Suppose I have some code like this:

std::vector<std::string> produce(const std::string& str){
    // create a vector based on input

void consume(const std::string& str){
    for (auto i:produce(str))
        // do some thing that use the str
        // and I'd like to move it from the vector
        some_process(str) // for example, move into this function

I just wonder if the compiler (I may use either VS2015 or gcc 6) can optimize to move the elements into for-loop. Or what should I do to make it move in, since the string can be quite lengthy.

Would an old begin to end for loop or a coroutine help?

  • @songyuanyao, Won't that just bind a forwarding reference to the value returned by iterator's operator*? And since the iterator returns an lvalue reference to std::string, std::string& && will collapse down to std::string&. Here's an example
    – Alejandro
    Nov 18, 2016 at 3:48
  • @Alejandro I think you're right. Nov 18, 2016 at 3:54

2 Answers 2


If you want to move elements from that vector to some_function() just do move explicitly:

void some_function( std::string str );
void some_function( std::string &&str ); // or explicitly

for(auto &i:produce(str))
    some_function( std::move(i) );

otherwise it is not clear what you mean by moving elements into for loop.

  • This is fine because "If range_expression returns a temporary, its lifetime is extended until the end of the loop".
    – ricab
    May 26, 2021 at 19:29

Just auto& with explicit std::move is enough.

But to be fancy

struct empty_t{}; 
template<class It,class B=empty_t>struct range_t:B{
  It b,e;
  It begin()const{return b;}
  It end()const{return e;}
  range_t(It s,It f):b(std::move(s)),e(std::move(f)){}
  // fancy
  template<class S, class F>
  range_t(B base, S s, F f):B(std::move(base)),b(s(*this)),e(f(*this)){}
template<class It>range_t<It> range(It b, It e){return{std::move(b),std::move(e)};}
template<class B, class S, class F>
auto range( B base, S s, F f ){
  auto It=std::result_of_t<s(base)>;
  return range_t<It,B>{
template<class R>
auto move_from(R& r){
  using std::begin; using std::end;
  return range( std::make_move_iterator(begin(r)), std::make_move_iterator(end(r)) ); 
template<class R>
auto move_from(R&& r){
  using std::begin; using std::end;
  return range(
    [](auto&r){return std::make_move_iterator(begin(r));},
    [](auto&r){return std::make_move_iterator(end(r));}

Now, barring typos,

for(auto i:move_from(produce(str)))
  some_function( std::move(i) );

Will have i being a moved-from copy of each element.

But that is insane.

This technique may be useful when you have iterating ranfe/container based code that you want to be move-agnostic.

template<class R, class F>
auto transform_to_vector( R&& r, F&& f ){
  using std::begin; using std::end;
  using rT=std::decay_t<std::result_of_t< f(*begin(std::forward<R>(r))) >>;
  std::vector<rT> retval;
  for(auto&& e:std::forward<R>(r)){
    retval.push_back( f(decltype(e)(e)) );
  return retval;

Now, calling the above with move_from(x) as your "range" is different than calling it with x. You could imagine other algorithms written like this as well.

  • But that is insane - this time I must agree: even if I like it, it doesn't make much sense for the OP. :-)
    – skypjack
    Nov 18, 2016 at 7:34

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