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I was just browsing through the draft of the C++11 standard and found the following puzzling statement (§13.6/8):

For every type T there exist candidate operator functions of the form

T* operator+(T*);

How should this "unary +" operator on pointer be understood? Is this just a no-op in the normal case, which can nevertheless be overloaded? Or is there some deeper point I am missing here?

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3 Answers 3

up vote 6 down vote accepted

The answer to your question is just a page above the quote you cited — §13.6/1:

The candidate operator functions that represent the built-in operators defined in Clause 5 are specified in this subclause. These candidate functions participate in the operator overload resolution process as described in and are used for no other purpose. [ Note: Because built-in operators take only operands with non-class type, and operator overload resolution occurs only when an operand expression originally has class or enumeration type, operator overload resolution can resolve to a built-in operator only when an operand has a class type that has a user-defined conversion to a non-class type appropriate for the operator, or when an operand has an enumeration type that can be converted to a type appropriate for the operator. Also note that some of the candidate operator functions given in this subclause are more permissive than the built-in operators themselves. As described in, after a built-in operator is selected by overload resolution the expression is subject to the requirements for the built-in operator given in Clause 5, and therefore to any additional semantic constraints given there. If there is a user-written candidate with the same name and parameter types as a built-in candidate operator function, the built-in operator function is hidden and is not included in the set of candidate functions. —end note ]

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The + on pointers is a noop except for turning things to rvalues. It sometimes is handy if you want to decay arrays or functions

int a[] = { 1, 2, 3 };
auto &&x = +a;

Now x is an int*&& and not an int(&)[3]. If you want to pass x or +a to templates, this difference might become important. a + 0 is not always equivalent, consider

struct forward_decl;
extern forward_decl a[];
auto &&x = +a; // well-formed
auto &&y = a + 0; // ill-formed

The last line is ill-formed, because adding anything to a pointer requires the pointer's pointed-to class type to be completely defined (because it advances by sizeof(forward_decl) * N bytes).

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isn't this what std::move() and std::forward() is meant to do? So if I understand this correctly +a and std::move(a) would do the same? – LiKao Feb 13 '12 at 22:18
@LiKao not at all. move preserves the type, but just changes the value category. So move(a) would yield an rvalue of type int[3], not an rvalue of type int*. Now applying move to a function doesn't do anything at all (casting to FunctionType&& yields an lvalue) and isn't particularly meaningful I think. – ᐅ Johannes Schaub - litb ᐊ Feb 13 '12 at 22:22
@LiKao: No, std::move preserves the array, while unary + decays it (and produces an rvalue pointer). – Xeo Feb 13 '12 at 22:25
The most important difference here is that move preserves identity: The location that the xvalue result references is still the same as what was put as argument to move. However the builtin + throws away identity and only preserves the value. – ᐅ Johannes Schaub - litb ᐊ Feb 13 '12 at 22:27

Well, you could overload it do do whatever you want, but it's just there for symmetry with the unary - operator. As you mention, it's just a no-op most of the time.

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could you? operator must have an argument of class or enumerated type? – Lol4t0 Feb 13 '12 at 19:40

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