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§ 3.10.1.5 from the standard defines prvalue expressions as:

— A prvalue (“pure” rvalue) is an rvalue that is not an xvalue. [ Example: The result of calling a function whose return type is not a reference is a prvalue. The value of a literal such as 12, 7.3e5, or true is also a prvalue. — end example ]

Thus the function foo() is a prvalue expression:

class Foo {}; 
Foo foo() { return Foo{}; }

To initialize a lvalue reference to a non-volatile const type / rvalue reference the initializer expression has to be ( § 5.2.1.1 ) :

[...] an xvalue (but not a bit-field), class prvalue, array prvalue or function lvalue and “cv1 T1” is reference-compatible with “cv2 T2”, or [...]

Thus,

Foo &&rrFoo_ = foo(); 

is valid code where rrFoo_ binds to a temporary object extending the lifetime of the object (§12.2):

Temporaries of class type are created in various contexts: binding a reference to a prvalue (8.5.3), returning a prvalue (6.6.3), a conversion that creates a prvalue (4.1, 5.2.9, 5.2.11, 5.4), throwing an exception (15.1), and in some initializations (8.5).

As stated above and neglecting RVO, the following initialization of an object of type Foo will copy move construct a temporary from default constructed object. The temporary object which will then be used to copy move construct the final object named obj_foo :

Foo obj_foo{ foo() }; 

So in both cases we either steal from or even extend the lifetime of the temporary object, which would otherwise be destroyed.

§3.10.1.2 defines xvalues as:

An xvalue (an “eXpiring” value) also refers to an object, usually near the end of its lifetime (so that its resources may be moved, for example). [...]

I cannot think of any case where a temporary object isn't created. So my question is, why are function expressions like foo() are considered to be prvalue expression even thought they have at least similar properties as xvalues ?

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  • You can write user-defined lvalue and xvalue expressions, too: int & f();, int && g();.
    – Kerrek SB
    Feb 4 '17 at 17:42
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Given int f1() and int && f2(), it's intended that decltype(f1()) is int, and decltype(f2()) is int &&. The way this is made to work is by specifying that f1() is a prvalue and f2() is an xvalue. decltype then looks at whether the given expression is a prvalue, xvalue or lvalue. If f1() and f2() were both xvalues, that same distinction would still need to be made some other way.

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