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This question already has an answer here:

The "Effective C++" Item 3 says "Use const whenever possible", and it gives an example like:

const Rational operator*(const Rational& lhs, 
                            const Rational& rhs);

to prevent clients from being able to commit atrocities like this:

Rational a, b, c;
(a * b) = c;   // invoke operator= on the result of a*b!

But isn't the non-reference return value of functions allready a rvalue? So why bother doing this?

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marked as duplicate by TemplateRex, Suma, flavian, jogojapan, Praetorian Jun 1 '13 at 4:08

This question has been asked before and already has an answer. If those answers do not fully address your question, please ask a new question.

Well, without the const, that assignment will compile... – Oliver Charlesworth May 30 '13 at 11:29
Since a * b returns a const Rational you cannot do = c on it. But I disagree on returning const values from operators. – rwols May 30 '13 at 11:32
@OliCharlesworth Why, the non-reference return value is definitely a rvalue, which can NOT used as a left operand in = expressions – zoujyjs May 30 '13 at 11:47
@zoujyjs you can invoke member functions on rvalues. – Koushik Shetty May 30 '13 at 11:48
Am I just overinterpreting or did you chose the title's grammar as a stylistic device to emphasize the question? – Christian Rau May 30 '13 at 11:55
up vote 50 down vote accepted

The point is that for class types (but not for builtin types), a = b is just a shorthand to a.operator=(b), where operator= is a member function. And member functions can be called on rvalues such (a * b) created by Rational::operator*. To enforce similar semantics as for builtin rvalues ("do as the ints do") some authors (Meyers including) recommended in C++98 to return by const-rvalue for classes with such operators.

However, in C++11 returning by const-rvalue is a bad idea as it will inhibit move semantics because const rvalues cannot bind to T&&.

In his notes An overview of the new C++ (C++11), Scott Meyers gives precisely the same example from his old book, and concludes that it is now considered poor design to add the const return value. The recommended signature is now

Rational operator*(const Rational& lhs, const Rational& rhs);

UPDATE: As implied by @JohannesSchaub-litb in the comments, in C++11 you can also use a reference qualifier on the assignment operator so that it will only accept lvalues as its left argument (i.e. the *this pointer, which is why this feature is also known as "rvalue references for *this"). You'll need g++ >= 4.8.1 (just released) or Clang >= 2.9 to make use of it.

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@Barmaley.exe: because move semantics require a non-const object (how can you move -- ie. modify -- this object otherwise?). – syam May 30 '13 at 11:43
@Barmaley.exe: of course mutable would work but this defeats const-correctness: you'd have to make mutable pretty much every member of a movable class and then constness would have no meaning at all any more. – syam May 30 '13 at 11:46
@zoujyjs how user-defined assignment operators behave is up to their implementation. The point is that in general they should behave as similar as possible as they do for builtins. But because for class types they can also be called on rvalues, it used to be recommended to make rvalues const to inhibit such assignments. – TemplateRex May 30 '13 at 11:59
@Barmaley.exe: Well for once I don't agree at all with Andy (and his answer you linked to). You can bend the language into doing all sort of things, but bending the semantics is plain evil. Moving means modifying the visible state of both objects (moved-from/to), const means you can't modify the visible state, that's simply incompatible semantics-wise. Just because you can shoot yourself in the foot doesn't mean you should. – syam May 30 '13 at 12:11
The proper way to forbid that assignment is Rational &operator=(const Rational& other) &; – Johannes Schaub - litb May 30 '13 at 12:47

The const modifier on the return value is not necessary and can hinder move semantics. The preferred way of preventing assignment to rvalues in C++11 is to use "ref-qualifiers."

struct Rational
  Rational & operator=( Rational other ) &; // can only be called on lvalues

Rational operator*( Rational const & lhs, Rational const & rhs );

Rational a, b, c;

(a * b) = c; // error
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Perhaps this is going to cost me rep points, but I disagree. Don't modify the expected return types of overloaded operators as it will annoy users of your class. i.e. use

Rational operator*(const Rational& lhs, const Rational& rhs);

(Of course, consting the parameters is good practice, and having constant reference parameters is even better as it means the compiler will not take deep copies. But don't have a constant reference return value in this case though as you'll get a dangling reference which is catastrophic. But do note that sometimes, taking a reference is slower than a pass by value. I think that doubles and ints come into that category on many platforms.)

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A reference return type for operator* would be somewhat odd... – Oliver Charlesworth May 30 '13 at 11:34
Maybe you can explain why it's better for the return value to be non-const? Otherwise, this answer isn't worth much. How will this "annoy users of your class"? – interjay May 30 '13 at 11:34
You might want to write a = (b * c).some_method_that_is_faster_on_non_const_self(). But I admit I've never come across that situation. – Fred Foo May 30 '13 at 11:34
Oli: I've edited my answer now and made it clear that I don't mean having a return reference! – Bathsheba May 30 '13 at 11:35
The question is about having a const value return type, not a const reference return type. So this answer doesn't seem relevant. – interjay May 30 '13 at 11:36

Because you might be intended to write (a * b) == c instead i.e.

if ((a * b) = (c + d)) // executes if c+d is true

But you wanted to

if ((a * b) == (c + d)) // executes if they're equal
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This is something that compiler warnings should diagnose, disabling move semantics to avoid this problem is a bad idea. – Jonathan Wakely May 30 '13 at 12:43

I guess what you would like to do according to your question is to declare the corresponding operator= private such that it is not accessible anymore.

hence you would like to overload the signature that matches (a*b) = c. I agree that the left part is an expression and therefore an rvalue would be a better match. however you are ignoring the fact that this is the return value of the function if you overload the function to return an rvalue it the compiler will complain about an invalid overloading as overloading rules don't consider return values.

As stated here the operator overload for assignment is always an inside class definition. if there would be a non-member signature like void operator=(foo assignee, const foo& assigner); the overload resolution could match the first part as an rvalue (then you could delete it or declare it private).

So you can choose from two worlds:

  • live with the fact that users can write stupid stuff like (a*b) = c which is not wrong but stores the value of c in an unaccessible temporary
  • use the signature const foo operator*(const foo& lhs, const foo& rhs) which dissallows the (a*b) = c and sacrifice move semantics


#include <utility>

class foo {
    foo() = default;
    foo(const foo& f) = default;
    foo operator*(const foo& rhs) const {
        foo tmp;
        return std::move(tmp);
    foo operator=(const foo& op) const {
        return op;
    // doesn't compile because overloading doesn't consider return values.
    // conflicts with foo operator=(const foo& op) const;
    foo && operator=(const foo& op) const; 

int main ( int argc, char **argv ) {
    foo t2,t1;
    foo t3 = t2*t1;
    foo t4;
    (t2 * t1) = t4;
    return 0;
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