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A question about boost::shared_ptr here:

I have 3 Classes.

A is some kind of Main class which is responsible to manage everything.

B is a class which just has functions to do some work.

Dispatcher is just a class which wraps around a seperate thread, which gets the work from Instaces of Bdone in this thread.

So it is kinda working like this: A has an instance of Dispatcher. Now on occassion A generates an instance of B and passes it to the dispatcher.

The important part is, that B needs to call A::callback() when it's done. This is why B gets a reference to A in it's constructor ( see code below )


class A : public boost::enable_shared_from_this<A>
    void sendB();
    void callback();
    Dispatcher m_Dispatcher;


class B
    B(boost::shared_ptr<A> ptr);
    boost::shared_ptr<A> m_PointerToA;
 /* Some other functions */


class Dispatcher
     void run();
     void dispatch(boost::shared_ptr<B> b);
     void doWork();
     boost::thread m_Thread;  


void A::sendB()
    boost::shared_ptr ptr_B;
    ptr_B.reset(new B(this->shared_from_this);


B::B(boost::shared_ptr<A> ptr) :
    : m_PointerToA(ptr)


int main()
     A instanceA;
          /* Do some other stuff */
     return 0;

So my question is:

Is it reasonable to use boost::shared_ptr for this purpose?

I am not sure if the shared_ptr is the right thing to go here. My problem is, that I don't know what happens exactly when I call the constructor from B and pass it the this pointer. Now according to shared_ptr I would assume that m_PointerToA takes ownership of A. But this would mean that when the work in the Dispatcher is done and my instance of B gets deleted it would also delete the reference to m_PointerToA which would actually mean it kills the object itself despite the fact there is an actual instance of A in the main loop.


Added some code and updated question itself to make it more clear.

share|improve this question
You don't want to use shared_ptr across thread boundaries. This is one place where the semantics of std::auto_ptr really shine; once you've passed the pointer to the other thread, you can't access it in the original thread. – James Kanze Mar 26 '12 at 12:29
boost::shared_ptr is actually thread safe, in the sense that you can rely on the reference counting to be in a safe state. – Ylisar Mar 26 '12 at 12:33
@JamesKanze But the pointer I pass is actually a this pointer. So actually I don't do anything with the "pointer" in particular. But of course some code in the instance from this is still running in the main thread. I actually just wanted to use the shared_ptr so I don't come in any troubles by losing references. I would have also no problem with using a raw pointer... – Toby Mar 26 '12 at 12:34
I have a couple of questions. You are newing your B instance in initClassB but how is that referenced? If you are storing it in A, how are you doing that? You are passing it to a thread you say, so is that being referenced solely from the that thread? The question is really about how you want A to die. Do you want it to go down with the other thread? As it stands the B is the sole owner of A, and it will die with B. In that case I would also recommend using an auto_ptr and it makes it very clear who owns the A instance. – Dennis Mar 26 '12 at 12:38
@Dennis Gonna update the question so it gets more clear ( I omitted some code when I first wrote it = – Toby Mar 26 '12 at 12:40
up vote 1 down vote accepted

Yes, it is okay to just copy/assign a shared_ptr, it will only increase the reference count.

In your example, shared_from_this() will create a (here: temporary) shared_ptr from the weak_ptr that is hold by this (ref count 1), so when you assign/copy-construct m_PointerToA, the reference count will increase temporarily to 2 before the ctor returns and the temporary object will be destroyed, decreasing the reference count to 1 again (the shared_ptr is "aware" of the one instance in your B object).

So, yes, if B is deleted, it will destroy A in this case (as the reference count drops to 0).

Your concern

This would mean if my Instance of B is deleted, it would also delete m_PointerToA which would also kill my instance of A . Of course my original instance of A is held elsewhere.

only shows that if you plan/need/intend to keep a pointer to the instance of A for further usage, you should do so with a shared_ptr as well instead of a raw pointer. If you have control of A's interface, the easiest way would be a named constructor like this:

class A : public boost::enable_shared_from_this<A> {
        static boost::shared_ptr<A> create();

        void initClassB();
        // ....
        A( const A & other );
        A& operator=( const A & rhs );


boost::shared_ptr<A> A::create() {
    return boost::shared_ptr<A>( new A() );

Then, even if your instance of B is deleted, the instance of A will still survive because the reference count of the shared_ptr is still (at least) 1.

share|improve this answer
Okay I see why your solution would really make sure that A will not be deleted because the reference count will at least be 1. But then I would like to know: Someone ( for example a main function or another class ) needs to call the A::create() method - so if instead of using your solution this main function would just create a normal instance of A I could lose it while B is getting deleted? So A would also get deleted despite the fact that there is an actual instance of that object? – Toby Mar 26 '12 at 13:28
Not sure what you mean by "despite the fact that there is an actual instance of that object". The shared_ptr will destroy the instance if the reference drops to 0. If there is only one shared_ptr to A in B, yes, destroying B will destroy that instance of A. If your are referring to A somewhere via a raw pointer, there is no way to prevent this. But that's why you should smart pointers consistently (don't use raw pointers to objects that are managed by smart pointers). – Johannes S. Mar 26 '12 at 13:58
With the example above, the main function would not be able to create a "normal" instance (raw pointer) of A because there is no constructor available/accessible (your compiler will report an error if you try). The only way to construct an instance of A is by calling A::create() – Johannes S. Mar 26 '12 at 13:59
I added main_example.cpp in the question to make it more clear. I just say, somewhere I get an actual instance of object A - now this means I would not use a create() method like you mentioned - resulting in the fact that my Ref Count could drop to 0 when B gets deleted? – Toby Mar 26 '12 at 14:09
Or let's ask my question in other words: If I derive my class A from boost::enable_shared_from_this<A> that doesnt implicitly make a ref count of 1? – Toby Mar 26 '12 at 14:10

There's nothing particular wrong with this design. However I would prefer to instead use boost::function<> & boost::bind. It gives you way better flexibility for the callback and doesn't tie B as tightly to A. Of course you still have to be vary of the usual threading caveats.

share|improve this answer
+1. Good advice. Also, if you have perfect control over the lifetime of your instances, you could simply store a reference to your A. If you don't need B to be assignable of course. – ereOn Mar 26 '12 at 12:58
Yeah I also thought about doing it a bit more generic, but in my first attempt I just wanted it to work. So there is no actualy problem with using the boost::shared_ptr? – Toby Mar 26 '12 at 13:11

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