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I'm trying to implement a minimalistic synchronization mechanism where there's an object contains some value of type Foo, this Foo may potentially be a heavyweight type, but rarely changes its value. the object may be accessed from multiple threads, almost 100% reads.

I am trying to think of a way to make this work without any locking requirements on the readers. My first attempt was to have my class contain the Foo through a shared pointer member of type std::shared_ptr<Foo>. The read operations would simply copy-construct the shared pointer, dereference it, and then use this "version" of the value to do whatever they want.

The write operations are supposed to apply their changes into a new copy of Foo, and once done, attempt to replace the current version of Foo with a new one.

I realized this is not possible with shared_ptr<Foo> since the copy-constructor could get into a read/write race with something trying to update it, and read a corrupted value. I could get around this problem using boost::intrusive_ptr<Foo> with an atomic counter and doing the version update with a CAS operation, but there's still a race condition I can't get rid of: the reader can be suspended just before calling intrusive_ptr_add_ref on an instance that's about to get destroyed by another thread that lowered the count to 0.

It seems like something is fundamentally broken with this approach.

Is there any way to accomplish this that doesn't rely on a critical section, readers/writer lock or a full-blown RCU (read-copy-update)? Maybe I'm missing something simple. Platform is Win7+/x86/x64.

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up vote 3 down vote accepted

The solution is to first have a local std::shared_ptr<Foo> which has the new Foo and assign it to the global std::shared_ptr via atomic assignment methods. To clarify: Don't use plain assignment. From the link, you could use:

atomic_store( &global_ptr, std::make_shared<Foo>(...) );
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if my class has std::shared_ptr<Foo> m_px and the reader executes std::shared_ptr<Foo> temp = m_px while a writer attempts to assign a new value to m_px, do I have a guarantee that I read either the new or the old value, rather than something corrupted? I thought it said in boost documentation that this race causes UB – yonil Mar 9 '13 at 0:58
@yonil why are you looking at boost documentation for std::shared_ptr? – David Brown Mar 9 '13 at 1:01
simply put, you can read from any value you want to any number of threads, but if so much as ONE write is done on it, you MUST lock. if you dont, it's UB. Now , with THAT said, there IS lock free data structures... – johnathon Mar 9 '13 at 1:01
@DavidBrown good question LOL – johnathon Mar 9 '13 at 1:01
@yonil : From the page Daniel linked to: "Note that the control block of a shared_ptr is thread-safe: different std::shared_ptr objects can be accessed using mutable operations, such as operator= or reset, simultaneously by multiple threads, even when these instances are copies, and share the same control block internally." – ildjarn Mar 9 '13 at 1:02

This would work..

Foo * globalFoo;

Foo* newFoo = new Foo();
Foo* temp;
do {
    temp = globalFoo;
} while(! std::atomic_compare_exchange_weak(temp, globalFoo, newFoo));
share|improve this answer
yes, I was just not aware of the atomic functions that are available - I was still thinking in terms of the old boost::shared_ptr and the 03 standard. I also didn't know the architecture supported 128bit atomic operations, so I didn't even suspect such a thing was possible – yonil Mar 9 '13 at 1:17
The hard part is knowing when it is safe to delete the old object. – brian beuning Mar 9 '13 at 15:34

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