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I know that it's possible to say delete this in C++ whenever you allocated something with new, using traditional pointers. In fact, I also know that it's good practice IF you handle it carefully. Can I have an object say delete this if it's being held by an std::shared_ptr? And that ought to call the destructor, right? To give you an idea, I'm making a game where a ship can shoot missiles, and I'd like to have the missiles delete themselves.

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Having an object delete itself with delete this is not good practice. The fact that you have to handle doing it carefully is enough to show that. It's an error prone way to arrange lifetime management. – bames53 Apr 23 '12 at 3:06

4 Answers 4

up vote 11 down vote accepted

No, it's not safe, the lifetime of the object is determined by holders of shared_ptr, so the object itself cannot decide whether it wants to die or not. If you do that, you'll get double delete when last shared_ptr dies. The only solution I can offer is "rethink your design" (you probably don't need shared_ptr in the first place, and missiles probably could be values or pooled objects).

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For a missile to delete itself it must own itself, or at the very least, share ownership of itself with others. Since you say that there is a shared_ptr to the missile, I am assuming that you already have multiple objects sharing ownership of the missile.

It is possible for the missile to hold a shared_ptr to itself, and thus share in the ownership of itself. However this will always create a cyclic ownership pattern: For as long as the missile's shared_ptr data member refers to itself, the reference count can never drop to zero, and thus the missile is leaked.

You could have an external object or event tell the missile to delete itself but then I'm not sure what the point is. In order to tell the missile to delete itself, that communication should take place via a shared_ptr, and then the delete isn't really going to happen until that shared_ptr lets go of the missile.

Yes, it is possible. No, I don't think it is a good idea. It looks prone to memory leakage to me and doesn't actually add value. But for the curious, here is how you would do it:

#include <iostream>
#include <memory>

class missile
    : public std::enable_shared_from_this<missile>
    std::shared_ptr<missile> self_;

    ~missile() {std::cout << "~missile()\n";}

    void set_yourself()
        self_ = shared_from_this();
    void delete_yourself()
        if (self_)

int main()
        std::shared_ptr<missile> m = std::make_shared<missile>();
        std::weak_ptr<missile> wp = m;
        std::cout << "before first reset()\n";
        std::cout << "after first reset()\n";
        // missile leaked here
        m = wp.lock();
        std::cout << "before second reset()\n";
        m.reset();  // missile deleted here
        std::cout << "after second reset()\n";
    catch (const std::exception& e)
        std::cout << e.what() << '\n';
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I'm not sure if I should up vote. The solution is correct and novel, but the question is wrong. – deft_code Apr 23 '12 at 17:24
How is there a memory leak? The wp is not expired. You have exactly the same responsibility here as when dealing with raw pointers. With the bonus that you will not have the rug pulled out from under your feet if you happen to be using the missile while it deletes itself. – Emily L. Oct 4 '14 at 12:49
@EmilyL.: I said prone to memory leak. If something neglects to tell the missile to delete itself, then it leaks. This example demonstrates that by removing all external owners without calling delete_yourself. The example then re-establishing an external owner, tells the missile to now delete itself, and then gets deleted when the external owner relinquishes ownership. I.e. why not just have external owners then? A more common idiom is the for missile to only maintain a weak_ptr to itself, and hand out strong ownership to an external entity using that weak_ptr. – Howard Hinnant Oct 4 '14 at 17:08
@deft_code: My point was that it is possible, here's how, but this solution sucks. It is error prone because it creates an ownership cycle that must be broken at run time, else there will be a leak. – Howard Hinnant Oct 4 '14 at 17:10

I know I'm late to the show but I ran into wanting to do this myself just now and realized that it is "kind-of-possible" but you need to take care of a few things.

Howard's answer is on the right track but misses the mark as you shouldn't leave construction of the original shared_ptr to the client. This is what opens up the risk of memory leaks. Instead you should encapsulate the construction and only allow weak pointers.

Here is an example:

class Missile{
    Missile(...){ }; // No external construction allowed
    Missile(const Missile&) = delete; // Copying not allowed
    void operator = (const Missile&) = delete; // -||-

    std::shared_ptr<Missile> m_self;
    template<typename... Args>
    static MissilePtr makeMissile(Args... args){ 
        auto that = std::make_shared<Misile>(args...);
        that.m_self = that; // that holds a reference to itself (ref count = 2)
        return that; // 'that' is destroyed and ref-count reaches 1.

    void die(){


typedef std::weak_ptr<Missile> MissilePtr;

void useMissile(MissilePtr ptr){
    auto missile = ptr.lock(); // Now ptr cannot be deleted until missile goes out of scope
    missile->die(); // m_self looses the reference but 'missile' still holds a reference
    missile->whatever(); // Completely valid. Will not invoke UB
} // Exiting the scope will make the data in missile be deleted.

Calling die() will result in semantically the same effect as delete this with the added benefit that all MissilePtr that are referring to the deleted object will be expired. Also if any of the MissilePtr are used for accessing this then the deletion will be delayed until the temporary std::shared_ptr used for the access is destroyed saving you life-time headaches.

However you must make sure that you always keep at least one MissilePtr around and at some point call die() otherwise you will end up with a memory leak. Just like you would with a normal pointer.

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This question is quite old, but I had a similar issue (in this case a "listener" object that had to manage its own lifecycle while still being able to share weak pointers), and googling around did not provide a solution for me, so I am sharing the solution I found, assuming that:

  • The object manages it's own lifecycle, and hence will never share a share_ptr, but a weak_ptr (if you need shared_ptr's a similar solution + use_shared_from_this could do it).
  • It is a bad idea to break RAII, and hence we will not do it: what we adress here is the issue of having a shared_ptr owned by an object itself, as containing a member share_ptr leads to double call to the object destruction and normally a crash (or at least undefined behaviour), as the destructor is called twice (once at normal object destruction and a second one when destroying the self contained shared_ptr member).


#include <memory>
#include <stdio.h>

using std::shared_ptr;
using std::weak_ptr;

class A {
    struct D {
            bool deleted = false;
            void operator()(A *p) {
                printf("[deleter (%s)]\n", p, deleted ? "ignored":"deleted");
                if(!deleted) delete p;

    public: shared_ptr<A> $ptr = shared_ptr<A>(this, D());

    public: ~A() {
        std::get_deleter<A::D>($ptr)->deleted = true;

    public: weak_ptr<A> ptr() { return $ptr; }

void test() {
    A a;

    printf("count: %d\n", a.ptr().lock().use_count());
    printf("count: %d\n", a.ptr().use_count());

int main(int argc, char *argv[]) {
    puts("+++ main");


    puts("--- main");


$ g++ -std=c++11 -o test test.cpp && ./test
+++ main
count: 2
count: 1
[deleter (ignored)]
--- main

The shared_ptr deleter should never get called for an object allocated in stack, so when it does at normal object destruction, it just bypasses the delete (we got to this point because the default object destructor was already called).

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