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# Why does the standard differentiate between direct-list-initialization and copy-list-initialization?

We know that `T v(x);` is called direct-initialization, while `T v = x;` is called copy-initialization, meaning that it will construct a temporary `T` from `x` that will get copied / moved into `v` (which is most likely elided).

For list-initialization, the standard differentiates between two forms, depending on the context. `T v{x};` is called direct-list-initialization while `T v = {x};` is called copy-list-initialization:

`§8.5.4 [dcl.init.list] p1`

[...] 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. [...]

However, there are only two more references each in the whole standard. For direct-list-initialization, it's mentioned when creating temporaries like `T{x}` (`§5.2.3/3`). For copy-list-initialization, it's for the expression in return statements like `return {x};` (`§6.6.3/2`).

Now, what about the following snippet?

``````#include <initializer_list>

struct X{
X(X const&) = delete; // no copy
X(X&&) = delete; // no move
X(std::initializer_list<int>){} // only list-init from 'int's
};

int main(){
X x = {42};
}
``````

Normally, from the `X x = expr;` pattern, we expect the code to fail to compile, because the move constructor of `X` is defined as `delete`d. However, the latest versions of Clang and GCC compile the above code just fine, and after digging a bit (and finding the above quote), that seems to be correct behaviour. The standard only ever defines the behaviour for the whole of list-initialization, and doesn't differentiate between the two forms at all except for the above mentioned points. Well, atleast as far as I can see, anyways.

So, to summarize my question again:

What is the use of splitting list-initialization into its two forms if they (apparently) do the exact same thing?

-
If you made that third constructor `explicit`, would it stop working? – Kerrek SB Nov 19 '12 at 20:04
The difference between direct-initialization and copy-initialization is defined 8.5 #16. The direct-initialization considers only constructors, whereas copy-initialization considers user-defined conversion sequences. Thus making the ctor explicit will result in a compiler error. – chill Nov 19 '12 at 20:05

## 1 Answer

Because they don't do the exact same thing. As stated in 13.3.1.7 [over.match.list]:

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

In short, you can only use implicit conversion in copy-list-initialization contexts.

This was explicitly added to make uniform initialization not, um, uniform. Yeah, I know how stupid that sounds, but bear with me.

In 2008, N2640 was published (PDF), taking a look at the current state of uniform initialization. It looked specifically at the difference between direct initialization (`T{...}`) and copy-initialization (`T = {...}`).

To summarize, the concern was that `explicit` constructors would effectively become pointless. If I have some type `T` that I want to be able to be constructed from an integer, but I don't want implicit conversion, I label the constructor explicit.

Then somebody does this:

``````T func()
{
return {1};
}
``````

Without the current wording, this will call my `explicit` constructor. So what good is it to make the constructor `explicit` if it doesn't change much?

With the current wording, you need to at least use the name directly:

``````T func()
{
return T{1};
}
``````
-
I should've known this, since I constantly complain about `std::tuple` and `std::unique_ptr`s constructor being `explicit` so I can't do `return {a, b, c};`. :) – Xeo Nov 19 '12 at 20:22
Well, since uniform initialization doesn't work uniformly on all types, I think the phrase "make uniform initialization not, um, uniform" is actually void. Eg. in snippet `X x; X y{x};`, `y` is a copy of `x` for all copyable types except those that have at least one list-constructor from any type (for those types, it usually doesn't compile). So in templates, you have to resort back to old C++03 initialization if you want to copy or convert. – jpalecek Nov 19 '12 at 22:07
@jpalecek: That's not true. The `initializer_list` constructor will only be used if the given braced-init-list is of the same type as the constructor. Therefore, it would only be called if `X` had a `X(initializer_list<X>)` constructor, which is rather unlikely. And even if it did, wouldn't it just... copy the member(s)? I'm not sure what it is you're concerned about here. The concern is usually for things like `vector<int>`, where the constructor that takes a size_t conflicts with the initailizer_list constructor. – Nicol Bolas Nov 19 '12 at 22:16
@jpalecek I believe that is a gcc4.5.1 bug, as this compiles on 4.7.0. `b` is being initialized via the (compiler generated) copy constructor, and the constructor taking `initializer_list` is not selected, even though it is preferred, because the member(s) of the braced-init-list are not convertible to `int`. As Nicol says in the earlier comment, if there existed a `A::A(initializer_list<A>)` constructor, that would be selected over the copy constructor. – Praetorian Nov 20 '12 at 1:03
@jpalecek: From section 13.3.1.7, p1: `-Initially, the candidate functions are the initializer-list constructors (8.5.4) of the class T and the argument list consists of the initializer list as a single argument. - If no viable initializer-list constructor is found, overload resolution is performed again, where the candidate functions are all the constructors of the class T and the argument list consists of the elements of the initializer list.` So you must be looking at an old version of the standard (I couldn't find that statement anywhere). – Nicol Bolas Nov 20 '12 at 1:35