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Was the unary + operator only included for symmetry with the unary - operator, or does it find some practical use in C++ code?

Searching here, I came across What is the purpose of the unary '+' operator in C?, but the only useful scenarios there involve preprocessor macros. Those are good to know, but they seem to be some less common situations, and involve macros. Are there any use cases involving more common C++ code?

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Mathematically? No. But it might find a use in operator overloading with classes. – ApproachingDarknessFish Jan 16 '13 at 19:05
@ValekHalfHeart: Yes, but any overload that does anything but return *this; will be seen as an abuse. – rodrigo Jan 16 '13 at 19:09
@rodrigo But could still provide a side effect on this, doesn't it? If this is good or useful DSL design is another question. – πάντα ῥεῖ Jan 16 '13 at 19:12
@ArneMertz: As nice as Boost.Spirit is, it is certainly a language abuse. Not that it takes any merit of it, but operator overloading was not designed to do this kind of things, as it is evident when you realize that you cannot change the operator precedence and your fancy new meanings for old operators are a bit loose (cout << a & b;, anyone?). – rodrigo Jan 16 '13 at 19:18
@ApproachingDarknessFish: it might find a use in operator overloading with classes. will you explain it by giving an example. – Destructor Oct 29 '15 at 14:57
up vote 31 down vote accepted
char ch = 'a';
std::cout << ch << '\n';
std::cout << +ch << '\n';

The first insertion writes the character a to cout. The second insertion writes the numeric value of ch to cout. But that's a bit obscure; it relies on the compiler applying integral promotions for the + operator.

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Oohh... that's kinky – Nik Bougalis Jan 16 '13 at 19:09
Is the numeric value its ASCII equivalent? – 0x499602D2 Jan 16 '13 at 19:26
@David - with a compiler that uses ASCII, yes. For other encodings (rare), no. – Pete Becker Jan 16 '13 at 19:32
Doesn't seem to work for me -- might these be the rare encodings? – 0x499602D2 Jan 16 '13 at 19:34
@David: use (a - '\0'), then it will work – Arne Mertz Jan 16 '13 at 19:43

Symmetry with unary - isn't entirely useless; it can be used for emphasis:

const int foo = -1;
const int bar = +1;

And an overloaded unary + can be used to denote an operation that yields the same logical value as its operand, while performing some non-trivial computation. (I've seen this done for type conversions in Ada, which permits unary +, but not conversions, to be overloaded.) I don't have a good C++ example to hand, and one could argue that it would be poor style. (Then again, I've seen plenty of rants about overloading <<.)

As for why C++ has it, it's probably largely for consistency with C, which added it with the 1989 ANSI standard. The C Rationale just says:

Unary plus was adopted by the C89 Committee from several implementations, for symmetry with unary minus.

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+1 One Lovely Quote. – sehe Jan 16 '13 at 21:56

If you explicitly stay clear of any number value semantics for a class, any operator overloading is clear not to "do as the ints do". In that case, the unary plus may get any meaning, doing much more than just returning *this

Prominent example: Boost.Spirit's unary plus for the embedded EBNF's Kleene Plus generates a parser rule that lets it's argument (a parser rule as well) match one or more times.

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I wish we could overload @, $, and # too. – Mooing Duck Jan 16 '13 at 21:58
@MooingDuck And while you're at it, can we have the ability to make our own operators, out of any combination of +-*/%=!<>~^|&*.[]()@#$? – Blacklight Shining Feb 27 '13 at 21:12
Most of those would make parsing ambiguous. If compiler sees a+-b, is that the builtins or a user overload? – Mooing Duck Feb 27 '13 at 21:40
@MooingDuck It's an overload if such an overload exists; else it's a + (-b). :D – Blacklight Shining Feb 27 '13 at 22:42

The unary + operator turns a lvalue into an rvalue:

struct A {
  static const int value = 1;

// ...

int x = std::min(0, A::value);

Oh noes! This code won't link, because someone forgot to define (as well as declare) A::value. std::min takes its arguments by reference so A::value must have an address so a reference can bind to it (technically, the one definition rule says it must be defined exactly once in the program.)

Nevermind, unary plus to the rescue:

int x = std::min(0, +A::value);

The unary plus creates a temporary with the same value, and the reference binds to the temporary, so we can work around the missing definition.

This isn't something you need often, but it is a practical use of the unary plus operator.

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Unary + applies integral promotions. @PeteBecker's answer shows one way that can be useful.

For another, note that an unscoped enumeration type gets promoted to an integer type which can represent all values in the enum. So in C++03, even without C++11's std::underlying_type<T>, you could do:

enum MyBitMask {
    Flag1 = 0x1,
    Flag2 = 0x2,
    Flag3 = 0x4,
    Flag4 = 0x8000000

inline MyBitMask operator&(MyBitMask x, MyBitMask y) {
    return static_cast<MyBitMask>( +x & +y );

inline MyBitMask operator|(MyBitMask x, MyBitMask y) {
    return static_cast<MyBitMask>( +x | +y );
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A bit late, but here's a very twisted use that I stumbled across. Apparently the + operator can be useful (if perhaps not strictly necessary) when designing safeguards around the possibility of encountering empty preprocessor tokens. See this post for a more in-depth discussion.

It's practical, but by no means pleasant.

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