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I understand auto_ptr has screwed up copy semantics and therefore is not safe for use in containers since copying one auto_ptr to another will make the source = NULL pointer (isn't this like move semantics anyway??). But then again, unique_ptr cannot be copied at all and can only transfer ownership. So, how is unique_ptr usable in containers and algorithms that need to use copy operations to copy and re-arrange elements?

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"how is unique_ptr usable in containers and algorithms that need to use copy operations" Not at all. But then again, many operations do not require copying. Re-arranging can be done via swap (and moves). – dyp Jul 13 '14 at 10:24
    
So, swap uses move semantics? – Tracer Jul 13 '14 at 10:29
    
The new Standard Library generic swap is based on a move construction and two move assignments. But unique_ptr also provides a specialized version of that generic algorithm. In any way, a movable type is swappable. – dyp Jul 13 '14 at 10:36
up vote 5 down vote accepted

There is an in-depth explanation of why auto_ptr is dangerous, while unique_ptr is not: N1856 : Why deprecate auto_ptr?

The main argument is that in generic code, something that has the syntax of a copy, should be a copy, not a move:

template <class It>
void sort(It first, It last)
{
    // ...
    value_type pivot_element = *mid_point;
    // ...
}

In the above example, the generic code is highly likely to have logic that demands that pivot_element and *mid_point be equivalent after the copy construction shown. This may or may not be generic code in the std::lib. It might be generic code you have written.

When value_type turns out to be a std::auto_ptr<T>, then the above code compiles, but the assumption that pivot_element == *mid_point fails. A run-time error follows.

When value_type turns out to be a std::unique_ptr<T>, then the above code fails at compile-time (because you can't copy a std::unique_ptr<T>). Thus use of std::unique_ptr<T> in preference to std::auto_ptr<T> effectively turns run time errors into compile-time errors.

Now it is also true that within the std::lib, algorithms such as sort have been respecified such that they are not allowed to copy value_type. So it actually is safe to sort a sequence of auto_ptr<T> now (using std::sort). However std::unique_ptr<T> completely replaces the functionality of auto_ptr<T>, and auto_ptr<T> is still dangerous to use in generic code that does use copying (unique_ptr<T> fails to compile when used in such generic code).

So unique_ptr is safer to use than auto_ptr because it refuses to compile when used with generic code that copies.

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They don't need to use copy operations anymore in the vast majority of cases. Move-only types like unique_ptr are first-class citizens. That's why move semantics is such a great improvement for both performance and correctness.

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