Sign up ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free.

I have the following code

auto adder = [](string& s1, const string& s2)->string&&
      if (!s1.empty())
         s1 += " ";
      s1 += s2;
      return move(s1);

   string test;
   test.reserve(wordArray.size() * 10);
   string words = accumulate(wordArray.begin(), wordArray.end(), 
       move(test), adder);

What I would like here is to avoid string copying. Unfortunately this is not accomplished by the vs2012 implementation of accumulate. Internally accumulate calls another function _Accumulate and the rvalue functionality gets lost in the process.

It I instead call the _Accumulate function like so

string words = _Accumulate(wordArray.begin(), wordArray.end(), 
    move(test), adder);

I get the intended performance gain.

Must the std library be rewritten to take rvalue arguments into consideration?

Is there some other way I may use accumulate to accomplish what I want without cheating too much?

share|improve this question

migrated from Dec 5 '12 at 14:27

This question came from our site for professional programmers interested in conceptual questions about software development.

your test is not an rvalue. the s1 in lambda is not an rvalue –  BЈовић Dec 5 '12 at 14:48

1 Answer 1

Checking one of the recent post C++11 drafts (N3337.pdf) we can see that the effect of std::accumulate is specified as

Computes its result by initializing the accumulator acc with the initial value init and then modifies it with acc = acc + *i or acc = binary_op(acc, *i) for every iterator i in the range [first,last) in order.

So, the standard actually forbids implementations that use std::move for the old accumulator value like this:

template <class InputIterator, class T, class BinOp>
T accumulate (InputIterator first, InputIterator last, T init, BinOp binop)
  while (first!=last) {
    init = binop(std::move(init), *first);
  return init;

which is unfortunate in your case.

Option (1): Implement this move-aware accumulate yourself.

Option (2): Keep using a functor like

struct mutating_string_adder {
  string operator()(string const& a, string const& b) const {return a+b;}
  string operator()(string & a, string const& b)      const {a += b; return std::move(a);}
  string operator()(string && a, string const& b)     const {a += b; return std::move(a);}

Note that I did not use rvalue reference return types here. This is intentional since it might avoid dangling reference issues, for example in the case where the last overload is picked and 'a' initialized to refer to a temporary object. All the operator+ overloads for strings also intentionally return by value.

Apart from that you might want to use std::copy in combination with std::stringstream and an output stream iterator.

Addendum: Alternate mutating_string_adder with some partial perfect forwarding:

struct mutating_string_adder {
  template<class T, class U>
  std::string operator()(T && a, U && b) const {
    return std::move(a) + std::forward<U>(b);
share|improve this answer
mutating_string_adder - the 2nd operator(), a is lvalue, therefore move doesn't do anything. However, I am not sure if the 1st operator() should use move. –  BЈовић Dec 6 '12 at 10:15
@BЈовић: The purpose of std::move is to turn an lvalue into an rvalue. So, sure, std::move does something. If I removed std::move around a in the return statement, the return value would be copy constructed instead of move constructed. There is no need to use std::move for the first overload because a+b already is an rvalue. –  sellibitze Dec 6 '12 at 10:25
The move-aware accumulate worked fine with no copies anywhere and the same reserved area used all the way –  Rolf W. Petersen Dec 6 '12 at 11:01
Right for the 1st, but I think you are wrong for the 2nd. Why would you turn lvalue into rvalue? Is that was possible, the object that is passed to s1 would be moved, and wouldn't exists anymore. Therefore, accessing it would be UB –  BЈовић Dec 6 '12 at 11:49
@BЈовић: I already said why std::move is used in the 2nd operator() overload. Sorry, I don't see any problems. Where exactly do you think there is an access of a moved-from object -- other than the assignment in the move-aware version of accumulate? –  sellibitze Dec 6 '12 at 16:50

Your Answer


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.