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There are two existing questions about replacing vector elements that are not assignable:

A typical reason for an object to be non-assignable is that its class definition includes const members and therefore has its operator= deleted.

std::vector requires that its element type be assignable. And indeed, at least using GCC, neither direct assignment (vec[i] = x;), nor a combination of erase() and insert() to replace an element works when the object is not assignable.

Can a function like the following, which uses vector::data(), direct element destruction, and placement new with the copy constructor, be used to replace the element without causing undefined behaviour?

template <typename T>
inline void replace(std::vector<T> &vec, const size_t pos, const T& src)
  T *p = + pos;
  new (p) T(src);

An example of the function in use is found below. This compiles in GCC 4.7 and appears to work.

struct A
  const int _i;
  A(const int &i):_i(i) {}

int main() {
  std::vector<A> vec;
  A c1(1);
  A c2(2);

  std::cout << vec[0]._i << std::endl;

  /* To replace the element in the vector
     we cannot use this: */
  //vec[0] = c2;

  /* Nor this: */

  /* But this we can: */
  std::cout << vec[0]._i << std::endl;

  return 0;
share|improve this question
Almost every STL implementation (and now standard library) i've ever seen utilizes this very technique to the high-heavens for sequence management. The only part of this specific usage you have here that raises my brow is the potential that the placement-construction may throw, at which time you now have a destroyed element in the vector, but the vector doesn't know that and will try to destroy it again on its own destruction. Nice question, btw. – WhozCraig Oct 16 '12 at 6:08
@WhozCraig: I agree, maybe conditioning this function on the copy constructor being nothrow ? (is_nothrow_copy_constructible) – Matthieu M. Oct 16 '12 at 6:41
Because value semantics get in the way. Coming from Java or other "reference-oriented" programming languages, people expect to be able to bind constant objects to mutable variables. As soon as you have one const member in class X, you cannot assign to variables of type X anymore (because variables are nothing more than named objects in C++), and that's rarely what people want. – fredoverflow Oct 16 '12 at 6:51
This doesn't solve the problem in any way, as the requirement stands: any object in a vector must be copyable. And it's definitely an antipattern, in that it isn't exception safe, and will raise havoc in the case of inheritance. If you want to support assignment, support assignment. – James Kanze Oct 16 '12 at 7:16
@jogojapan Compilers can and do enforce this requirement. Try compiling with g++ -D_GLIBCXX_CONCEPT_CHECKS. (At one point, it was the intent to require this to fail to compiler. This was deferred since concepts didn't make it into this release, but I would expect it to be the case in the next version of the standard.) – James Kanze Oct 16 '12 at 7:48
up vote 11 down vote accepted

This is illegal, because 3.8p7, which describes using a destructor call and placement new to recreate an object in place, specifies restrictions on the types of data members:

3.8 Object lifetime []

7 - If, after the lifetime of an object has ended and before the storage which the object occupied is reused or released, a new object is created at the storage location which the original object occupied, a pointer that pointed to the original object [...] can be used to manipulate the new object, if: [...]
— the type of the original object [...] does not contain any non-static data member whose type is const-qualified or a reference type [...]

So since your object contains a const data member, after the destructor call and placement new the vector's internal data pointer becomes invalid when used to refer to the first element; I think any sensible reading would conclude that the same applies to other elements as well.

The justification for this is that the optimiser is entitled to assume that const and reference data members are not respectively modified or reseated:

struct A { const int i; int &j; };
int foo() {
    int x = 5;
    std::vector<A> v{{4, x}};
    bar(v);                      // opaque
    return v[0].i + v[0].j;      // optimised to `return 9;`
share|improve this answer
Brilliant find! +1 and likely to be accepted soon. – jogojapan Oct 16 '12 at 10:39

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