In http://herbsutter.com/2008/01/01/gotw-88-a-candidate-for-the-most-important-const/ it mentions "most important const" where by C++ deliberately specifies that binding a temporary object to a reference to const on the stack lengthens the lifetime of the temporary to the lifetime of the reference itself. I was wondering why c++ only allows the lifetime of the object to be lengthened when the reference is const and not when it isn't? What is the rational behind the feature and why does it have to be const?

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    I'm hoping for a quote from The Standard here, since I've never been able to quite convince myself that it does require the const. (Looking at 12.2 p4 and 5 in N3936).
    – BoBTFish
    Commented Apr 14, 2014 at 14:50
  • So that the compiler doesn't have to verify that no paths modify the temporary before the object goes out of scope.
    – Brian Cain
    Commented Apr 14, 2014 at 14:52
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    @BoBTFish: You're looking at the lifetime of temporaries bound to references. For the rules about how to bind them in the first place, see [dcl.init.ref] (8.5.3 in C++11). In particular, the final bullet of p5: "the reference shall be an lvalue reference to a non-volatile const type [or] an rvalue reference." Commented Apr 14, 2014 at 14:58
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    @MSalters, you might want to modify the object before passing it into another function. Or you might want to call a non-const method on the object and keep the return value from that, but discard the object. Neither of these are necessarily best coding style, but they aren't errors any more than modifying any temporary object is.
    – dan
    Commented Apr 14, 2014 at 15:50
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    A non-const rvalue reference will bind to a temporary and will also extend the lifetime of the temporary to the lifetime of the reference.
    – Oktalist
    Commented Apr 14, 2014 at 17:34

3 Answers 3


Here's an example:

void square(int &x)
  x = x * x;

int main()
  float f = 3.0f;


  std::cout << f << '\n';

If temporaries could bind to non-const lvalue references, the above would happily compile, but produce rather surprising results (an output of 3 instead of 9).

  • Interesting, I hadn't thought of that.
    – Neil Kirk
    Commented Apr 14, 2014 at 15:10
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    Why would it output 3?
    – David G
    Commented Apr 14, 2014 at 15:12
  • This is the usual explanation, I think. What if it were allowed in copy-style initialization, but not in parameter initialization? There are already explicit vs. implicit conversions. Commented Apr 14, 2014 at 15:12
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    @0x499602D2 Because float 3.0f would be converted to temporary int of value 3 to be passed to function. Result of the function would be lost in the temporary.
    – Neil Kirk
    Commented Apr 14, 2014 at 15:13
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    @Mankarse Not really - you'd normally expect to call square(int &&x) as square(std::move(f)) (because it wouldn't accept lvalues), which is a strong indication f shouldn't be inspected after the call. Commented Apr 15, 2014 at 5:49

Consider the following:

int& x = 5;
x = 6;

What should happen if this was allowed? By contrast, if you did

const int& x = 5;

there would be no legal way to modify x.

  • A hidden local variable with value 5 should be created. There is no technical reason not to allow it.
    – Neil Kirk
    Commented Apr 14, 2014 at 15:09
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    @NeilKirk However, that's not something you expect from int&, it would be only a burden for the compiler designers, and would not differ from int x=5.
    – yo'
    Commented Apr 14, 2014 at 15:43
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    @tohecz but that is how const ref binding is implemented with return values from normal functions. All features are "burdens" for the compiler designers, that's not a reason for it not to be a feature!
    – dan
    Commented Apr 14, 2014 at 15:52
  • Simple examples like these look pointless, but they can be useful when you have horrific template code where letting this little thing just compile would save a lot of work.
    – Neil Kirk
    Commented Apr 14, 2014 at 16:03
  • This answer isn't really consistent with C++ as a whole, since it is entirely legal to do int&& x = 5; x = 6;.
    – Mankarse
    Commented Apr 15, 2014 at 3:00

Note that const references can be bound to objects that don't even have an address normally. A const int & function parameter can take an argument formed by the literal constant expression 42. We cannot take the address of 42, so we cannot pass it to a function that takes a const int *.

const references are specially "blessed" to be able to bind to rvalues such as this.

Of course, for traditional rvalues like 2 + 2, lifetime isn't an issue. It's an issue for rvalues of class type.

If the binding of a reference is allowed to some object which, unlike 42, does not have a pervasive lifetime, that lifetime has to be extended, so that the reference remains sane throughout its scope.

It's not that the const causes a lifetime extension, it's that a non-const reference is not allowed. If that were allowed, it would also require a lifetime extension; there is no point in allowing some reference which then goes bad in some parts of its scope. That behavior undermines the concept that a reference is safer than a pointer.

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