25

Having this code:

template <class IIt, class OIt>
OIt copy2(IIt begin, IIt end, OIt dest)
{
   while (begin != end)
   {
      //make gap between element addresses
      for (int i = 0; i < 99999999; i++)
      {
         dest++;
      }
      *dest++ = *begin++;
   }
   return dest;
}

int main(int argc, char** argv)
{
   vector<int> vec({ 1, 2, 3 });
   vector<int> vec2;
   copy2(vec.begin(), vec.end(), back_inserter(vec2));
   for (int i : vec2)
   {
      cout << i << endl;
   }
}

Which takes quite a long to compile, but will finally do with the proper output

1
2
3

The problem is (without knowing the inner implementation of std::vector, is it c-style array? or more complex structure?), how can it properly find those elements in the for(int i:vec2), when the address (pointers) of those elements are not sequential? (i.e. because of the shifting of the iterator/pointer by 99999999).

I thought there was a requirement for OutputIterator to have that property, that only one-access, one-shift could be performed on it. But when you shift(add) it more than once between accessing them, then there is a gap, which is quite huge in my case. So how does it compile?

  • @Graham a vector gives you a pointer to a C-style array from data(), but it can resize it in place (up to capacity) without affecting the existing elements. Prior to C++20, that requires implementation-defined magic – Caleth Aug 1 at 8:56
  • 2
    @Caleth It is permitted to resize it in place, which in practise means allocating successively larger arrays with space to grow up to some limit before more allocation is needed. Because the underlying storage is defined to be a contiguous C-style array, resizing may need a new allocation and copy, so you can't rely on pointers staying valid after resizing. – Graham Aug 1 at 9:58
  • @Graham I don't mean reallocating, but a vector<T> with capacity >= 5 can hand out a pointer to a T[4], have an element inserted, then hand out a pointer to a T[5] with the same address as the T[4]. Somehow it has to destroy the T[4] and construct a T[5] without affecting the elements – Caleth Aug 1 at 10:03
  • 1
    @Caleth After inserting, the address of T[5] could theoretically be same as the previous T[4] depending on implementation; but it could equally well be completely the other end of memory. Pointers to internal storage become invalid after any resize operation, so after you do the insert, you'd need to find the new address of that T[5] element. That's why all the resize operations have the side effect of invalidating all iterators. You're guaranteed that the data in the previous T[4] will be in T[5] after insertion, but not where that data lives in memory. – Graham Aug 1 at 10:25
  • 1
    I think you confuse “compile” with “execute”. – Carsten S Aug 2 at 10:45
52

You've been fooled.

The iterator returned by std::back_inserter has it++ as a no-op. So those 'gaps' you are creating? Yeah that's all doing nothing.

| improve this answer | |
  • 3
    But clearly, OP knew there was no gap, they did print the vector... It's really unclear what they thought they were doing with this loop. – Jeffrey Jul 31 at 17:51
  • 10
    @Jeffrey My interpretation of their premise is that the gaps are there somewhere, and there is a pointer somewhere, and the pointer jumps over the gaps, which pointers aren't supposed to do. – eerorika Jul 31 at 22:43
  • They also have the problem that if it did reallocate the array to create a gap, then all their pointers and iterators would become invalid and their code would throw an exception. So it can only run by not working as expected. :) – Graham Aug 1 at 10:55
19

Your for-loop

for (int i = 0; i < 99999999; i++)
{
    dest++;
}

does not do what you think. It has no effect on there, other than iterating from 0 to 99999999.

When you look into the std::back_insert_iterator, it says

[...]. Incrementing the std::back_insert_iterator is a no-op.

or as stated in 23.5.2.1.1 it simply returns the back_insert_iterator, without doing anything into it.

constexpr back_insert_iterator& operator++();
constexpr back_insert_iterator  operator++(int);

#Returns: *this.

Meaning dest++; has no effect. This makes entire assumptions you made, completely not valid. The program took long to execute only because of the iteration from 0 to 99999999.


It raises the question: Then why there is an std::back_insert_iterator<Container>::operator++ overload at all?

From cpprefereence std::back_insert_iterator<Container>::operator++:

Does nothing. These operator overloads are provided to satisfy the requirements of LegacyOutputIterator. They make it possible for the expressions *iter++=value and *++iter=value to be used to output (insert) a value into the underlying container.

| improve this answer | |
18

std::vector, is it c-style array?

Not quite, but the buffer that it creates is structurally identical.

when the address (pointers) of those element are not sequential?

The premise is faulty. The memory addresses of vector elements are contiguous. One object begins immediately after another.

Also, whether they are sequential or not doesn't matter. You can equally well iterate over a linked list even though those elements are not contiguous in memory.

OutputIterator ... But when you shift(add) it more then once between accessing them, then there is a gap

This assumption is not true.

In particular case of std::back_insert_iterator, the documentation says:

std::back_insert_iterator<Container>::operator++

Does nothing.

| improve this answer | |

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