6
#include <vector>

struct A { int a[100]; };

void foo (const A& a) {
  std::vector<A> vA; 
  vA.push_back(std::move(a));  // how does move really happen?
}

int main () {
  A a;
  foo(a);
}

The above code compiles fine. Now everywhere it's written that move avoids copying.
Following are my queries:

  1. Does the move really work when one deals with a lvalue [non]-const reference?
  2. Even with "rvalue reference", how is the copy avoided when the object is inserted into a standard container like above?

e.g.

void foo (A&& a) {  // suppose we invoke this version
  std::vector<A> vA; 
  vA.push_back(std::move(a));  // how copy is avoided?
}
  • 1
    It works in the sense that std::move(a) produces a const A && (remember that std::move merely casts its argument to a rvalue reference). But there's no such thing as a push_back(const A &&) -- only push_back(const A &) and push_back(A &&)--, and the first one will be called, causing a copy to happen (since you can't bind a const rvalue ref to a non-const rvalue ref, but you can bind it to a const lvalue reference). – peppe Aug 12 '16 at 11:45
  • What do you mean, "how is the copy avoided?". Are you asking how vector::push_back(T &&) is implemented? – Steve Jessop Aug 12 '16 at 11:53
  • @SteveJessop, in a way Yes. But I would fine not to go much in details. My basic question is that, since A&& a coming from outside might be created in some location. std::vector is contiguous container. How is it possible to avoid the copy at all? – iammilind Aug 12 '16 at 11:55
  • 2
    @iammilind: well, in the case where the value type T is the struct A from your code, moving that type is exactly the same as copying it, so the copy isn't avoided. For a type with a useful move constructor (like for example vector itself has) which does something faster than what the copy constructor does, then we'd be in business. But if a type stores all its data inside the object itself (i.e. no external data structure like vector has) then generally speaking you can't write a useful move constructor/assignment. – Steve Jessop Aug 12 '16 at 11:57
  • 2
    The thing to remember is that the concept Copyable is a subset of the concept Movable. Everything that is Copyable automatically is also Movable, even if the thing that C++ refers to as a move is actually implemented just as a copy. That's part of why moving doesn't specify what state the source is left in: it's permitted not to change its state at all. Whereas not everything that is Movable is also Copyable (for example unique_ptr), and for some Copyable things the move is different from the copy (like vector). – Steve Jessop Aug 12 '16 at 12:05
10

std::move doesn't do a move. It actually casts the lvalue reference to an rvalue reference. In this case, the result of the move is a const A && (which is totally useless by the way).

std::vector has an overload for a const A & and a A &&, so the overload with const A & will get chosen and the const A && is implicitly casted to const A &

The fact that std::move can be called on const objects, is strange/unexpected behavior for most programmers, though it somehow is allowed. (Most likely they had a use case of it, or none to prevent it)

More specific for your example, the move constructor of the class A will get called. As A is a POD, this most likely will just do a copy as all bits just have to move/copied to the new instance of A.

As the standard only specifies that the original object has to be in a valid though unspecified state, your compiler can keep the bits in A in place and doesn't have to reset them all to 0. Actually, most compilers will keep these bits in place, as changing them requires extra instructions, which is bad for performance.

  • Why is it strange? The fact that const T & can bind to rvalues is not new in C++11. – user743382 Aug 12 '16 at 11:50
  • Let me clearify that sentence, I meant the existance of const A && – JVApen Aug 12 '16 at 11:50
  • 4
    It stops being strange when you consider that in C++, adding std::move into a bit of code that otherwise would result in a copy, and in general the Movable concept mean "move if possible otherwise copy". They don't mean "move if possible otherwise fail to compile". – Steve Jessop Aug 12 '16 at 11:51
  • 1
    Okay, then still, why is it strange? const-qualified rvalues are not new in C++11 either. :) – user743382 Aug 12 '16 at 11:51
  • 1
    No copy is avoided. Your two foo functions will behave exactly the same since you've not defined a move constructor (nor does your A class have any movable resources). – Miles Budnek Aug 12 '16 at 11:55
0

Created a snippet to show it. Though in your example default constructor will be called, but you get the idea.

#include <vector>
#include <iostream>

struct A { 
  int a[100];
  A() {}
  A(const A& other) {
    std::cout << "copy" << std::endl;
  }
  A(A&& other) {
    std::cout << "move" << std::endl;
  }
};

void foo(const A& a) {
  std::vector<A> vA; 
  vA.push_back(std::move(a));
}

void bar(A&& a) {
  std::vector<A> vA; 
  vA.push_back(std::move(a));
}

int main () {
  A a;
  foo(a);            // "copy"
  bar(std::move(a)); // "move"
}
  • it would be more demonstrative if you write foo(std::move(a)); – Slav Jun 18 '19 at 12:29

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