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12.6.1 - Explicit initialization

struct complex {
  complex();
  complex(double);
  complex(double,double);
};

complex sqrt(complex,complex);

complex g = { 1, 2 };  // construct complex(1, 2) 
                       // using complex(double, double) 
                       // and *copy/move* it into g

8.5 Initializers

14 - The initialization that occurs in the form

T x = a;

as well as in argument passing, function return, throwing an exception (15.1), handling an exception (15.3), and aggregate member initialization (8.5.1) is called copy-initialization. [Note: Copy-initialization may invoke a move (12.8). — end note ]

15 - The initialization that occurs in the forms

T x(a);

T x{a};

as well as in new expressions (5.3.4), static_cast expressions (5.2.9), functional notation type conversions (5.2.3), and base and member initializers (12.6.2) is called direct-initialization.

8.5.4 List-initialization [dcl.init.list]

1 - List-initialization is initialization of an object or reference from a braced-init-list. Such an initializer is called an initializer list, and the comma-separated initializer-clauses of the list are called the elements of the initializer list. An initializer list may be empty. List-initialization can occur in direct-initialization or copy-initialization contexts; list-initialization in a direct-initialization context is called direct-list-initialization and list-initialization in a copy-initialization context is called copy-list-initialization.

The problem with atomics

29.6.5 Requirements for operations on atomic types [atomics.types.operations.req]

#define ATOMIC_VAR_INIT(value) see below

The macro expands to a token sequence suitable for constant initialization of an atomic variable of static storage duration of a type that is initialization-compatible with value. [Note: This operation may need to initialize locks. — end note ] Concurrent access to the variable being initialized, even via an atomic operation, constitutes a data race. [ Example:

atomic<int> v = ATOMIC_VAR_INIT(5);

According to previous sections it seems there shouldn't be assignment initialization without a copy-constructor involved, even if it's elided according to §12.8.31 and §12.8.32, but atomics are defined as:

29.5 Atomic types [atomics.types.generic]

atomic() noexcept = default;
constexpr atomic(T) noexcept;
atomic(const atomic&) = delete;
atomic& operator=(const atomic&) = delete;
atomic& operator=(const atomic&) volatile = delete;
T operator=(T) volatile noexcept;
T operator=(T) noexcept;

There's no copy-constructor!

Frequently, ATOMIC_VAR_INIT expands to a brace expression for brace initialization, but atomic<int> v = {5} is still an assignment initialization and would imply copy construction after direct construction of a temporary.

I've looked over the "constant initialization" section to see whether there's a loophole allowing this without a copy (because of "The macro expands to a token sequence suitable for constant initialization of an atomic variable of static storage duration of a type that is initialization-compatible with value") but I'm already giving up.

Related discussions:

http://thread.gmane.org/gmane.comp.lib.qt.devel/8298

http://llvm.org/bugs/show_bug.cgi?id=14486

EDIT

An answer quoting the relevant standard sections while building a deduction process would be ideal.

CONCLUSION

So, after the nice answer by Nicol Bolas, the funny conclusion is that complex g = { 1, 2 } is a copy (it is copy-initialization context) which don't copy (copy-list-initialization resolves like direct-list-initialization) for which the standard suggests there's a copy operation (12.6.1: ...and copy/move it into g).

FIX

Pull request: https://github.com/cplusplus/draft/pull/37

share|improve this question
    
That's a lot of standards quotes. What is your actual question? –  sehe Dec 3 '12 at 23:53
    
"Is this a defect in the c++11 standard?" then see "The problem with atomics". It looks like a conflict referring to atomic<int> v = ATOMIC_VAR_INIT(5) while copy construction is deleted. –  pepper_chico Dec 3 '12 at 23:56
6  
I think the question could be simplified as "Does copy-list-initialization imply copy-initialization?", with a short example. –  Kerrek SB Dec 4 '12 at 0:00
    
@KerrekSB I have my ways, I'm already mentioning that quotes in the answers being given. –  pepper_chico Dec 4 '12 at 0:11
2  
I think this question might be relevant. –  Xeo Dec 4 '12 at 0:25

2 Answers 2

up vote 9 down vote accepted
complex g = { 1, 2 };  // construct complex(1, 2) 
                       // using complex(double, double) 
                       // and *copy/move* it into g

This is untrue. And I'm not saying that the copy/move will be elided; I mean that there will be no copying or moving.

You quoted 8.5 p14, which defines T x = a; as copy-initialization. This is true. But it then goes on to define how initialization actually works:

From 8.5, p16:

The semantics of initializers are as follows. The destination type is the type of the object or reference being initialized and the source type is the type of the initializer expression. If the initializer is not a single (possibly parenthesized) expression, the source type is not defined.

  • If the initializer is a (non-parenthesized) braced-init-list, the object or reference is list-initialized (8.5.4).

That right there means that copy-initialization rules do not apply to a braced-init-list. They use a separate set of rules, as covered in 8.5.4.

You quoted 8.5.4, which defines T x = {...}; as copy-list-initialization. Where your reasoning goes wrong is that you never looked up what copy-list-initialization actually does. There is no copying; that's just what it's called.

copy-list-initialization is a subset of list-initialization. Therefore, it follows all of the rules laid down by 8.5.4, p3. I'm not going to quote them here, because they're several pages long. I'll simply explain how the rules apply to complex g = {1, 2};, in order:

  1. The initializer list has elements, so this rule doesn't count.
  2. complex is not an aggregate, so this rule doesn't count.
  3. complex is not a specialization of initializer_list, so this rule doesn't count.
  4. Applicable constructors are considered via overload resolution, in accord with the rules of 13.3 and 13.3.1.7. This finds the constructor that takes two doubles.

Therefore, no temporary will be created and copied/moved in.

The only difference between copy-list-initialization and direct-list-initialization is stated in 13.3.1.7, p1:

[...] In copy-list-initialization, if an explicit constructor is chosen, the initialization is ill-formed.

That is the only difference between complex g{1, 2} and complex g = {1, 2}. They are both examples of list-initialization, and they work in a uniform way except for the use of explicit constructors.

share|improve this answer
    
It indeed looks all right even if it's a bit implicit copy-list-initialization should follow just as direct-list-initialization. Also, that "complex" code sample in the standard just adds up to confuse (there's indeed a defect there). But I think they are less relevant than your assumption, thanks. –  pepper_chico Dec 4 '12 at 1:29
    
@Chico: That sounds more like an editorial issue than a defect, since it is only in non-normative code. So file a GitHub bug on it. –  Nicol Bolas Dec 4 '12 at 1:44
    
Just to complement. According to this process atomic<int> v = {5} resolves to the single constructor left, the constexpr constructor. This is indeed a very simple expression that's valid by very tortuous means and subtle rules. If you take braces out, it's not valid anymore as @kerrek-sb also points; if it's not a constant/literal like 5, it's not valid too. –  pepper_chico Dec 4 '12 at 4:10
1  
@Chico: That line doesn't work because it's a "constant/literal". It works because the class in question has a matching constructor which is not explicit. The fact that it's a constexpr constructor is irrelevant. You could pass an integer variable in the braced-init-list and it would still work, because constexpr constructors do not have to be called with constant expressions. –  Nicol Bolas Dec 4 '12 at 4:33
1  
reminds me of stackoverflow.com/questions/7935639/… :-) –  Johannes Schaub - litb Dec 4 '12 at 21:29

The constructor-from-T is not explicit, and copy-list-initialization is not the same as copy-initialization. Both cause "constructors to be considered", but copy-initialization always "considers" the copy con­struc­tor, while list-initialization considers constructors with the list elements filled in (plus some details). To wit:

struct Foo
{
    Foo(int) {}
    Foo(Foo const &) = delete;
};

int main()
{
    Foo f = { 1 };  // Fine
}

(This would fail if the constructor was explicit. Also, Foo x = 1; will of course fail on account of the deleted copy constructor.)

Perhaps an even more enlightening use case:

Foo make() { return { 2 }; }

void take(Foo const &);
take(make());

Everything necessary for this is in 8.5.4/3 and in 13.3.1.7/1.

share|improve this answer
    
I'll look in that section so. The point is, I'm not asserting copy-list-initialization is the same as copy-initialization, that's why I've quoted the List-initialization section. The point is, where in the standard, there's a point that overrules quoted 8.5.14 and 8.5.15 for list-initialization. –  pepper_chico Dec 4 '12 at 0:09
2  
@Chico: The difference is that Foo f = 1; causes a user-defined conversion as in Foo f = Foo(1); and will thus match the copy constructor. By contrast, list initialization will match the other constructor, as in Foo f(1);. See the update. –  Kerrek SB Dec 4 '12 at 0:22
    
I really would like to see your process of deduction plus quoting the relevant standard sections (not linking). –  pepper_chico Dec 4 '12 at 0:32
    
+1 for that take-make use case –  pepper_chico Dec 4 '12 at 14:38

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