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I want to know - are there any guidelines about syntax of C++ (non-)member functions, that allows me to understand (without comments, if possible) the ownership policy of its arguments and return value. By ownership I mean, that the owner is responsible for the destruction of the owned object.

I distinguish the following rules about arguments:

  • take ownership
  • don't take ownership
  • share

and about return value:

  • release ('return by value' is in this group)
  • don't release
  • share

For example, passing object by reference doesn't take it's ownership:

void func(object & obj) { ... }

Such guidelines may use standard constructions like unique_ptr, shared_ptr, etc. If there are no such guidelines, then the examples of possible syntax misunderstandings are welcome too.

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3  
I don't understand the question. You know about unique_ptr, shared_ptr and probably about weak_ptr too - the semantics of these are well documented and enable you to distinguish all the cases you mentioned. –  Björn Pollex Nov 3 '11 at 9:32
    
Do you mean, given a function signature involving pointers, how can you tell who owns the memory and therefore who is responsible for allocation/cleanup? –  flipchart Nov 3 '11 at 9:34
    
@BjörnPollex "Such guidelines may use ..." - I mean, that if there is no another way to express the ownership rule in syntax, then such constructions may be used. For example, I don't know another simple way to share the ownership except as use shared_ptr. The more trivial syntax - the better guideline. Thanks for comment. –  abyss.7 Nov 3 '11 at 9:43
    
@flipchart: no, the questioner means, "how can I invent a style guide which, provided everyone follows it, allows them to tell who owns memory etc?". –  Steve Jessop Nov 3 '11 at 9:45
    
@flipchart I mean: "is there a way to compose a function signature involving pointers so that the other developer can "tell who owns the memory and therefore who is responsible for allocation/cleanup". Steve Jessop is correct too - I mean the same thing. –  abyss.7 Nov 3 '11 at 9:46

3 Answers 3

I just use this syntax for parameters where needed:

example constructor declaration:

t_array(const t_ownership_policy::t_take& policy, THESpecialType* const arg);

In use at the callsite:

t_array array(t_ownership_policy::Take, THESpecialTypeCreate(...));

Where t_ownership_policy::t_take is just a dummy overload disambiguator typename.

In this system, there are multiple policies, each with separate types. I favored unique types per policy because a typed enumeration (for example) does not support initialization as easily, and it's too easy to pass an unsupported policy to a function or constructor. 'Polymorphic' policies can reduce symbol count, but it's a pain because it pushes error detection to runtime.

For 'returning':

void func(t_container<t_type>& outValue);

Where t_container is whichever pointer container type you choose. Then the container type already implements the necessary boilerplate. This container may be something like a shared_ptr, or some specialization you have written.

and for more elaborate types, i'll often use syntax like so:

void func(t_special_container& outValue) {
  ...
  outValue.take(ptr);
  - or -
  outValue.copy(ptr);
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If I understand you, then Boost call_traits might be what you are looking for:

The example (copied from the docs goes):

template <class T>
struct contained
{
   // define our typedefs first, arrays are stored by value
   // so value_type is not the same as result_type:
   typedef typename boost::call_traits<T>::param_type       param_type;
   typedef typename boost::call_traits<T>::reference        reference;
   typedef typename boost::call_traits<T>::const_reference  const_reference;
   typedef T                                                value_type;
   typedef typename boost::call_traits<T>::value_type       result_type;

   // stored value:
   value_type v_;

   // constructors:
   contained() {}
   contained(param_type p) : v_(p){}
   // return byval:
   result_type value() { return v_; }
   // return by_ref:
   reference get() { return v_; }
   const_reference const_get()const { return v_; }
   // pass value:
   void call(param_type p){}

};

Not much clearer than param_type, reference_type and return_type to indicate what is meant.

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I can't see why using smart pointers doesn't suffice. I can't think of anything else that I wouldn't categorize as code smell. Using smart pointers over raw pointers makes ownership and responsebilities perfectly clear:

  • auto_ptr/unique_ptr - single owner, ownership is transferred
  • shared_ptr - multiple owners, ownership may be transferred
  • scoped_ptr - single owner, ownership cannot be transferred
  • weak_ptr - observer (but shared_ptr may be created from weak_ptr)

I think that these suffice to clearly show the responsibilities, e.g.

void func(std::auto_ptr<Class> input) {...} // func() takes ownership of input
void func(boost::shared_ptr<Class> input) {...} // func() and caller share ownership
std::auto_ptr<Class> func() {...} // caller takes ownership of returned value
boost::shared_ptr<Class> func() {...} // func() and caller shares ownership of returned object
boost::weak_ptr<Class> func() {...} // func() owns created object, but caller may observe it

As you mention, references are also great in this sense. Note if there's a need to free the pointers using some custom mechanism, shared_ptr and unique_ptr supports custom deleters. auto_ptr does not have this capability.

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1  
What possibilities are you missing? The common case is when writing the boilerplate abstraction layer for anything that does not go through new, new[], delete, delete[], but has its own allocator or reference counting scheme -- commonly when incorporating external APIs with your codebase. –  justin Nov 3 '11 at 10:50
3  
@Justin: If it has its own allocator, then unique_ptr and shared_ptr can be given custom deleters to deal with that. If it has its own reference counting scheme, then boost::intrusive_ptr is a good choice - it handles the smart-pointer semantics, and you only have to take care of the reference counting itself. –  Mike Seymour Nov 3 '11 at 11:30
    
@MikeSeymour: I've updated the answer with a remark about custom deleters, thx. –  larsm Nov 3 '11 at 12:17
    
@Mike Seymour +1 all valid points. however, I still don't see 100% coverage using these utilities, and the OP's question is still valid because these types are not always sufficient. some more examples: 1) in the case of the special allocator, the object may need to to reference its allocator (or some other context). 2) abstraction and exporting of implementations to reduce compile times 3) boost or more modern standard features aren't an option for everybody 4) some resources are best served by further specializations/features these types do not offer. –  justin Nov 3 '11 at 12:24

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