int &z = 12;
int y; int &r = y;
Why is the first code wrong? What is the "meaning" of the error in the title?
C++03 3.10/1 says: "Every expression is either an lvalue or an rvalue." It's important to remember that lvalueness versus rvalueness is a property of expressions, not of objects.
Lvalues name objects that persist beyond a single expression. For example, obj , *ptr , ptr[index] , and ++x are all lvalues.
Rvalues are temporaries that evaporate at the end of the full-expression in which they live ("at the semicolon"). For example, 1729 , x + y , std::string("meow") , and x++ are all rvalues.
The address-of operator requires that its "operand shall be an lvalue". if we could take the address of one expression, the expression is an lvalue, otherwise it's an rvalue.
On the right hand side, a temporary object of type
Why a temporary gets created? Because a reference has to refer to an object in the memory, and for an object to exist, it has to be created first. Since the object is unnamed, it is a temporary object. It has no name. From this explanation, it became pretty much clear why the second case is fine.
A temporary object can be bound to const reference, which means, you can do this:
C++11 and Rvalue Reference:
For the sake of the completeness, I would like to add that C++11 has introduced rvalue-reference, which can bind to temporary object. So in C++11, you can write this:
Note that there is
Since C++11 has introduced rvalue-reference,
References are "hidden pointers" (non-null) to things which can change (lvalues). You cannot define them to a constant. It should be a "variable" thing.
I am thinking of
as almost equivalent of
Non-const and const reference binding follow different rules
These are the rules of the C++ language:
You have to understand that these are C++ rules. They just are.
It is easy to invent a different language, say C++', with slightly different rules. In C++', it would be permitted to create a non-const reference with a rvalue. There is nothing inconsistent or impossible here.
But it would allow some risky code where the programmer might not get what he intended, and C++ designers rightly decided to avoid that risk.