I'm trying to understand exactly how thread-safe, atomic reference counting works, for example as with std::shared_ptr. I mean, the basic concept is simple, but I'm really confused about how the decref plus delete avoids race conditions.

This tutorial from Boost demonstrates how an atomic thread-safe reference counting system can be implemented using the Boost atomic library (or the C++11 atomic library).

#include <boost/intrusive_ptr.hpp>
#include <boost/atomic.hpp>

class X {
  typedef boost::intrusive_ptr<X> pointer;
  X() : refcount_(0) {}

  mutable boost::atomic<int> refcount_;
  friend void intrusive_ptr_add_ref(const X * x)
    x->refcount_.fetch_add(1, boost::memory_order_relaxed);
  friend void intrusive_ptr_release(const X * x)
    if (x->refcount_.fetch_sub(1, boost::memory_order_release) == 1) {
      delete x;

Okay, so I get the general idea. But I don't understand why the following scenario is NOT possible:

Say the refcount is currently 1.

  1. Thread A: atomically decrefs the refcount to 0.
  2. Thread B: atomically increfs the refcount to 1.
  3. Thread A: calls delete on the managed object pointer.
  4. Thread B: sees the refcount as 1, accesses the managed object pointer... SEGFAULT!

I can't understand what prevents this scenario from occurring, since there is nothing preventing a data race from between the time the refcount reaches 0, and the object is deleted. Decrefing the refcount and calling delete are two separate, non-atomic operations. So how is this possible without a lock?

  • 5
    How does the refcount is 1 while there are two references from the two threads? – Curve25519 Jul 6 '15 at 20:22
  • You need to spell out the invariant of a use count. A use count should never reach 0 while there are users. Your code must have a bug somewhere. – curiousguy Jan 19 '17 at 23:49

You probably overestimate the threadsafety a shared_ptr provides.

The essence of atomic ref counting is to ensure that if two different instances of a shared_ptr (that are managing the same object) are accessed/modified, there will be no race condition. However, shared_ptr doesn't ensure thread safety, if two threads access the same shared_ptr object (and one of them is a write). One example would be e.g. if one thread dereferences the pointer, while the other resets it.
So about the only thing shared_ptr gurantees is that there will be no double delete and no leak as long as there is no race on a single instance of a shared_ptr (It also doesn't make accesses to the object it points to threadsafe)

As a result, also creating a copy of a shared_ptr is only race free, if there is no other thread, that could logically delete/reset it at the same time (you could also say, it is not internally synchronized). This is the scenario you describe.

To repeat it once more: Accessing a single shared_ptr instance from multiple threads where one of those accesses is a write (to the pointer) is still a race condition.

If you want to e.g. copy a std::shared_ptrin a threadsafe manner, you have to ensure that all loads and stores happen via std::atomic_... operations which are specialized for shared_ptr.

  • 1
    Atomic operations on shared_ptr are little known and underrated. +1 – sehe Jul 6 '15 at 23:00
  • @sehe: A more accurate description is that "atomic operations on shared pointers are horribly misdesigned and broken" :-) Efforts are underway to improve that situation, though. – Kerrek SB Jul 7 '15 at 9:44
  • @sehe: I have to admit that I haven't used them myself, yet. I only remembered them from Herb Sutter's talk about lock-free programming at cppcon2014. – MikeMB Jul 7 '15 at 10:13
  • I used them. But they aren't widely supported yet. Also, the standard doesn't require the implementation to actually use atomics. – sehe Jul 7 '15 at 10:17
  • Does this also apply to QSharedPointer? Qt documentation states that "QSharedPointer and QWeakPointer are thread-safe and operate atomically on the pointer value. " – philipp Aug 10 '15 at 12:21

That situation will never arise. If the ref count of a shared pointer reaches 0 then the last reference to it has been removed and it is safe to delete the pointer. There is no way to create another reference to the shared pointer since there isn't an instance left that you could copy.

  • Im not sure whether you don't mention the scenario, because it's UB anyway or because you overlooked it, but it is indeed possible to copy a shared_ptr while the object its pointing to is deleted. E.g. if you have a global shared_ptr and one thread makes a local copy of it, while the other thread resets the pointer to another object. And even if you don't want to consider std:share_ptr::reset (I'm not sure, if boosts intrusive pointers have that) then think of a situation, where the share_ptr itself is dynamically allocated (be it directly or a a member of another object) and then deleted. – MikeMB Jul 6 '15 at 22:10
  • @MikeMB That doesn't make sense. If you are copying a shared_ptr that points to an object, then that object hasn't been deleted. A shared_ptr does not delete an object until it confirms that no other shared_ptrs point to it and, in the process of deleting the object, ensures that it no longer points to the object. – David Schwartz Jan 20 '17 at 1:21
  • @David: What you say is only true when talking about two different instances. When one thread reads (for copying) the same instance the other one writes to (e.g. calling reset or the destructor) you have no such guarantee (datarace -> UB). That is at least one reason, why they want to introduce an std::atomic_shared_ptr – MikeMB Jan 20 '17 at 7:29
  • @MikeMB I don't think the OP is asking about something that unusual. I think the OP understands that shared_ptr instances behave like every other type as far as a single instance goes. – David Schwartz Jan 20 '17 at 8:28
  • @DavidSchwartz: Well, I thought this was exactly what the OP was asking about (hence my answer). I might be wrong, but I've heard that misconception quite often. Someone said "std::shared_ptr is threadsafe" and meant the ref counting and deletion (as opposed to other implementations where the ref count doesn't happen atomically), but the next person understands it as "A shared_ptr may be accessed (and modified) from different threads simultaneously" – MikeMB Jan 20 '17 at 10:18

Your scenario is not possible because Thread B should have been created with an incremented refcount already. Thread B should not be incrementing the ref count as the first thing it does.

Let's say Thread A spawns Thread B. Thread A has the responsibility to increment the ref count of the object BEFORE creating the thread, to guarantee thread safety. Thread B then only has to call release when it exits.

If Thread A creates Thread B without incrementing the ref count, bad things might happen as you've described.

  • 1
    Can you provide a link to the question you've answered? – IInspectable Jul 6 '15 at 20:41
  • 4
    @IInspectable: Seems like a perfectly reasonable answer to the question on this page - or am I missing something? – psmears Jul 6 '15 at 21:02

The implementation doesn't provide or require such a guarantee, avoidance of the behavior you are describing is predicated on the proper management of counted-references, usually done through a RAII class such as std::shared_ptr. The key is to entirely avoid passing by raw pointer across scopes. Any function which stores or retains a pointer to the object must take a shared pointer so that it can properly increment the ref count.

void f(shared_ptr p) {
   x(p); // pass as a shared ptr
   y(p.get()); // pass raw pointer

This function was passed a shared_ptr so the refcount was already 1+. Our local instance, p, should have bumped the ref_count during copy-assignment. When we called x if we passed by value we created another ref. If we passed by const ref, we retained our current ref count. If we passed by non-const ref then it's feasible that x() released the reference and y is going to be called with null.

If x() stores/retains the raw pointer, then we may have a problem. When our function returns the refcount might reach 0 and the object might be destroyed. This is our fault for not correctly maintaining ref count.


template<typename T>
void test()
    shared_ptr<T> p;
        shared_ptr<T> q(new T); // rc:1
        p = q; // rc:2
    } // ~q -> rc:1
    use(p.get()); // valid
} // ~p -> rc:0 -> delete


template<typename T>
void test()
    T* p;
        shared_ptr<T> q(new T); // rc:1
        p = q; // rc:1
    } // ~q -> rc:0 -> delete
    use(p); // bad: accessing deleted object

For std::shared_ptr a reference counting change is thread safe, but not the access to the content of the `shared_ptr.

Regarding boost::intrusive_ptr<X>, this is no answer.


Thread B: atomically increfs the refcount to 1.

Impossible. To increment the reference count to one, the reference count would have to be zero. But if the reference count is zero, how is thread B accessing the object at all?

Either thread B has a reference to the object or it doesn't. If it does, then the reference count cannot be zero. If it does not, then why is it messing with an object managed by smart pointers when it has no reference to that object?

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