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I am trying to make a copy of a vector of string and append it to the end of its original vector, i.e. duplicating its contents. Example:

 Input : vector<string> s = {"abc", "def"}
 Output: vector<string> s = {"abc", "def", "abc", "def"}

I was using the insert method, i.e.

s.insert(s.end(), s.begin(), s.end());

However, this exhibits compiler-dependent results. In, LLVM clang, it gave me the expected answer.

With GCC it gave me

 Output: vector<string> s = {"abc", "def", "", ""}

I am wondering why this happens and what's the safest way to achieve this vector duplication goal?

Here is the ideone.com link for the program above: http://ideone.com/40CH8q

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It seems like UB if the iterators are invalid. Call reserve to guarantee noninvalidation. –  Kerrek SB Feb 15 at 19:55
Which version of g++ are you using? Using g++ 4.8.1, I get the correct output. –  user3264405 Feb 15 at 19:56
I was using the same g++4.8.1. I've attached a link to the online compiler to show the problem. –  spacepure Feb 15 at 20:02
@KerrekSB Is this really guaranteed? I thought that any insertion or deletion invalidates the iterators (that means there is not any guarantee that they are still valid, although they can be) –  leemes Feb 15 at 20:04
@Ali: Interesting; I can't see anything obviously UB about it. You're exploiting the fact that the vector's storage is contiguous... –  Kerrek SB Feb 16 at 0:29

4 Answers 4

Although it can possibly be done with iterators, a safe alternative is to avoid them:

size_t size = v.size();  // Of course we shouldn't access .size() in the loop...
v.reserve(size * 2);     // Preallocation. Thanks @Ali for this performance hint
for (size_t i = 0; i < size; ++i)

In general, working with iterators while also modifying the data structure (not only its elements) is dangerous; you should read carefully when iterators are invalidated and when it's safe to reuse old iterators after a modification. Thus, it sometimes makes sense to use the "old" method to iterate through a random-access sequence: using an index variable.

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Just checked and answered there; thank you for your hint, it's indeed a good idea in general to force pre-allocation if you know how many insertions will follow for sure. –  leemes Feb 15 at 23:42
How do you see it done with iterators? –  Andrey Chernyakhovskiy Feb 16 at 1:04

As others have already pointed out, you need to make sure by calling vector::reserve() that the vector doesn't get reallocated during insertion. (It is also a good idea to call reserve if you chose to put the elements with push_back() into your vector.)

Then there is still the iterator invalidation issue (as detailed under vector::insert()) but the code below, as far as I know, bypasses that:

#include <algorithm>
#include <iostream>
#include <iterator>
#include <string>
#include <vector>

using namespace std;

int main() {

  vector<string> s{"abc", "def"};

  auto size = s.size();

  s.reserve(2*size); // <-- This one is essential to ensure
                     //     no reallocation during insertion

  const string* first = s.data(); // using pointer, instead of iterator

  copy(first, first+size, back_inserter(s));

  for (const auto& e : s)
    cout << e << '\t';

  cout << endl;
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From cppreference.com: "The past-the-end iterator is also invalidated." <-- That's the problem. If I understand it correctly, it doesn't make a difference if you write s.end() or s.begin() + s.size(); both are "past-the-end iterators". The only bypass would be to treat the first or last element different, also introducing a special case for empty vectors. In my opinion, it's not worth the effort since it's less readable than using plain old index access. –  leemes Feb 15 at 23:41
@leemes Thanks for checking. However, note that s.data() yields a pointer, not an iterator. So s.data() + s.size() is not equivalent to s.end(). –  Ali Feb 15 at 23:45
Oh, I read your code too fast. In this case it might indeed work. –  leemes Feb 15 at 23:50
@leemes Yeah, that often happens to me too. :( Updated the code, made the type explicit and also added a comment. Hopefully, the next fast reader won't miss the point(er). –  Ali Feb 15 at 23:58

As already stated, it seems all you need to do is make a call to reserve:

sv.reserve(sv.size() * 2);

This is because if a reallocation occurs, the iterators are invalidated. You can check this for yourself:

std::cout << sv.capacity() << "\n"; // 2

The new size will be bigger than the capacity so a reallocation occurs.

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As far as I understand it, the end iterator might still be invalidated. –  Kit Fisto Feb 15 at 20:04
@Kit Maybe that's only for push_back. But I'm no expert. –  user1508519 Feb 15 at 20:10
Unfortunately, the end iterator is invalidated by any insert, even at the end, even if there's no reallocation. That's because it's after the insertion point. So although I don't think there's any serious reason why it shouldn't have defined behavior, using the end iterator to define the range that gets inserted is not (AFAIK) defined behavior. –  Steve Jessop Feb 15 at 21:46
@SteveJessop Please check my answer. Does that invoke UB? –  Ali Feb 15 at 23:03
@Ali: not sure. According to the standard the pointer first+size is invalidated, but you'd think that just means it can't be used to access an element any more (not that it could before, being an off-the-end pointer). Certainly in practice, being "invalidated" from the POV of the vector can't magically make the pointer no longer equality-comparable with other pointers :-) –  Steve Jessop Feb 16 at 11:47

This can be done this way too

vector<string> data = {"abc", "def"}; // Input String Vector
int len = data.size();
for(int i = 0; i < len; i++)
    data.push_back(data[i]); // Making Copy of String Vector

vector<string> data = {"abc", "def", "abc", "def"};
//Resultant String Vector
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