Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

Am I allowed to move elements out of a std::initializer_list<T>?

#include <initializer_list>
#include <utility>

template<typename T>
void foo(std::initializer_list<T> list)
{
    for (auto it = list.begin(); it != list.end(); ++it)
    {
        bar(std::move(*it));   // kosher?
    }
}

Since std::intializer_list<T> requires special compiler attention and does not have value semantics like normal containers of the C++ standard library, I'd rather be safe than sorry and ask.

share|improve this question
    
The core language defines that the object referred to by an initializer_list<T> are non-const. Like, initializer_list<int> refers to int objects. But I think that is a defect - it is intended that compilers can statically allocate a list in read only memory. –  Johannes Schaub - litb Nov 19 '11 at 14:42

4 Answers 4

up vote 23 down vote accepted

No, that won't work as intended; you will still get copies. I'm pretty surprised by this, as I'd thought that initializer_list existed to keep an array of temporaries until they were move'd.

begin and end for initializer_list return const T *, so the result of move in your code is T const && — an immutable rvalue reference. Such an expression can't meaningfully be moved from. It will bind to an function parameter of type T const & because rvalues do bind to const lvalue references, and you will still see copy semantics.

Probably the reason for this is so the compiler can elect to make the initializer_list a statically-initialized constant, but it seems it would be cleaner to make its type initializer_list or const initializer_list at the compiler's discretion, so the user doesn't know whether to expect a const or mutable result from begin and end. But that's just my gut feeling, probably there's a good reason I'm wrong.

Update: I've written an ISO proposal for initializer_list support of move-only types. It's only a first draft, and it's not implemented anywhere yet, but you can see it for more analysis of the problem.

share|improve this answer
7  
In case it isn't clear, it still means using std::move is safe, if not productive. (Barring T const&& move constructors.) –  Luc Danton Nov 19 '11 at 9:46
    
Hmm, interesting. –  FredOverflow Nov 19 '11 at 9:46
    
I don't think that you could make the whole argument either const std::initializer_list<T> or just std::initializer_list<T> in a way that does not cause surprises quite often. Consider that each argument in the initializer_list can be either const or not and that is known in the context of the caller, but the compiler must generate just one version of the code in the context of the callee (i.e. inside foo it does not know anything about the arguments that the caller is passing in) –  David Rodríguez - dribeas Nov 19 '11 at 10:34
    
@David: Good point, but it would still be useful to have a std::initializer_list && overload do something, even if a non-reference overload is also required. I suppose it would be even more confusing than the current situation, which is already bad. –  Potatoswatter Nov 19 '11 at 10:42
    
You may be interested by this article: cpptruths.blogspot.fr/2013/10/… –  JB Jansen Mar 10 at 1:10
bar(std::move(*it));   // kosher?

Not in the way that you intend. You cannot move a const object. And std::initializer_list only provides const access to its elements. So the type of it is const T *.

Your attempt to call std::move(*it) will only result in an l-value. IE: a copy.

std::initializer_list references static memory. That's what the class is for. You cannot move from static memory, because movement implies changing it. You can only copy from it.

share|improve this answer
    
A const xvalue is still an xvalue, and initializer_list references the stack if that is necessary. (If the contents are not constant, it is still thread-safe.) –  Potatoswatter Nov 20 '11 at 0:58
3  
@Potatoswatter: You cannot move from a constant object. The initializer_list object itself may be an xvalue, but it's contents (the actual array of values that it points to) are const, because those contents may be static values. You simply cannot move from the contents of an initializer_list. –  Nicol Bolas Nov 20 '11 at 1:09
    
See my answer and its discussion. He has moved the dereferenced iterator, producing a const xvalue. move might be meaningless, but it's legal and even possible to declare a parameter that accepts just that. If moving a particular type happens to be a no-op, it might even work correctly. –  Potatoswatter Nov 20 '11 at 1:15
    
@Potatoswatter: The C++11 standard expends a lot of language ensuring that non-temporary objects are not actually moved unless you use std::move. This ensures that you can tell from inspection when a move operation happens, since it affects both the source and the destination (you don't want it to happen implicitly for named objects). Because of that, if you use std::move in a place where a move operation doesn't happen (and no actual movement will happen if you have a const xvalue), then the code is misleading. I think it's a mistake for std::move to be callable on a const object. –  Nicol Bolas Nov 20 '11 at 1:19
    
Maybe, but I'll still take fewer exceptions to the rules over the possibility of misleading code. Anyway, that is exactly why I answered "no" even though it's legal, and the result is an xvalue even if it will only bind as a const lvalue. To be honest, I've already had a brief flirtation with const && in a garbage-collected class with managed pointers, where everything relevant was mutable and moving moved the pointer management but didn't affect the contained value. There are always tricky edge cases :v) . –  Potatoswatter Nov 20 '11 at 1:32

This won't work as stated, because list.begin() has type const T *, and there is no way you can move from a constant object. The language designers probably made that so in order to allow initializer lists to contain for instance string constants, from which it would be inappropriate to move.

However, if you are in a situation where you know that the initializer list contains rvalue expressions (or you want to force the user to write those) then there is a trick that will make it work (I was inspired by the answer by Sumant for this, but the solution is way simpler than that one). You need the elements stored in the initialiser list to be not T values, but values that encapsulate T&&. Then even if those values themselves are const qualified, they can still retrieve a modifiable rvalue.

template<typename T>
  class rref_capture
{
  T* ptr;
public:
  rref_capture(T&& x) : ptr(&x) {}
  operator T&& () const { return std::move(*ptr); } // restitute rvalue ref
};

Now instead of declaring an initializer_list<T> argument, you declare aninitializer_list<rref_capture<T> > argument. Here is a concrete example, involving a vector of std::unique_ptr<int> smart pointers, for which only move semantics is defined (so these objects themselves can never be stored in an initializer list); yet the initializer list below compiles without problem.

#include <memory>
#include <initializer_list>
class uptr_vec
{
  typedef std::unique_ptr<int> uptr; // move only type
  std::vector<uptr> data;
public:
  uptr_vec(uptr_vec&& v) : data(std::move(v.data)) {}
  uptr_vec(std::initializer_list<rref_capture<uptr> > l)
    : data(l.begin(),l.end())
  {}
  uptr_vec& operator=(const uptr_vec&) = delete;
  int operator[] (size_t index) const { return *data[index]; }
};

int main()
{
  std::unique_ptr<int> a(new int(3)), b(new int(1)),c(new int(4));
  uptr_vec v { std::move(a), std::move(b), std::move(c) };
  std::cout << v[0] << "," << v[1] << "," << v[2] << std::endl;
}

One question does need an answer: if the elements of the initializer list should be true prvalues (in the example they are xvalues), does the language ensure that the lifetime of the corresponding temporaries extends to the point where they are used? Frankly, I don't think the relevant section 8.5 of the standard addresses this issue at all. However, reading 1.9:10, it would seem that the relevant full-expression in all cases encompasses the use of the initializer list, so I think there is no danger of dangling rvalue references.

share|improve this answer
    
String constants? Like "Hello world"? If you move from them, you just copy a pointer (or bind a reference). –  dyp Jul 7 at 11:38
    
"One question does need an answer" The initializers inside {..} are bound to references in the function parameter of rref_capture. This does not extend their lifetime, they're still destroyed at the end of the full-expression in which they've been created. –  dyp Jul 7 at 11:42

Consider the in<T> idiom described on cpptruths. The idea is to determine lvalue/rvalue at run-time and then call move or copy-construction. in<T> will detect rvalue/lvalue even though the standard interface provided by initializer_list is const reference.

share|improve this answer
4  
Why on earth would you want to determine the value category at runtime when the compiler already knows it? –  FredOverflow Sep 18 '13 at 19:16
    
Please read the blog and leave me a comment if you disagree or have a better alternative. Even if the compiler knows the value category, initializer_list does not preserve it because it has only const iterators. So you need to "capture" the value category when you construct the initializer_list and pass it through so the function can make use of it as it pleases. –  Sumant Sep 20 '13 at 20:40

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.