I am trying to understand the semantic difference between these two ways of initialization:

Foo foo{x};
Foo foo = {x};

I am interested to know the difference in the following cases:

  1. x is of type Foo.
  2. Foo has a constructor that takes an argument of the same type as that of x.
  3. x is not of type Foo but a converting constructor is available.
  4. x is not of type Foo but an explicit converting constructor is available.

By difference I mean, in each case:

  1. Conceptually, which constructors are invoked?
  2. Which constructors calls are usually optimized away by the compiler?
  3. Is implicit conversion allowed?
  • 5
    Have you done any research at all? cppreference pretty much covers all there is to know about list initialization.
    – user3920237
    Feb 17, 2015 at 19:16
  • There's no such thing as an "explicit converting constructor". And I'm not sure what kind of distinction you are trying to draw between 2) and 3).
    – T.C.
    Feb 17, 2015 at 19:32
  • 5
    Downvoted because you didn't do any research. A question is only useful if the information does not already exist. Feb 17, 2015 at 19:40
  • Related: stackoverflow.com/q/20733360
    – dyp
    Feb 17, 2015 at 19:55
  • 1
    – Mark
    Feb 17, 2015 at 21:45

1 Answer 1

Foo foo{x};    // 1

Foo foo = {x}; // 2

1 is direct-list-initialization. 2 is copy-list-initialization.

Assuming that Foo is a class type, then in most cases they do exactly the same thing, conceptually or otherwise, except that if an explicit constructor is selected during overload resolution, then #2 is ill-formed. In particular, unlike copy-initialization, copy-list-initialization does not conceptually construct a temporary.

The one exception is when x is of type Foo or a type derived therefrom. In this case, #1 is equivalent to Foo foo(x); (i.e., direct-initialization) and #2 is equivalent to Foo foo = x; (i.e., copy-initialization). The subtle difference is that overload resolution for #2 in this case considers only non-explicit constructors, rather than considering all constructors and then becoming ill-formed if an explicit constructor is selected.* This exception is added by the resolution of CWG issue 1467, which was adopted last November.

* You'd have to write some pretty tortured code for this to matter. For example:

struct X
    X() = default;
    explicit X(X&);
    X(const X&);

int main() { 
    X x1;
    X x2 = {x1}; // #1
    X x3 = x1;   // #2

Pre-CWG1467, line #1 is ill-formed because overload resolution selects X(X&), which is explicit. Post-CWG1467, the explicit constructor X(X&) isn't considered, so X(const X&) is used. Note that line #2 is always well-formed and uses X(const X&).

  • You may want to improve this answer by quoting the relevant sections from the standard, clarify some parts and so on.
    – edmz
    Feb 17, 2015 at 19:17
  • @black IMO quoting the standard to explain initialization leads to bloat unless it's a language-lawyer esque question. The OP is essentially asking how initialization works, it would be unnecessary.
    – user3920237
    Feb 17, 2015 at 19:17
  • @remyabel Well yes but I think the answer should be expanded to cover the topics the OP's asking about a little more completely.
    – edmz
    Feb 17, 2015 at 19:28
  • 3
    @black If you read the question, you can see the OP is asking about 4 different cases, with 3 questions for each. I'm unable to see why T.C. should have to jump through hoops to make an unnecessarily bloated answer when what he has so far is sufficient.
    – user3920237
    Feb 17, 2015 at 19:30
  • @remyabel Different POVs. Now that the answer has been updated it seems to be more valid. --end OT.]
    – edmz
    Feb 17, 2015 at 19:43

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