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In The C++ programming language Edition 4 there is an example of a vector implementation, see relevant code at the end of the message.

uninitialized_move() initializes new T objects into the new memory area by moving them from the old memory area. Then it calls the destructor on the original T object, the moved-from object. Why is the destructor call necessary in this case?

Here is my incomplete understanding: moving an object means that the ownership of the resources owned by the moved-from object are transferred to the moved-to object. The remainings in the moved-from object are some possible members of build-in types that do not need to be destroyed, they will be deallocated when the the vector_base b goes out of scope (inside reserve(), after the swap() call). All pointers in the moved-from object are to be put to nullptr or some mechanism is employed to drop ownership of moved-from object on those resources so that we are safe, then why call the destructor on a depleted object when the "vector_base b" destructor will anyway deallocate the memory after the swap is done?

I understand the need to explicitly call the destructor in the cases when it must be called because we have something to destruct (e.g. drop elements) but I fail to see its meaning after the std::move + deallocation of vector_base. I read some texts on the net and I'm seeing the destructor call of the moved-from object as an signal (to whom or what?) that the lifetime of the object is over.

Please clarify to me what meaningful work remains to be done by the destructor? Thank you!

The below code snipped is from here

template<typename T, typename A>
void vector<T,A>::reserve(size_type newalloc)
    if (newalloc<=capacity()) return;                   // never decrease allocation
    vector_base<T,A> b {vb.alloc,size(),newalloc-size()};   // get new space
    uninitialized_move(vb.elem,vb.elem+size(),b.elem);  // move elements
    swap(vb,b);                                 // install new base 
} // implicitly release old space

template<typename In, typename Out>
Out uninitialized_move(In b, In e, Out oo)
    using T = Value_type<Out>;      // assume suitably defined type function (_tour4.iteratortraits_, _meta.type.traits_)
    for (; b!=e; ++b,++oo) {
        new(static_cast<void*>(&*oo)) T{move(*b)};  // move construct
        b->~T();                                // destroy
    return oo;       
share|improve this question
This is a generic implementation, you don't even now if T{move(*b)} calls a move-constructor. – dyp Dec 14 '13 at 22:38
Don't think about moving too much. To first approximation, moving is just like copying, and the world still plays by the same rules. – Kerrek SB Dec 14 '13 at 22:45
:-) but moving is very important exactly because it is not copying, which is too expensive to be done in some cases, so I have to think about it as different from copy. With copy I can decide to drop the original or not, with move I kind of say "I am now the new owner of your belongings and you are depleted" – cvomake Dec 14 '13 at 22:53

1 Answer 1

up vote 7 down vote accepted

Moving from an object just means that the moved-from object might donate its guts to live on in another live object shortly before it is [probably] going to die. Note, however, that just because an object donated its guts that the object isn't dead! In fact, it may be revived by another donating object and live of that object's guts.

Also, it is important to understand that move construction or move assignment can actually be copies! In fact, they will be copies if the type being moved happens to be a pre-C++11 type with a copy constructor or a copy assignment. Even if a class has a move constructor or a move assignment it may choose that it can't move its guts to the new object, e.g., because the allocators mismatch.

In any case, a moved from object may still have resources or need to record statistics or whatever. To get rid of the object it needs to be destroyed. Depending on the class's contracts it may even have a defined state after being moved from and could be put to new use without any further ado.

share|improve this answer
Now that makes more sense ;) Maybe you could think of it as a living donation of a kidney. Not all guts are transplanted, and the donator might still live after the operation. – dyp Dec 14 '13 at 22:46
I have to admit that this brings new perspectives to my question. Still, the fact that the moved-from object might still have resources is a bit odd as this would mean the the move constructor does not keep the invariants of the class, or what kind of resources are you referring to? – cvomake Dec 14 '13 at 23:08
@cvomake: A copy is a valid move construction as long as the move doesn't guarantee that pointers or references into the old object stay valid as long as the new object stays valid. A move does not guarantee that any resources are transferred. It merely indicates that it is save to transfer resources and, thus, many classes will aim at rather transferring than copying resources upon moves. – Dietmar Kühl Dec 14 '13 at 23:32
moved object is like zombie, you still need kill it :) – Yankes Dec 15 '13 at 1:28
@DyP: Your statement is one I have been trying to discredit for years now. A moved-from object must still have all of its invariants intact. The only thing a client of a moved-from object can count on is that the moved-from object is in a valid (invariants intact) but unspecified state. Now if you are the author of this class, you can define its invariants any way you want. Maybe your class has an invariant that amounts to a moved-from value can only be destructed or assigned to. – Howard Hinnant Dec 15 '13 at 1:44

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