If I understand it correct, a=std::move(b) binds reference a to the address of b. And after this operation the content that b points to is not guaranteed.

The implementation of move_iterator here has this line

auto operator[](difference_type n) const -> decltype(std::move(current[n]))
  { return std::move(current[n]); }

However, I don't think it makes sense to std::move an element in an array. What happens if a=std::move(b[n])?

The following example confuses me also:

std::string concat = std::accumulate(

Since the concat will itself allocate a continuous chunk of memory to store the result, which will not have any overlap with source. The data in source will be copied to concat but not moved.

  • 4
    "If I understand it correct, a=std::move(b) binds reference a to the address of b." Only if this is a declaration, and a is of reference type. Otherwise, it is a move-assignment. E.g. if a and b are std::vector<int>, the pointer to the heap storage the vector manages is copied from b to a, and b is changed to point to somewhere else.
    – dyp
    Jan 20, 2015 at 10:33
  • 1
    Iterators are an abstraction of pointers. Dereferencing a pointer yields an lvalue: int i = 42; int* p = &i; then *i is an lvalue. Similarly for iterators. But that means that the algorithms will typically copy the values iterators refer to. move_iterator makes *it return an rvalue.
    – dyp
    Jan 20, 2015 at 10:36

3 Answers 3


If I understand it correct, a=std::move(b) binds reference a to the address of b. And after this operation the content that b points to is not guaranteed.

Ah, no: a is not necessarily a reference. The above use of std::move also grants the compiler permission to call decltype(a)::operator=(decltype(b)&&) if it exists: such assignment operators are used when during the assignment to a the value of b need not be preserved, but b must still be left in some sane state for destruction.

However, I don't think it makes sense to std::move an element in an array. What happens if a=std::move(b[n])?

It can make sense... it just means that each array elements may be efficiently assigned/moved to another variable, but only once per element. After they've been moved-from, a properly-written move constructor or assignment operator should leave objects in a valid but unspecified state, which means you'd usually want to set them again before reading from them.

My answer here shows how someone could append/move elements from a list to a vector. With current C++ Standards, you can create move_iterators directly like that.

The code below shows how - even with older compilers / C++ Standards - make_move_iterator can be used with std::copy if you want to move from the elements in the source iterator range.

#include <iostream>
#include <vector>
#include <algorithm>
#include <iterator>

struct X
    X(int n) : n_(n) { }
    X(const X& rhs) : n_(rhs.n_) { }
    X(X&& rhs) : n_{ rhs.n_ } { rhs.n_ *= -1; std::cout << "=(X&&) "; }
    X& operator=(X&& rhs) { n_ = rhs.n_; rhs.n_ *= -1; std::cout << "=(X&&) "; return *this; }
    int n_;

int main()
    std::vector<X> v{2, 1, 8, 3, 4, 5, 6};
    std::vector<X> v2{};

    std::copy(v.begin() + 2, v.end(), std::insert_iterator(v2, v2.end()));
    for (auto& x : v)
        std::cout << x.n_ << ' ';
    std::cout << '\n';

    std::copy(std::make_move_iterator(v.begin() + 2), std::make_move_iterator(v.end()), std::insert_iterator(v2, v2.end()));
    for (auto& x : v)
        std::cout << x.n_ << ' ';
    std::cout << '\n';


2 1 8 3 4 5 6 
=(X&&) =(X&&) =(X&&) =(X&&) =(X&&) 2 1 -8 -3 -4 -5 -6 

Code can be run / edited on coliru.

  • Now I understand, I thought with std move, compiler would do some magic to swap the memory of two lvalue variables. It turns out that the magic is done through copy constructor that takes an rvalue. Which means it won't work on plain old types. For example, if b is an int array, a=std::move(b[n]) would be the same as a=b[n].
    – Min Lin
    Jan 20, 2015 at 11:34
  • 1
    @MinLin: copy constructors and assignment operators are the most obvious uses for "move magic". As you say - they don't make operations on ints more efficient - only types where there's some way to take ownership of data without as much copying or allocation/deallocation. Jan 20, 2015 at 12:18
  • @MinLin: Notice that "copy constructor that takes an rvalue" is exactly what we mean when we say "move constructor." What you said is an unusual, but perfectly cromulent, way of putting it. :) (Although, also notice, we're talking about assignment operators here. So you could have said "copy assignment operator that takes an rvalue", or "move assignment operator" — again, both perfectly accurate descriptors.) Apr 19, 2017 at 21:54
  • 1
    remove_if would move anyway, so i don't see a gain
    – Yola
    Mar 13, 2018 at 11:53
  • 1
    @Yola: true now - maybe ideone (the online compiler I used back in 2015) was using an old compiler version that hadn't updated remove_if to do that - can't remember for sure. But, I've replaced the example to show how it can be used in combination with std::copy. Mar 14, 2018 at 11:47

The purpose of move_iterator is to supply algorithms with rvalues of their inputs.

Your example auto a=std::move(b[n]) does not move a value in an array but moves it out of it, which is a sensible thing to do.

The trick in your std::accumulate is the definition of operator+ for std::string (remember that the default version of accumulate uses operator+. It has a special optimization for rvalue arguments. For our case overload number 7 is the important one since accumulate uses the expression init + *begin. This will try to reuse the memory of the right hand side argument. If this actually turns out to be an optimization is not really clear.

  • Could you explain the difference between aVector.push_back(std::move(*it)) and aVector.push_back(*std::make_move_iterator(it)) ?
    – Vassilis
    Dec 15, 2018 at 16:03

http://en.cppreference.com/w/cpp/iterator/move_iterator says this:

std::move_iterator is an iterator adaptor which behaves exactly like the underlying iterator (which must be at least an InputIterator), except that dereferencing converts the value returned by the underlying iterator into an rvalue.

Most (if not all) standard algorithms that accept a range, walk an iterator from the beginning of the range to the end, and perform an operation on the dereferenced iterator. For example, std::accumulate might be implemented as:

template <class InputIterator, class T>
T accumulate (InputIterator first, InputIterator last, T init)
  while (first!=last) {
    init = init + *first;
  return init;

If first and last are normal iterators (the call was

std::accumulate(source.begin(), source.end(), std::string("1234"));

, then *first is an lvalue reference to string, and the expression init + *first will call std::operator+(std::string const&, std::string const&) (overload 1 here).

However, if the call was

std::accumulate(std::make_move_iterator(source.begin()), std::make_move_iterator(source.end()), std::string("1234"));

then inside std::accumulate, first and last are move iterators and therefore *first is an rvalue reference. This means that init + *first calls std::operator+(std::string const&, std::string &&) instead (overload 7).

  • In fact, overload 7 (where lhs is an lvalue [string const&] and rhs is an rvalue [string &&]) is implemented like this: return std::move(rhs.insert(0, lhs)); in order to avoid having to copy the (const) lhs before modification. Instead, it modifies the (temporary) rhs and then steals from it. Feb 5, 2015 at 14:31
  • Overload 8 (where both strings are temporary rvalues) is even smarter: it either inserts lhs into rhs or appends rhs to lhs depending on which string has enough capacity for the entire result. Feb 5, 2015 at 14:32

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