1

Consider a class defined as below:

struct A
{
    void f();
    void f() const;
    void f() &;
    void f() const &;
    void f() &&;
    void f() const &&;
};

What are the differences between:

1) void A::f(); and void A::f() &; (Please notice this!)

2) void A::f() const; and void A::f() const &;

3) void A::f() &&; and void A::f() const &&;

2
  • 1
    stackoverflow.com/questions/8610571/… . And you cannot have both ref-qualified functions and normal functions. It's either one or another.
    – lapk
    Sep 13, 2013 at 2:20
  • Petr's comment should be the best answer.
    – xmllmx
    Sep 13, 2013 at 2:36

2 Answers 2

2

You can transform these to

void f(A&);
void f(const A&);

void f(A&);
void f(const A&);
void f(A&&) &&;
void f(const A&&);

The first is special - it is a A&, but still accepts rvalues, unlike other non-const lvalue references. In all other regards, it is the same as any other function with a A& parameter.

There is no difference in overload resolution between the second (const) and the fourth (const&), except if they respectively compete against a (&&). I don't think that can happen for normal functions, but only for conversion functions, because the Standard forbids this case (in general, if there is any function in the current scope with a ref qualifier, all functions must)

void f();
void f() &&;

But with conversion functions, you can still have an overload resolution set with both operator int() and operator long()&&. In that case, even if the object on which they are invoked is R() (an rvalue), if you need to convert to int then the first conversion function would be used.

1
  1. f() is a normal function for f() const, this must point to a modifiable lval
  2. f() const is a const function (cannot change this) f() const &is the same but guarantees this is an lval as well
  3. f()&& this must be a temporary value for f() const && this must be a temporary value that you cannot modify

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