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Why it is not possible to convert rvalues to lvalues? It is possible to do a conversion in the opposite direction though. Technically rvalues do have a memory address, isn't it?

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    Thought experiment: int x = 1; -- 1 is an rvalue here. Does the literal 1 have a memory address? Can you do &1 to obtain its address?
    – cdhowie
    Commented Jun 21, 2017 at 13:40
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    @OfT Because temporaries are allowed to bind to const references, which extends the lifetime of the temporary. That doesn't change the fact that 2 is an rvalue. My comment is meant to make you think twice about your pondering "technically, rvalues do have a memory address, right?" The answer is that not all rvalues have a memory address.
    – cdhowie
    Commented Jun 21, 2017 at 16:11
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    @OfT That's correct. The trick is that you can't take the address of something without a name (an rvalue). But by binding that temporary to a reference, you've given it a name (recall that a reference is just another name for an object) and so you're allowed to take its address.
    – cdhowie
    Commented Jun 21, 2017 at 20:34
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    @cdhowie You can't do &*"hello"?
    – curiousguy
    Commented Feb 5, 2019 at 14:28
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    As curiousguy points out, it's not whether it has a name, it's whether it has a location.
    – Ben Voigt
    Commented Jun 15, 2022 at 19:20

3 Answers 3

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You can:

int&& x = 3;

x is now an lvalue. A so called 'rvalue-reference' can bind to a temporary, but anything with a name is an lvalue, so you need to forward<>() it if you need it's rvalueness back.

Note that by binding a temporary to a rvalue-reference (or a const reference) you extend its lifetime. Technically a cast is possible, but not recommended, since temporaries have short lifetime, so you typically get a dangling reference.

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  • I don't understand what you mean with the forward<>().
    – KcFnMi
    Commented Oct 15, 2022 at 14:18
  • Can we pass x to a function, func(x); after that?
    – KcFnMi
    Commented Oct 15, 2022 at 14:19
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It is rather straightforward to write a template function unmove(), that does the opposite of std::move():

template<class T> T& unmove(T&& t) { return static_cast<T&>(t); }

Please note that, according to the standard since C++11:

a temporary bound to a reference parameter in a function call exists until the end of the full expression containing that function call: if the function returns a reference, which outlives the full expression, it becomes a dangling reference.

So it is safe to use unmove() within a single full expression, but after the expression has been fully evaluated, the temporaries go away.

My common use for unmove() is to call functions / methods, that return values through references, when I don't need those values.

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  • Does anyone know if this will still work in c++23? regarding open-std.org/jtc1/sc22/wg21/docs/papers/2022/p2266r3.html
    – sp2danny
    Commented Jul 9, 2023 at 10:14
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    @sp2danny Yes it breaks due to that addendum. The paper even lists a template from the OpenOffice temporary library o3tl, that has the same purpose and same code as unmove, except, that it is called temporary there. The solution is simple to add an explicit static_cast. Thanks for the pointer and I have already edited the answer.
    – Kai Petzke
    Commented Jul 11, 2023 at 17:43
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Correct an anwer above.

int&& x = 3;

x is 'rvalue-reference'. See https://www.tutorialspoint.com/What-is-double-address-operator-and-and-in-Cplusplus

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  • Both of you are right. "rvalue-reference" is part of the type of x, and "lvalue" is the value-category of x. There is no such value-category as "rvalue-reference".
    – Ben Voigt
    Commented Jun 15, 2022 at 19:17
  • The old answer is correct. Expression x is an lvalue of type int, while variable x has type int &&, aka "rvalue reference to int" (not an rvalue, since only expressions can be rvalues/lvalues/etc). Commented Jun 15, 2022 at 19:17

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