Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

Is this class design the standard C++0x way to prevent copy and assign, to protect client code against accidental double-deletion of data?

struct DataHolder {
  int *data;   // dangerous resource
  DataHolder(const char* fn); // load from file or so
  DataHolder(const char* fn, size_t len); // *from answers: added*
  ~DataHolder() { delete[] data; }

  // prevent copy, to prevent double-deletion
  DataHolder(const DataHolder&) = delete;
  DataHolder& operator=(const DataHolder&) = delete;

  // enable stealing
  DataHolder(DataHolder &&other) {
    data=other.data; other.data=nullptr;
  DataHolder& operator=(DataHolder &&other) {
    if(&other!=this) { data = other.data; other.data=nullptr};
    return *this;

You notice, that I defined the new move and move-assign methods here. Did I implement them correctly?

Is there any way I can -- with the move and move-assign definitions -- to put DataHolder in a standard container? like a vector? How would do I do that?

I wonder, some options come into mind:

// init-list. do they copy? or do they move?
// *from answers: compile-error, init-list is const, can nor move from there*
vector<DataHolder> abc { DataHolder("a"), DataHolder("b"), DataHolder("c") };

// pushing temp-objects.
vector<DataHolder> xyz;
xyz.push_back( DataHolder("x") );
// *from answers: emplace uses perfect argument forwarding*
xyz.emplace_back( "z", 1 );

// pushing a regular object, probably copies, right?
DataHolder y("y");
xyz.push_back( y ); // *from anwers: this copies, thus compile error.*

// pushing a regular object, explicit stealing?
xyz.push_back( move(y) );

// or is this what emplace is for?
xyz.emplace_back( y ); // *from answers: works, but nonsense here*

The emplace_back idea is just a guess, here.

Edit: I worked the answers into the example code, for readers convenience.

share|improve this question
const RValue references? –  Benjamin Lindley Apr 16 '11 at 15:29

2 Answers 2

up vote 5 down vote accepted

Your example code looks mostly correct.

  1. const DataHolder &&other (in two places).

  2. if(&other!=this) in your move assignment operator looks unnecessary but harmless.

  3. The initializer list vector constructor won't work. This will try to copy your DataHolder and you should get a compile time error.

  4. The push_back and emplace_back calls with rvalue arguments will work. Those with lvalue arguments (using y) will give you compile time errors.

There really is no difference between push_back and emplace_back in the way that you have used them. emplace_back is for when you don't want to construct a DataHolder outside of the vector, but instead pass the arguments to construct one only inside the vector. E.g.:

// Imagine this new constructor:
DataHolder(const char* fn, size_t len);

xyz.emplace_back( "data", 4 );  // ok
xyz.push_back("data", 4 );  // compile time error


I just noticed your move assignment operator has a memory leak in it.

DataHolder& operator=(DataHolder &&other)
      delete[] data;  // insert this
      data = other.data;
   return *this;
share|improve this answer
I don't think preventing move-to-self is useless. After all, a = std::move(a) is valid and should be a no-op. –  ltjax Apr 16 '11 at 15:57
(1) copy-paste-error. i edited that out. (2) really? isn't that the usual pattern for copy? temp-object can not be this? hmmm. (3) right, the init-list members behave const. ok. (4) Ah, thats "emplace"... of course. Now I understand. (*) Beautiful all those new things working together: rvalue-refs, perfect-forwarding, template-varargs. Great! –  towi Apr 16 '11 at 17:00
@towi - The usual pattern for copy is the "copy-and-swap" idiom: T& operator =(T rhs /* pass by value! */) { this->swap(rhs); return *this; } This has three benefits: 1) delegates to copy ctor so no need to duplicate code; 2) is exception-safe iff swap does not throw (and it shouldn't!); and 3) self-assignment works without an explicit check. this->swap(rhs) (with T&& rhs) is also often a nice way to implement the move assignment operator. –  JohannesD Apr 16 '11 at 17:58
@JohannesD waitwaitwait... Ok, the pass-by-value I can understand, thats where the delegation to copy-ctor happens. but what's with T::swap(T&)? I have to implement that, and that would be duplicate code. Ok, often we implement it anyway. Thats what you mean, right? Why is explicit self-check not needed? Because its done in swap? Hmm... because rhs is a copy. But that would make two copies, One implicit in the call-by-value, one explicit piece-by-piece in swap(T&). Ok, thats cheap, I see! You suggest two swap impls, right? swap(T&) and swap(T&&)? Thx a billion... –  towi Apr 16 '11 at 19:41
@JohannesD I just want to point out, that in this class I want to discourage the client code from using copy at all. Copy here is expensive, and data could also be a non-copyable resource -- a file, a lock. I don't like providing a copy-ctor for data-holding classes, you never know how often you copy, then. –  towi Apr 16 '11 at 19:49

Temporary objects that hold no name, eg. DataHolder("a"), are moved when available. The standard container in C++0x will always move when possible, that's what also allows std::unique_ptr to be put in a standard container.
Besides that, you implemented your move operations wrong:

  // enable stealing
  DataHolder(const DataHolder &&other) {
    data=other.data; other.data=nullptr;
  DataHolder& operator=(const DataHolder&&other) {
    if(&other!=this) { data = other.data; other.data=nullptr};
    return *this;

How do you move from a constant object? You can't just change the other's data, as that other is constant. Change that to simple DataHolder&&.

share|improve this answer
ups, copy-paste-error with the const&&ies. I removed the consts so readers will not learn this faulty code. –  towi Apr 16 '11 at 16:55

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.