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I want to explicitly destroy an object (call the destructor on it and all its fields), but it may happen that I still hold some pointers to the object in question. Thus, I don't want to yet free the memory; instead I would like to leave a sort of a flag "I am a destroyed object".

I came with an idea of the following approach:

class BaseClass { //all objects in question derive from this class
    BaseClass() : destroyed(false) {}
    virtual ~BaseClass() {}
    bool destroyed;
    bool isDestroyed() { return destroyed; }
    void destroy() {
        this->~BaseClass(); //this will call the virtual destructor of a derivative class
        new(this) BaseClass();

When destroy is called, I basically destroy the whatever object I had (perhaps a derivative one) and create a new "zombie" one in that very same place. As a result I hope to achieve:

  • Any other pointer ptr previously pointing to this object can still call ptr->isDestroyed() to verify its existence.
  • I am aware that if I don't check the flag of the zombie and try to access fields belonging to any derived object, bad things may happen
  • I am aware that the zombie object still consumes as much memory as the destroyed object (as it may be a derivative of BaseClass)
  • I still have to free memory of the destroyed object. I hope however, that calling delete is still correct?


Are there any other problems which I should consider when using the above pattern?

Will calling delete on the zombie object correctly free whole memory consumed by the previous (normal) object?

While I appreciate your input on how to do it differently, and I may be inclined to do it your way - I would still like to understand all the risks that the above code poses.

share|improve this question
It seems you are looking for std::shared_ptr. – Joachim Pileborg Nov 10 '12 at 12:15
This is a bad idea. Use smart pointers. – Loki Astari Nov 10 '12 at 12:20
new(this) BaseClass(); - I'm pretty sure all bets are off after this if this was "originally of a derived type". – Mat Nov 10 '12 at 12:21
@CygnusX1 - This is some of the stupidest and idiotic code I have seen for a long time. What the hell are you trying to achieve?! – Ed Heal Nov 10 '12 at 13:10
@CygnusX1, surprise - that's exactly how weak_ptr works. – Griwes Nov 10 '12 at 13:34
up vote 5 down vote accepted

You got some nasty comments to your question. Now I don't think they are deserved although there may be better ways to do what you want. I understand where you are coming from but actually you are using the destructor the same way you would use the reset function you refuse to write. Actually you gain nothing from calling a destructor since calling a distructor has nothing to do with actually deleting or resetting anything unless you actually write the code to do it within the destructor.

As to your question about the placement new:

As you may know already the placement new doesn't allocate any memory so calling it will just create the object in the same place. I understand that is exactly what you want but it's just not ncessary. Since you don't call delete on your object just destroy, you can set destroyed to true without initializing the class.

To sum it up:

  1. If you use the destructor as a regular virtual function you gain nothing. Don't do it since you can get into trouble if a destructor is called twice
  2. A call to a placement new will not allocate memory and just perform needless initialization. You can just set destroyed to true.

To do what you want to do correctly and gain the benefits of destructors, you should overload the new and delete operators of your classes and use the normal destruction mechanism. You can then opt not to release the memory but mark it as invalid or maybe release most of the memory but leave the pointer pointing to some flags.


Following the comments I decided to sum up all the risks I see and the risks that others have pointed out:

  1. Accessing invalid pointer in a multi-threaded environment: Using your method a class may be accessed after the destructor has run but before the destroyed flag is set (As to your question in one of the comments - shared_ptr is for most purposes thread safe)
  2. Relaying on a behavior you don't totally control: Your method relies on the way destructors auto call the destructors of other members which are not dynamically allocated: This means that you still have to release dynamically allocates memory specifically, You have no control on how exactly this is implemented, You have no control on the order in which other destructors are called.
  3. Relaying on a behavior you don't totally control (Point 2): You are relaying on the way a compiler implements the part of the destructor which calls other destructors you have no way in telling whether your code will be portable or even how will it handle calling it twice.
  4. Destructors may be called twice: Depending on your implementation this may cause memory leaks or heap corruption unless you guard against releasing the same memory twice. You claim you guard against that case by calling the placement new - However in a multi-threading environment this is not guaranteed further more you assume that all memory allocations are done by the default constructor - depending on your specific implementation this may or may not be true.
  5. You are going against the better judgment of everyone that answered your question or commented on it - You may be onto something genius but most probably you are just shooting yourself in the leg by limiting your implementation to a small subset of situations where it will work correctly. It is like when you use the wrong screwdriver you will eventually end up damaging the screw. In the same way using a language construct in a way it was not intended to be used may end up with a buggy program - Destructors are intended to be called from delete and from the code generated by the compiler to clear the stack. Using it directly is not wise.

And I repeat my suggestion - overload delete and new for what you want

share|improve this answer
"Actually you gain nothing from calling a destructor since calling a distructor has nothing to do with actually deleting or reseting anything unless you actually write the code to do it within the destructor." -- Note that a destructor automatically calls the destructors of all the class members. Using the destructor over implementing reset() myself saves me the trouble of iterating over all the members and calling reset() myself (provided the members have such function). – CygnusX1 Nov 17 '12 at 7:40
@CygnusX1 You are right but automatic destruction is only for class variables that are not allocated dynamically. Your approach is very risky in my opinion - You rely on automatic behavior that is correct only for part of your class data. Also since for those variables nothing is released there is little gain. However I see how this maight help you - Just remember to guard against double calls to destructors or trying to release already released memory. – Sebastian Cabot Nov 17 '12 at 9:07
Good points. However, I don't see (yet) any additional risk of double-destructing or double-releasing when using the above construct (except for multi-threading hazards). Even if destroy() is called twice, it should still work fine, I think? This is because when I destroy an object manually I immediately create a new one in its place. Only calling delete twice at the same pointer could lead to an error, but that would be wrong even without the above construct. – CygnusX1 Nov 17 '12 at 11:06
@CygnusX1 - I tried to sum up all the risks I and others see. Edited the answer – Sebastian Cabot Nov 17 '12 at 15:38
Thank you for your time summing it all up, although I don't see the some of the problems as real problems. – CygnusX1 Nov 17 '12 at 20:04

There is a suggestion of using smart pointers. In fact - I am doing that, but my references are circular. I could use some fully-fledged garbage collectors, but since I know myself where (and when!) circle chains can be broken, I want to take advantage of that myself.

Then you can explicitly null-ify (reset if you are using shared_ptr) one of the circular smart pointers and break the cycle.

Alternatively, if you know where the cycles will be in advance, you should also be able to avoid them in advance using weak_ptr in place of some of the shared_ptrs.

--- EDIT ---

If an object referenced by weak pointers only would merely get flagged as "invalid" and release control over all its contained pointers (is this sentence clear?), I would be happy.

Then weak_ptr::expired should make you happy :)

share|improve this answer
Explicitly nullify smart pointers - In my case, it means going through all my classes, implementing reset method for each, which will nullify all smart pointers of each class. Together with marking that the object is no longer usable. Yes, I can do this, but that's the job that destructors were invented for in the first place. – CygnusX1 Nov 10 '12 at 13:07
@CygnusX1 So you are using your own smart pointer? No you don't need to "nullify all smart pointers of each class". You just need to null-ify the one that keeps the cycle alive. And no, that's not "the job that destructors were invented for in the first place" - you are not destroying the smart pointer, you are just changing its state. – Branko Dimitrijevic Nov 10 '12 at 13:13
I think I worded it incorrectly. What I meant is - I would have to implement reset() member function which would reset all member pointers of that object (and not all pointers everywhere). I want to break cycles by making the nodes "weak" and not by making edges "weak". – CygnusX1 Nov 10 '12 at 13:26
@CygnusX1 So, what's the problem? You'll need to invalidate one of the in-cycle pointers somehow. Whether you invalidate it in a member function or somewhere else, you'll have to do it. Whether you do it by null-ifying the pointer or by zombifying the object it points to is logically the same. I think you are approaching this whole thing from the wrong angle - if you know where the cycle is, then you know which pointer to null-ify to break it, so why can't you just do it? – Branko Dimitrijevic Nov 10 '12 at 13:34
@CygnusX1 Well, you said "I know myself where (and when!) circle chains can be broken", which kind of implied the opposite. OK, since you don't actually know that, hold a single "well-known" shared_ptr to the object and all the other pointers will be weak_ptr. When the time comes to free the object, just reset this one shared_ptr and all of the weak_ptrs will automatically expire (i.e. their weak_ptr::expired will return true). – Branko Dimitrijevic Nov 10 '12 at 13:43

As with everyone else, I recommend you should just use weak_ptr. But you asked why your approach doesn't work as well. There are some issue of elegant implementation and separation of concerns that your code walks all over, but I won't argue those. Instead, I'll just point out that your code is horribly not thread-safe.

Consider the following execution sequence of two threads of control:

// Thread One
if ( ! ptr -> isDestroyed() ) {     // Step One
    // ... interruption ...
    ptr -> something();             // Step Three

And the other:

// Thread Two
ptr -> destroy();                   // Step Two

By the time step 3 comes around, the pointer is no longer valid. Now it's possible to fix this by implementing lock() or similar, but now you've incurred the possibility of defects about not releasing locks. The reason that everyone is recommending weak_ptr is that this whole class of problems has been worked out both in the interface of the class and its implementations.

One issue remains. You seem to want a facility where you can kill an object at will. This is the tantamount to requiring that the only pointers to an object are weak ones, that no strong ones are present that would break when the object was manually deleted. (I'll stipulate that this isn't a bad idea, though I must say I don't know why it's not in your case.) You can get this by building on top of weak_ptr and shared_ptr. These classes are generic, so if you want to disallow shared_ptr access to BaseClass, then you can write a specialization for shared_ptr<BaseClass> that behaves differently. Hide one instance of shared_ptr<BaseClass> to prevent deletion and provide such pointers through a factory method under your control.

In this model the semantics of destroy() need attention. The first choice is whether you want synchronous or asynchronous operation. A synchronous destroy() would block until all external pointers are released and not allow the issuing of new ones. (I'll assume that copy constructors are already disabled on the pointer.) There are two kinds of asynchronous destroy(). The simpler of the two fails if there still exist external references. Calling unique() on the hidden shared_ptr() makes this an easy implementation. The more complicated one acts like an asynchronous I/O call, scheduling the destruction to happen at some point in the future, presumably as soon as all external references are gone. This function might be called mark_for_death() to reflect the semantics, since the object might or might not be destroyed at return time.

share|improve this answer
Good point! I haven't thought about thread safety. However, by using smart pointers I don't gain thread-safety either, do I? Any member function (be it destroy as above or reset as suggested) would have to be guarded in some way. If I change the behavior of shared_ptr this part of code would have to be guarded as well. – CygnusX1 Nov 17 '12 at 8:05
Putting a single guard system on a smart pointer rather than guards on each member function is indeed one of the reasons to use smart pointers. It's the strongest reason from the perspective of design patterns, since it separates concerns well. The thread safety of shared_ptr and weak_ptr has already been fully worked out. The only other concern on top of that is the semantics of destroy(); I've added a paragraph on that topic to my answer. – eh9 Nov 17 '12 at 14:58
Wish I could upvote your answer again.... – CygnusX1 Nov 17 '12 at 20:04

I would consider using one appropriate of the smart pointer patterns instead. Behavior of accessing a deleted object is still undefined and a 'zombie' flag won't really help. The memory that was associated with the object instance that was deleted could be immediately occupied by any other object created, thus accessing the zombie flag isn't an information you can trust.

IMHO the placement new operator

new(this) BaseClass();

used in your destroy() method won't really help. Depends a bit how this method is intended to be used. Instead of deleting derived objects or inside destructors of deleted objects. In the latter case the memory will be freed anyway.


According to your edit, wouldn't it be better to use the shared pointer/weak pointer idiom to solve the occurrence of circular references. I would consider these as a design flaw otherwise.

share|improve this answer
I am destroying the object, I am not deleting the underlying memory. Instead, I am reusing the memory myself to create a new object there. – CygnusX1 Nov 10 '12 at 12:29
Yes, I've seen that after writing the answer, it's suspect anyway. – πάντα ῥεῖ Nov 10 '12 at 12:35
It's suspect - I agree. That's why I want to know all the risks I am taking before committing myself to it. – CygnusX1 Nov 10 '12 at 12:38
I don't really understand your response from the "IMHO" part. I am never deleting any memory in the "destroy()" method, so no memory will be freed. weak_ptr is... weak... if I access an object through it, the object may not exist anymore. – CygnusX1 Nov 10 '12 at 13:01
@CygnusX1 have you considered... adding a flag? You can reset() whatever pointers it holds when that flag gets set. – R. Martinho Fernandes Nov 10 '12 at 13:32

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