According to cppref, accessing const members of shared_ptr across multiple threads is safe. But is this statement valid when we have a weak_ptr that corresponds to a shared_ptr?

As an example assume the following code:

#include <memory>
#include <iostream>
#include <thread>

std::shared_ptr<int> sp;
std::weak_ptr<int> gw;

int main()
    sp = std::make_shared<int>(42);
    gw = sp;
    auto th1 = std::thread([]{
        for (int i = 0; i < 200; i++) {
            if (sp.use_count() > 1) {
                std::cout << i << "\n";
    auto th2 = std::thread([]{
        for (int i = 0; i < 20; i++) {
            if (auto l = gw.lock()) {
                std::cout << "locked ->" << l.use_count() << "\n";

This code creates 2 threads. One checks use_count() of shared_ptr() which is a const method and the other one use lock() to lock weak_ptr() which also is a const method too. But in reality, when I call lock on weak_ptr, I practically increase reference count of shared_ptr which is not thread safe unless reference count is internally guarded. I wonder if I will have a data race in situations like this. Is this supposed to be thread-safe by standard?

  • Like you said, you're only calling const functions so it has to be safe. If a const function alters some internal state, it's on the implementation to get that right. – NathanOliver Jun 1 '20 at 17:59
  • @NathanOliver the problem is that from what I got from cpp ref(if I assume it mirrors meaning of standard), standard does not define any operation relation between shared_ptr and weak_ptr. So being const probably means only on this object and does not define anything for other related objects. lock() creates a new shared_ptr and I don't think it will be thread-safe. – Afshin Jun 1 '20 at 18:06
  • In order for weak_ptr to work it has to share the control block with the shared_ptr you get it from. That shared state is protected though since you call only const member functions on both pointers. – NathanOliver Jun 1 '20 at 18:08

Yes. The reference counter is atomic, so there are no data races in your example.

That being said, mutable operations on objects pointed by std::shared_ptr are not atomic, so they must be guarded as you would guard access via a plain pointer.

  • Just to note that the use of use_count() though being thread-safe avoiding any data race there is still a race condition between the threads resulting with non deterministic behavior, which might be logically ok or not. – Amir Kirsh Jun 3 '20 at 1:58

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