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The original question is related to overloading operator= and I like to share my findings as it was nontrivial for me to find them. I cannot imagine reasonable example to use (a=b) as lvalue. With the help of IRC and google I've found the next article: http://msdn.microsoft.com/en-us/magazine/cc301415.aspx

it provides two examples.

  (a=b)=c

  f(T& );
  f(a=b)

but both a bit not good, and I believe that it is bad practice. The second one give me the same feeling. Could you provide more good examples why it should be non constant?

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6 Answers 6

up vote 10 down vote accepted

One good reason is that one of the requirements in the standard for a class X to be useable in the standard containers is that the expression a = b must have type X& (where a is an lvalue of type X and b is an rvalue of type X).

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Good catch, mate :) –  Johannes Schaub - litb Jun 3 '10 at 20:15
    
Thanks! Nice shot. I'll vote this up. (But probably this is related to bad practice in STL. Can you give a pure C++ example?) –  outmind Jun 3 '10 at 20:19
2  
But why does the container needs an X& as return? –  KennyTM Jun 3 '10 at 20:20
1  
I haven't ever thought of a specific container example which would usefully benefit from a = b being of type X& but it's possible that there is an implementation that does rely on it and you'd probably be in for a reasonably obscure error message if you had a class that broke this contract. –  Charles Bailey Jun 3 '10 at 20:24
    
I'd be interested in any decent (or even half-decent) answers to KennyTM's question. About the best rationale I could find on the web was here: keyongtech.com/4706456-why-the-copy-assignment-operator/2#18, but even that is pretty weak (the code that requires Assignable to return a non-const ref could be trivially changed to "myValue = newValue; return myValue;" if Assignable were instead defined to return a const ref). –  Michael Burr Jun 3 '10 at 22:48

Most probably because this is how the native types of the language work. e.g.:

int x = 0, y = 1, z = 2;
(x = y) = z;

AFAIK, Dr. Stroustrup said that it is a good thing to have consistency in the language. i.e. user-defined types should behave just like native types.

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Thanks! Good example. C backward compatibility and consistence. –  outmind Jun 3 '10 at 20:23
2  
Except that the C++ behavior is in fact different than C. From the C99 standard (6.5.16/3 "Assignment operators"): "An assignment expression has the value of the left operand after the assignment, but is not an lvalue." It would be interesting to know what Stroustrup's thinking was on why this change was necessary. I can't readily think of a good, desirable use-case (but that just means someone needs to tell me or remind me what it is). –  Michael Burr Jun 3 '10 at 22:02
1  
@Peter: No on both accounts. Parentheses do not introduce a sequence point and the behavior of (x = y) = z is indeed undefined. Moreover, in (x+y)*z there's no guarantees of what happens first and what happens next. Parentheses only alter the mathematical meaning of the expression, but introduce no temporal restrictions, no sequence points. The compiler is free to evaluate it in any order it pleases, as long as the result is correct. It can do it as x*z + y*z. Or as x + (y*z) + x*(z-1). –  AndreyT Jun 3 '10 at 23:54
1  
@AndreyT, notice that in C++0x, (x = y) = z; is well-defined. value computation of the left operand of an assignment expression happens before the assignment, and the assignment happens before value computation of the result of an assignment. Thus assignment of x = y is done, then it's lvalue result is computed, and then result = z is done. These are well ordered in C++0x. –  Johannes Schaub - litb Jun 4 '10 at 21:39
1  
@AndreyT they solved it like i described above. Sequenced-before is a relation on two evaluations of expressions, and an evaluation can contain value computation (lvalue/rvalue computation) and initiation of side effects. And value computation of both operands of "op=" is sequenced-before the actual assignment, which in turn is sequenced before the value computation of its result. Thus, in (x = y) = z both assignments are sequenced transitively and thus do not cause undefined behavior. Notice that C++0x has no sequence points anymore, but instead sequenced-before relations. –  Johannes Schaub - litb Jun 4 '10 at 23:25

I've spent some time and here is my example:

class A
{
public:
    const A& operator= (const A& a) {return *this;}
};

int main(int argc, char* argv[])
{
    A a1;
    A& a2 = a1;
    A& a3 = (a2 = a1);
}

and the compiler output: : error C2440: 'initializing' : cannot convert from 'const A' to 'A &'

I've checked it on MS VS 2010, but is it true on other platforms? And if this example is sufficient condition for = to be non const?

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1  
Also compile error on g++. –  KennyTM Jun 3 '10 at 20:16
    
Thanks you! What is your ideas about sufficiency? –  outmind Jun 3 '10 at 20:17

Andrew Koenig wrote a post about this a long time ago. A lot of it comes down to doing what people expect under slight unusual circumstances. The example he gives is that in C, return x=y; always means the same thing as x=y; return x;. In C++, if you return essentially anything other than a reference (including a const reference), the two can mean different things.

Edit: Sorry, I linked to the wrong post. Try this one. The problem arises from the fact that a T const & can bind to a temporary instead of the "real" object, so what happened with the code above was that it created a temporary, copied the object into it, bound the reference to it, destroyed the temporary, then returned the (now dangling) reference.

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1  
How? How can they mean different things if you return something other than reference? –  AndreyT Jun 3 '10 at 22:31

Why should it be const? If you're assigning to it, obviously it's modifiable. That would be artifically limiting.

As for use cases, why not:

T &local = t1 = t2 = t3;

In this example, local isn't const.

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What types of t1,t2,t3? T* or T or T&? –  outmind Jun 3 '10 at 20:21
1  
Why can you assign to a pointer? –  KennyTM Jun 3 '10 at 20:21
    
@outmind: In this case, t3 is a type that is convertible and/or assignable to t2, t2 is a type that is convertible and/or assignable to t1, and t1 is a type that is convertible and/or assignable to T*. –  Bill Jun 3 '10 at 20:40
    
@Bill: If we are talking about T * t1, then local = t1 doesn't require operator=(const & T) to return reference nonconst. –  outmind Jun 3 '10 at 20:52
    
Dumb oversight, fixed. t1-t3 are T&. –  zildjohn01 Jun 3 '10 at 22:09

If we consider three auto_ptr a, b and c, the operator = has to return a non-const reference so that you can do multiple assigns since assigning the pointer to another modifies the first.

so if we have a = b = c, the following happens: c is assigned to b (c is modified to point to null), the operator returns a reference to b the reference returned by (b = c) is assigned to a, it is thus modified to point to null, which is only possible if the reference is non-const.

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