6

My C++ colleagues and I ran into a curious construct:

struct A { int i; };
void foo(A const& a);

int main() {
  foo(A() = A{2}); // Legal
}

The A() = A{2} expression completely befuddled us as it appears to be assigning A{2} to a temporary, default-constructed object. But see it in compiler explorer (https://gcc.godbolt.org/z/2LsfSk). It appears to be a legal statement (supported by GCC 9 and Clang 9), as are the following statements:

struct A { int i; };

int main() {
  A() = A{2};
  auto a = A() = A{3};
}

So it appears, then, that in some contexts A() is an lvalue. Or is something else going on here? Would appreciate some explanation and, preferably, a reference to the C++17 standard.


Update: @Brian found that this is a duplicate of assigning to rvalue: why does this compile?. But would really appreciate if someone could find the appropriate reference in the C++ standard.

6
  • @Brian Is it a duplicate? int() = 2; is also assignment to an rvalue, but it is not allowed by the compiler. So what makes user-defined types different? Dec 20, 2019 at 19:55
  • 1
    The duplicate explains this. If the LHS is a class, then the assignment operation calls operator=. If the LHS is a non-class, then the built-in operator is used, which requires an lvalue.
    – Brian Bi
    Dec 20, 2019 at 19:58
  • @Brian, Fine but the duplicate doesn't specify the section of the language standard that's relevant...and that's what I requested. Dec 20, 2019 at 20:00
  • All right. I reopened the question.
    – Brian Bi
    Dec 20, 2019 at 20:01
  • Related: stackoverflow.com/questions/28598468
    – M.M
    Dec 21, 2019 at 23:23

1 Answer 1

7

A{} is always an rvalue per [expr.type.conv]

1 A simple-type-specifier or typename-specifier followed by a parenthesized optional expression-list or by a braced-init-list (the initializer) constructs a value of the specified type given the initializer. If the type is a placeholder for a deduced class type, it is replaced by the return type of the function selected by overload resolution for class template deduction for the remainder of this subclause.
2 If the initializer is a parenthesized single expression, the type conversion expression is equivalent to the corresponding cast expression. Otherwise, if the type is cv void and the initializer is () or {} (after pack expansion, if any), the expression is a prvalue of the specified type that performs no initialization. Otherwise, the expression is a prvalue of the specified type whose result object is direct-initialized with the initializer. If the initializer is a parenthesized optional expression-list, the specified type shall not be an array type.

emphasis mine

The reason these works is here is nothing in the standard to stop it from working.

For built in types like int there is [expr.ass]/1

The assignment operator (=) and the compound assignment operators all group right-to-left. All require a modifiable lvalue as their left operand; their result is an lvalue referring to the left operand.

So this stops you from doing int{} = 42;. This section doesn't apply to classes, though. If we look in [class.copy.assign] there is nothing that says that an lvalue is required, but the first paragraph does state

A user-declared copy assignment operator X​::​operator= is a non-static non-template member function of class X with exactly one parameter of type X, X&, const X&, volatile X&, or const volatile X&

Which means

A{} = A{2};

is actually

A{}.operator=(A{2})

Which is legal to do on an rvalue class object since the default operator = for your class has no ref-qualifier to stop it from being called on rvalues. If you add

A& operator=(const A& a) & { i = a.i; }

to A instead of using the default assignment operator then

A{} = A{2};

would no longer compile since the operator= will only work on lvalues now.

3
  • Thanks. Close. I think I just found it--8.2.1[basic.lval], paragraph 2. Dec 20, 2019 at 20:13
  • @KyleKnoepfel Added that bit in so you have standard references for each bit. Dec 20, 2019 at 20:16
  • @KyleKnoepfel [basic.lval] only speaks about properties of Zvalues, but it doesn't say which expressions are lvalues/xvalues/prvalues. Dec 21, 2019 at 14:27

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