtual void f(int a) {}
    using B::foo;
};

C++ Standard n3337 § 10.2 Member name lookup

1) Member name lookup determines the meaning of a name (id-expression) in a class scope (3.3.7). Name lookup can result in an ambiguity, in which case the program is ill-formed. For an id-expression, name lookup begins in the class scope of this; for a qualified-id, name lookup begins in the scope of the nested- name-specifier. Name lookup takes place before access control (3.4, Clause 11).

2) The following steps define the result of name lookup for a member name f in a class scope C.

3) The lookup set for f in C, called S(f, C), consists of two component sets: the declaration set, a set of members named f; and the subobject set, a set of subobjects where declarations of these members (possibly including using-declarations) were found. In the declaration set, using-declarations are replaced by the members they designate, and type declarations (including injected-class-names) are replaced by the types they designate. S(f, C) is calculated as follows:

4) If C contains a declaration of the name f, the declaration set contains every declaration of f declared in C that satisfies the requirements of the language construct in which the lookup occurs. [ Note: Looking up a name in an elaborated-type-specifier (3.4.4) or base-specifier (Clause 10), for instance, ignores all non- type declarations, while looking up a name in a nested-name-specifier (3.4.3) ignores function, variable, and enumerator declarations. As another example, looking up a name in a using-declaration (7.3.3) includes the declaration of a class or enumeration that would ordinarily be hidden by another declaration of that name in the same scope. — end note ] If the resulting declaration set is not empty, the subobject set contains C itself, and calculation is complete.

5) Otherwise (i.e., C does not contain a declaration of f or the resulting declaration set is empty), S(f, C) is initially empty. If C has base classes, calculate the lookup set for f in each direct base class subobject Bi , and merge each such lookup set S(f, Bi ) in turn into S(f, C).

5

Your declaration of A::f(int a) hides all signatures B::f unless they are exposed to the derived class. There are 2 good options for exposing the "hidden" methods.

Option 1

class A:public B{
public:
    using B::f;
    virtual void f(int a){}
};

Option 2

class A:public B{
public:
    virtual void f(int a){}
    virtual void f(){ B::f(); }
};
0

1) You must use pointers. 2) If you want to get A::f(), you must use A* type variable, but class instance can be of type B* or A*.

    #include <iostream>
    using namespace std;
    class A {
    public:
        virtual void f(int a) {cout << a << " A::f(int)" << endl; }
        virtual void f(){cout << 5 << " A::f()" << endl;}
    };
    class B:public A {
    public:
        virtual void f(int a) {cout << a+1 << " B::f(int)" << endl; }
    };
    int main() {
        A *a;
        a = new B();
        a->f(1);
        a->f();
        delete a;
        a = new A();
        a->f(1);
        a->f();
        delete a;
        return 0;
    }

Output:

    2 B::f(int)
    5 A::f()
    1 A::f(int)
    5 A::f()

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