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I am studying Google's filament job system. Currently, I am studying the WorkStealingDequeue they implemented. You can look at the full source code here . This data structure is based on this work. In their implementation of pop and steal, they use memory_order_seq_cst as a full memory barrier.

template <typename TYPE, size_t COUNT>
TYPE WorkStealingDequeue<TYPE, COUNT>::pop() noexcept {
    // mBottom is only written in push(), which cannot be concurrent with pop(),
    // however, it is read in steal(), so we need basic atomicity.
    //   i.e.: bottom = mBottom--;
    int32_t bottom = mBottom.fetch_sub(1, std::memory_order_relaxed) - 1;

    // we need a full memory barrier here; mBottom must be written and visible to
    // other threads before we read mTop.
    int32_t top = mTop.load(std::memory_order_seq_cst);

    if (top < bottom) {
        // Queue isn't empty and it's not the last item, just return it.
        return getItemAt(bottom);
    }

    TYPE item{};
    if (top == bottom) {
        // We took the last item in the queue
        item = getItemAt(bottom);

        // Items can be added only in push() which isn't concurrent to us, however we could
        // be racing with a steal() -- pretend to steal from ourselves to resolve this
        // potential conflict.
        if (mTop.compare_exchange_strong(top, top + 1,
                std::memory_order_seq_cst,
                std::memory_order_relaxed)) {
            // success: mTop was equal to top, mTop now equals top+1
            // We successfully poped an item, adjust top to make the queue canonically empty.
            top++;
        } else {
            // failure: mTop was not equal to top, which means the item was stolen under our feet.
            // top now equals to mTop. Simply discard the item we just poped.
            // The queue is now empty.
            item = TYPE();
        }
    }

    // no concurrent writes to mBottom possible
    mBottom.store(top, std::memory_order_relaxed);
    return item;
}

template <typename TYPE, size_t COUNT>
TYPE WorkStealingDequeue<TYPE, COUNT>::steal() noexcept {
    do {
        // mTop must be read before mBottom
        int32_t top = mTop.load(std::memory_order_seq_cst);

        // mBottom is written concurrently to the read below in pop() or push(), so
        // we need basic atomicity. Also makes sure that writes made in push()
        // (prior to mBottom update) are visible.
        int32_t bottom = mBottom.load(std::memory_order_acquire);

        if (top >= bottom) {
            // queue is empty
            return TYPE();
        }

        // The queue isn't empty
        TYPE item(getItemAt(top));
        if (mTop.compare_exchange_strong(top, top + 1,
                std::memory_order_seq_cst,
                std::memory_order_relaxed)) {
            // success: we stole a job, just return it.
            return item;
        }
        // failure: the item we just tried to steal was pop()'ed under our feet,
        // simply discard it; nothing to do.
    } while (true);
}

For the implementation to be correct, It is required that mBottom to be fetched before mTop in pop() and mTop to be fetched before mBottom in steal(). If we think memory_order_seq_cst as a full memory barrier like most implementation do, then the above code is correct. But from what I understand, C++11 doesn't say anything about memory_order_seq_cst as full memory barrier. From what I understand to ensure the correct ordering then the mBottom fetch_sub operation must be at least std::memory_order_acq_rel. Is my analysis correct?

And then is memory_order_seq_cst on mTop necessary? memory_order_seq_cst force all operation on mTop to be on a single total order(STO). But in this case, the only one that participate in the STO is mTop. I believe we already have modification order guarantee which stated that every threads must agree on the modification order of every variable relative to itself. Is memory_order_acq_rel in the compare_exchange_strong operation enough?

  • What is a "full memory barrier"? – curiousguy Jun 14 at 0:51
  • All operation before memory_order_seq_cst must be executed before the synchronization operation. Operation with memory_order_seq_cst must be executed before all operation after it. It is a barrier that prevents reordering on both direction. I am not sure whether it is the correct term. – kevinyu Jun 14 at 2:58
  • Yes, all operations potentially measurable by other threads. Like an ack-rel barrier. – curiousguy Jun 14 at 3:22
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This code has a data race in steal, and therefore undefined behaviour, regardless of the memory orderings.

There is nothing preventing the stealing thread calling getItemAt(top) to read the value at a given index, while the worker thread that owns the queue calls push enough times to wrap around the buffer and overwrite the entry, or calls pop enough times to empty the queue and then calls push to overwrite that entry.

e.g. mTop is 0, mBottom is 1 => queue has one element.

Stealing thread reads mTop and mBottom. top<bottom, so it gets to the call the getItemAt(top) and is suspended by the OS due to task switching.

Worker thread calls pop. It reads mBottom and sets bottom to 0. It then reads top (0). 0==0, so we call getItemAt(bottom) to retrieve the item. It then increments mTop to 1, and sets mBottom to 1.

Worker thread then calls push and calls setItemAt(mBottom) to set the next element, which is now element 1.

The worker thread now repeats this push/pop dance COUNT times, so the queue never has more than one element, but each time incrementing mTop and mBottom so the active element is moved round the buffer until mBottom & MASK is again 0.

The worker thread calls push and thus setItemAt(mBottom), which accesses element 0. The OS resumes the stealing thread, which also is accessing element 0 => read and write to the same location without ordering => data race and undefined behaviour.

This is only OK if TYPE is std::atomic<T> for some T.

Assuming that COUNT is large enough that in practice this never happens, then push write to mBottom with memory_order_release, and steal reads with memory_order_acquire. This means the the write to the relevant data item happens-before the read of the item in steal, so reading the item is OK. This is visible even with the fetch_sub in pop using memory_order_relaxed due to a concept called "release sequences".

The use of memory_order_seq_cst on the loads and successful compare-exchange of mTop forces the operations on mTop into a single global total order. However, the comment on the load of mTop in pop is wrong: the use of memory_order_seq_cst does not prevent the mBottom.fetch_sub call being reordered, as this is a load from mTop, and the fetch_sub call uses memory_order_relaxed. The memory_order_seq_cst on the load does not impose any ordering on non-memory_order_seq_cst writes from the same thread to other variables.

I am not sure at this time what the impact on this may be on the code.

  • Interesting, what If we remove the wrap around mechanism. Instead, we always reset the deque every frame and make an assertion that the job inside the queue in a frame will never be more than COUNT? I still wonder whether memory_order_seq_cst automatically translate to a full memory barrier. I found this statement a lot. – kevinyu Jun 13 at 11:12
  • Okay, after thinking some more. I realize that this deque is used for a job system. So the wrap around might be mitigated by ensuring that the number of job for every frame per dequeue must not be greater than COUNT. This can be done by waiting for all job on this frame before pushing job for the next frame. – kevinyu Jun 13 at 11:23
  • "The memory_order_seq_cst on the load does not impose any ordering on non-memory_order_seq_cst writes from the same thread to other variables." Um, yes it does. That's the whole point of memory orders: to impose ordering between the atomic operation/barrier and previous operations in the same thread. It's not (just) about the atomic operation itself; it's about the relationship between that atomic operation and any prior operations on the thread. relaxed isn't some global opt-out of any ordering; later barriers can impose ordering on an object that itself doesn't impose ordering. – Nicol Bolas Jun 13 at 15:19
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    Consider x.store(42,memory_order_relaxed); y.load(memory_order_seq_cst); The memory_order_seq_cst operation is a load. It does not impose an order on the prior store from the same thread. If it had said y.store(99,memory_order_seq_cst) then it would impose an ordering on the store. Loads are not release operations – Anthony Williams Jun 13 at 15:38
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    @AnthonyWilliams Is memory_order_seq_cst in mTop necessary? As you said memory_order_seq_cst forces global total order. But in this case the only variable that participate in the total order is mTop. Without global total order, we already have modification order guarantee. Every thread have to agree on a single modification order for every single variable. It seems like that is already enough. – kevinyu Jun 16 at 6:34

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