• What's difference between default copy and std::move in that example?
  • After move the object is there any dependence between new and old ones?
int main () {

    int a = 100;

    auto a_copy = a;                 // deduced as int

    auto a_move = std::move(a);      // deduced as int



  • 14
    Be aware that std::move doesn't actually move anything. It just performs a cast to rvalue ref, and the result is helpfully an rvalue whereas simply naming a is not. These two facts are part of providing an object from which to move but are not actually the thing that moves from it. So, asking about "after move" is a red herring. – Lightness Races in Orbit Jan 11 '15 at 15:56

In this example, there is no difference. We will end up with 3 ints with value 100. There could definitely be a difference with different types though. For instance, let's consider something like vector<int>:

std::vector<int> a = {1, 2, 3, 4, 5}; // a has size 5
auto a_copy = a;                      // copy a. now we have two vectors of size 5
auto a_move = std::move(a);           // *move* a into a_move

The last variable, a_move, takes ownership of a's internal pointers. So what we end up with is a_move is a vector of size 5, but a is now empty. The move is much more efficient than a copy (imagine if it was a vector of 1000 strings instead - a_copy would involve allocating a 1000-string buffer and copying 1000 strings, but a_move just assigns a couple pointers).

For some other types, one might be invalid:

std::unique_ptr<int> a{new int 42};
auto a_copy = a;            // error
auto a_move = std::move(a); // OK, now a_move owns 42, but a points to nothing

For many types, there's no difference though:

std::array<int, 100> a;
auto a_copy = a;            // copy 100 ints
auto a_move = std::move(a); // also copy 100 ints, no special move ctor

More generally:

T a;
auto a_copy = a;            // calls T(const T& ), the copy constructor
auto a_move = std::move(a); // calls T(T&& ), the move constructor
  • 1
    @Person.Junkie Yes, std::move just performs a static cast to rvalue ref, but definitely prefer std::move() over writing the cast - it's (a) less typing and (b) makes the intent of the line of code much clearer. – Barry Jan 11 '15 at 15:58
  • 2
    @Barry: I disagree - although it's much shorter it is a lie. – Lightness Races in Orbit Jan 11 '15 at 15:59
  • 3
    @LightnessRacesinOrbit would you prefer to see std::move renamed to something like std::rref? Because I know I would - std::move is extremely misleading. – mbgda Jan 11 '15 at 16:38
  • 3
    @Barry: Yeah, there we go; that's probably what I'm remembering. I believe it's a point that's been conceded a few times by various high-profile types (as opposed to being limited to forum posts on cprogramming.com). That is, "it signifies intent" is a cute principle that may work well in simple scripting languages, but it entirely defies logic (not to mention established paradigms) in something as flexible as C++. – Lightness Races in Orbit Jan 11 '15 at 16:45
  • 3
    The vector a is not guaranteed to be empty after move. – T.C. Jan 11 '15 at 20:38

Using std::move just changes an lvalue to an xvalue, so it is eligible for use with move constructors and move assignment operators. These do not exist for built-in types, so using move makes no difference in this example.


What's difference between default copy and std::move in that example?

There is no difference. Copying something satisfies the requirements of a move, and in the case of built-in types, move is implemented as a copy.

After move the object is there any dependence between new and old

No, there are no dependencies. Both variables are independent.

  • ...and what is advantage of std::move and why? – Person.Junkie Jan 11 '15 at 15:45
  • 2
    @Person.Junkie Here? There is no advantage. There is the disadvantage that the code is confusing. – juanchopanza Jan 11 '15 at 15:46
  • In general? why exist std::move? I know that std::move convert lvalue/rvalue to rvalue using static_cast, can this 'cast' cause big improvement? – Person.Junkie Jan 11 '15 at 15:49
  • 5
    @Person.Junkie That is way too broad. There are whole papers about that. But basically, some types are cheap to move, and expensive to copy. In these cases there may be an advantage in moving. Also, some things are not copyable, but may be movable (e.g. a file stream or a unique pointer.) – juanchopanza Jan 11 '15 at 15:50
  • 7
    @Person.Junkie: The cast doesn't itself cause any "big improvement". The cast allows a programmer to conveniently indicate that they want a different function called to implement the data transfer: conventionally, we write "move constructors" that move rather than copy, e.g. by swapping internal pointers. That can cause a huge improvement, but std::move itself doesn't do that. You could do it in C++03 with tags and various other techniques, it just wasn't quite as convenient (and couldn't work generically e.g. elements in standard library containers). – Lightness Races in Orbit Jan 11 '15 at 15:58

To expand on the other poster's answer, the move-is-a-copy paradigm applies to all data structures composed of POD types (or composed of other types composed of POD types) as well, as in this example:

struct Foo
    int values[100];
    bool flagA;
    bool flagB;

struct Bar
    Foo foo1;
    Foo foo2;

int main()
    Foo f;
    Foo fCopy = std::move(f);
    Bar b;
    Bar bCopy = std::move(b);
    return 0;

In the case of both Foo and Bar there is no meaningful way to move the data from one to another because both are ultimately aggregates of POD types - none of their data is indirectly owned (points to or references other memory). So in these cases, the move is implemented as a copy and originals (f, b) remain unaltered after the assignments on the std::move() lines.

Move semantics can only be meaningfully implemented with dynamically allocated memory or unique resources.

  • 1
    "there is no meaningful way to move the data from one to another because both are composed of value types" -- I don't think value types is the correct term here. All of the standard library containers are value types, and there is certainly a meaningful way to move their data. – Benjamin Lindley Jan 11 '15 at 15:57
  • 1
    @BenjaminLindley They are not composed of value types though - they contain dynamically allocated memory (so, pointer types). – mbgda Jan 11 '15 at 15:57
  • Okay, but if I put a std::vector in a struct, like this: struct Foo { std::vector<int> v; };, then that struct is composed of value types, and there is a meaningful way to move its data. – Benjamin Lindley Jan 11 '15 at 16:00
  • 1
    @BenjaminLindley I think you're being too pedantic about this - it's composed only of value types on the surface, but not through the entire composition chain. – mbgda Jan 11 '15 at 16:00
  • 1
    I like to call it "flat data" but I think I made that up. The point, of course, is that there's no indirection involved so if you can work that into the language somehow, you're sorted. – Lightness Races in Orbit Jan 11 '15 at 16:03

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

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