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I don't know why the destruction of an object in vector is called at the following point of time.

class Something
{
public:
    Something() {}
    ~Something()    { cout << "destruction called" << endl; }
};

int main()
{
    std::vector<Something> vec;
    Something sth1 = Something();   
    Something sth2 = Something();
    vec.push_back(sth1);
    vec.push_back(sth2);
    vec.clear();
}

After I push sth2, destruction for sth1 is called. Why? Shouldn't sth1 be kept in vec[0]?

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3 Answers 3

up vote 10 down vote accepted

Because the vector has to resize its capacity to be able to store two elements instead of one. It allocates a new buffer, it copies the old buffer to the new one, removes the old buffer, and then adds the new object.

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Then what should I do if I want sth1 to be stored in vector until I call clear(). I know reserve() might help, but what if I don't know the exact capacity? –  ChanDon Mar 8 '11 at 2:18
1  
@CDBean: You can't have the actual sth1 object stored in the vector no matter what you do; the vector will always hold on to a copy one way or the other. As I mention in my answer, push_back() creates a copy to begin with. You could switch to using a vector<Something*> if you really want; then only pointers to the original object are being stored (but you have to be careful that they remain valid throughout the lifetime of the vector) –  Cameron Mar 8 '11 at 2:26
    
@CDBean: You can't, and I don't see why you'd want to. (Copies are fine. C++0x adds moves, too.) Why is what's going on bad? If you want to avoid copies, use a smart pointer like unique_ptr or shared_ptr. (Not auto_ptr.) –  GManNickG Mar 8 '11 at 2:57

The vector allocates memory (as a contiguous block, i.e. an array) on the fly to hold the objects you put into it. Since it doesn't know in advance how big it will grow to, it grows its capacity gradually as you add more elements to it.

Each time it has to grow to fit a new element, it has to allocate a new array big enough to store everything (typically twice the size as the old array to avoid having to resize too often); then it has to copy all the elements from the old array to the new one. The old array is then freed, destroying the objects it contains.

vec[0] will contain an object exactly like sth1, just not the same object (it will be a copy that was created using the copy constructor during the resize of the vector).

Also note that push_back() always copies the element being pushed in (it doesn't keep a reference); this allows the objects it holds to persist in the vector past their lifetime on the stack. So at the end of main(), there will be four calls to the destructor: one for each of the two objects in the vector, and one each for sth1 and sth2 as they are popped off the stack.

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1) Something sth1 = Something();
2) Something sth2 = Something();
3) vec.push_back(sth1);
4) vec.push_back(sth2);
5) vec.clear(); 

At 1) you're creating sth1 on the stack - it's lifetime will be until the stack frame is destroyed as main() exits. The compiler is permitted (Standard 12.8.15) to elide the assignment to make the construction equivalent to:

Something sth1;

But, the compiler is also allowed to follow your code more mindlessly and potentially inefficiently:

1a) create a temporary Something()
1a) copy-construct sth1 on the stack, lifetime as per main(), copying the value of the temporary
1c) destroy the temporary

Summary: don't bother with the assignment: unlike say C# or Java, objects are constructed implicitly in C++.

At 3) - vec.push_back(sth1) can be expected to allocate some memory on the heap, then copy-construct an object therein with the same value as sth1. Note that this is not sth1 itself, but a copy of the value of sth1 at the time the push_back is performed. Updates to these copies, and updates to sth1 and sth2 are then independent.

At 4) the vector may or may not need to resize its heap memory to make space for a copy of sth1: if it does so, then the existing value at [0] - which was copy-constructed from sth1 but is not actually sth1, would be copied to the new memory area then the destructor would be called in the about-to-be-released memory area.

At 5) the copies of sth1 and sth2 are destroyed

After 5, sth1 and sth2 themselves go out of scope as main exits, and their destructors are invoked.

If you want to see this happening, I suggest you add better trace to your class:

struct Something
{
    Something() { std::cout << "Something(this " << (void*)this << ")\n"; }
    ~Something() { std::cout << "~Something(this " << (void*)this << ")\n"; }
    Something(const Something& rhs)
    { std::cout << "Something(this " << (void*)this
                << ", rhs " << (void*)rhs << ")\n"; }
    Something& operator=(const Something& rhs)
    { std::cout << "operator=(this " << (void*)this
                << ") = " << (void*)rhs << '\n'; }
};

You can also print (void*)&vec[0] after each of the push_backs.

Taking a step back from your attempt and looking at whether/how to eliminate copying:

  • you can create a vector<Something*> then push_back(&sth1) and &sth2
    • this is fine as long as the lifetimes of sth1 and sth2 (which is that of the surrounding scope - here the lifetime of main() itself) span the times at which the pointers may be dereferenced
    • following the pointer to the actual sth1 and sth2 objects - rather than copies made at the time push_back() is used - means that any updates to sth1 and sth2 will be visible via the pointers, and updates through the pointers actually affect sth1 and sth2

If you want the lifetime of the objects known to the vector to live beyond that implied by the scope surrounding your stack-based sth1 and sth2, you can:

  • allocate sth1 and sth2 on the heap ala Something* sth1 = new Something();
  • keep pointers in the vector
    • if you don't use smart pointers (e.g. boost::shared_pointer), then you'll need to delete each pointer before removing it from the vector or clearing the vector (to avoid memory leaks).
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I'm pretty sure that initialization during declaration always uses the copy-constructor (not the assignment operator) but your point about possible inefficiencies still stands –  Cameron Mar 8 '11 at 2:40
    
@Cameron: nope... had a discussion about it on here a week or so ago and consulted the Standard... compiler's free to elide but not required to. –  Tony D Mar 8 '11 at 2:48
    
@Cameron: it's 12.8.15 if you're curious... wording is "is permitted" rather than required/shall etc.. –  Tony D Mar 8 '11 at 2:57
    
You're right, here the compiler is allowed to optimize away the temporary object, but if it didn't, the copy constructor would be called, not the assignment operator (12.6.1) –  Cameron Mar 8 '11 at 3:23
    
@Cameron: yikes - silly me :-). Thanks! –  Tony D Mar 8 '11 at 3:25

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