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The TR1 has introduced shared_ptr, weak_ptr, scoped_ptr and unique_ptr et al.

I would like to know the various conversion/type-promotion rules between these types.

For example what occurs when a scoped_ptr is assigned to a shared_ptr? Are such conversion possible/meaningful and what are some use-cases for such conversions?

(Is there a table in the specifiction?)

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3 Answers 3

First, a couple of corrections to your question:

  • scoped_ptr is a part of Boost and is not included in either C++ TR1 or C++0x (it's expected that in C++0x unique_ptr can be used where scoped_ptr has been traditionally used).

  • unique_ptr is not a part of C++ TR1; it is a part of C++0x (since it relies on rvalue references and move semantics, which are only available in C++0x).

To answer your question: shared_ptr and weak_ptr go hand in hand. An object owned by a shared_ptr can also be referenced by a weak_ptr. They are complementary.

A unique_ptr has sole ownership of the object it manages; no one else can have ownership of the object. This is the opposite of the ownership semantics of shared_ptr: with a unique_ptr, you have unshared unique ownership; with a shared_ptr you have shared, non-unique ownership.

You can construct a shared_ptr from a unique_ptr; when you do this, the unique_ptr loses ownership of the object. This works because you always know that a given unique_ptr is always the only owner of an object, so it is capable of releasing that ownership.

Once an object is owned by a shared_ptr, you can't release ownership of the object because there's no guarantee that a given shared_ptr is the sole owner of the object.

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@sonicoder: A unique_ptr is noncopyable, just as scoped_ptr is noncopyable. The semantics of unique_ptr and scoped_ptr are obviously not identical since a unique_ptr can be moved, but they are similar and there are very few cases where you would use a scoped_ptr but a unique_ptr would be undesirable. –  James McNellis Nov 21 '10 at 9:33

Given two classes A and B (which might be smart pointer types), there are four main ways to convert an instance of type B to type A:

  • A is an accessible base-class object of B (e.g. B is publicly derived from A), and the conversion can slice or simply adjust the type of a reference or pointer. (intentional strike-through).

  • A has an accessible constructor taking a B.

  • B has an accessible conversion operator producing an A.

  • There exists some function that takes a B and produces an A, and you're calling that function.

For smart pointers inheritance is not used to facilitate conversion, because inheritance allows for incorrect conversions; hence strike-through above. For example, if SmartPtr<Derived> inherited publicly from SmartPtr<Base>, then one would be able to do SmartPtr<Base>& spBase = spDerived;, and then e.g. spBase = spOtherDerived, which would be rather problematic... At a suitably high level of abstraction this is essentially the same problem as for const for pointer conversions; see FAQ item 18.17 "Why am I getting an error converting a Foo** → Foo const**?".

So, smart pointer conversions are generally expressed via the last three bullet points, namely constructors, conversion operators and named conversion functions.

Essentially there are three smart pointers in C++0x, disregarding the deprecated auto_ptr:

  • std::unique_ptr for single objects.

  • std::unique_ptr for arrays.

  • std::shared_ptr for single objects.

unique_ptr expresses ownership transfer, as the old auto_ptr did and does. But auto_ptr did not support arrays. unique_ptr does, and that affects possible conversions.

For single objects, unique_ptr supports the conversions that corresponding raw pointers does, via constructors. It has a templated constructor taking a unique_ptr of other type. See e.g. C++0x draft N3126 §

But, for arrays that would be just as dangerous as with raw pointers! And so for arrays unique_ptr does not offer base/derived conversion. See e.g. C++0x draft N3126 §

Since unique_ptr expresses ownership transfer while shared_ptr expressed shared ownership there can be no safe general conversion from shared_ptr to unique_ptr. However, the other way, the Boost shared_ptr has a constructor taking auto_ptr, and the C++0x shared_ptr retains this (also has it) and naturally adds a constructor taking unique_ptr. See C++0x draft N3126 §

shared_ptr provides base/derived conversions via constructors and via free functions that conceptually implement "casts". Essentially this means that shared_ptr is pretty dangerous to use directly for arrays of class type objects. For that use, wrap it.

Converting from shared_ptr to unique_ptr is, as mentioned, not supported as a general operation. Because shared ownership is not directly compatible with ownership transfer. However, disregarding complications wrt. thread safety, shared_ptr::unique tells you whether there is a single owner (namely your instance), and then, if you have the requisite knowledge of how the initial shared_ptr was constructed, you can use the free function get_deleter to get a pointer to the deleter function, and do some low level shenanigans. If you understand completely what I'm talking about here, then fine, good. If not, then it's best that I don't give more details, because this is a very very special case and it requires utmost care and that you Really Know What You're Doing™. ;-)

Well, that's about it. I'm not discussing weak_ptr, since it's just part of the shared_ptr functionality. But hopefully the above is what you're asking about.

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  1. scoped_ptr AFAIK is not part of TR1 (Correct me if I wrong). Generally boost's scoped_ptr can't transfer ownership at all. Once you assigned pointer to it, you can't release it.
  2. unique_ptr can transfer ownership only using std::move so it does not transfer ownership as well.
  3. shared_ptr can't release ownership as other pointers may shared it with. It can be converted to weak_ptr. If you try to convert it from weak_ptr and the object was released it would throw.
  4. weak_ptr can be created from shared_ptr, when converted to shared_ptr it may throw if the object no longer exists.
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