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I have been trying to Google my question but I honestly don't know how to succinctly state the question.

Suppose I have two threads in a multi-core Intel system. These threads are running on the same NUMA node. Suppose thread 1 writes to X once, then only reads it occasionally moving forward. Suppose further that, among other things, thread 2 reads X continuously. If I don't use a memory fence, how long could it be between thread 1 writing X and thread 2 seeing the updated value?

I understand that the write of X will go to the store buffer and from there to the cache, at which point MESIF will kick in and thread 2 will see the updated value via QPI. (Or at least this is what I've gleaned). I presume that the store buffer would get written to the cache either on a store fence or if that store buffer entry needs to be reused, but I don't know store buffers get allocated to writes.

Ultimately the question I'm trying to answer for myself is if it is possible for thread 2 to not see thread 1's write for several seconds in a fairly complicated application that is doing other work.

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  • If the two threads are running on the same NUMA node, then QPI would not be involved. – Hadi Brais Jul 12 '18 at 11:47
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Memory barriers don't make other threads see your stores any faster. (Except that blocking later loads could slightly reduce contention for committing buffered stores.)

The store buffer always tries to commit retired (known non-speculative) stores to L1d cache as fast as possible. That makes them globally visible because of MESI/MESIF/MOESI. The store buffer is not designed as a proper cache or write-combining buffer (although it can combine back-to-back stores to the same cache line), so it needs to empty itself to make room for new stores. Unlike a cache, it wants to keep itself empty, not full.

Fences/barriers work by making the current thread wait, not by speeding up store visibility.

A simple implementation of a full barrier (mfence or a locked operation) is to stall the pipeline until the store buffer drains, but high-performance implementations can do better and allow out-of-order execution separately from the memory-order restriction.

(Unfortunately Skylake's mfence does fully block out-of-order execution, to fix the obscure SKL079 erratum involving NT loads from WC memory. But lock add or xchg or whatever only block later loads from reading L1d or the store buffer until the barrier reaches the end of the store buffer. And mfence on earlier CPUs presumably also doesn't have that problem.)


In general on non-x86 architectures (which have explicit asm instructions for weaker memory barriers, like only StoreStore fences without caring about loads), the principle is the same: block whichever operations it needs to block until this core has completed earlier operations of whatever type.

Related:


Ultimately the question I'm trying to answer for myself is if it is possible for thread 2 to not see thread 1's write for several seconds

No, the worst-case latency is maybe something like store-buffer length (56 entries on Skylake, up from 42 in BDW) times cache-miss latency, because x86's strong memory model (no StoreStore reordering) requires stores to commit in-order. But RFOs for multiple cache lines can be in flight at once, so the max delay is maybe 1/5th of that (conservative estimate: there are 10 Line Fill Buffers). There can also be contention from loads also in flight, but we just want an order of magnitude back-of-the-envelope number.

Lets say RFO latency (DRAM or from another core) is 300 clock cycles (basically made up) on a 3GHz CPU. So a worst-case delay for a store to become globally visible is maybe something like 300 * 56 / 5 = 3360 core clock cycles. So within an order of magnitude, worst case is about ~1 microsecond on the 3GHz CPU we're assuming. (CPU frequency cancels out, so an estimate of RFO latency in nanoseconds would have been more useful).

That's when all your stores need to wait a long time for RFOs, because they're all to locations that are uncached or owned by other cores. And none of them are to the same cache line back-to-back so none can merge in the store buffer. So normally you'd expect it to be significantly faster.

I don't think there's any plausible mechanism for it to take even a hundred microseconds, let alone a whole second.

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  • I think that we can model the time it takes for a store to reach another thread as follows: the time it takes the store to be retired (which means leaving the store buffer to either the L1D or an LFB) + the time it takes to copy the line from the private cache of the core to the private cache of the other core (or the target register). This may require an L2-L2 transfer for inclusive L2 and for different physical cores. But both of these time components can vary wildly. It's very hard to put an upper limit on that. – Hadi Brais Jul 12 '18 at 11:07
  • @HadiBrais: Retirement from the out-of-order core (ROB) is separate from reaching the end of the store buffer and committing to L1d (to a line in M state). The store buffer decouples OoO execution/retirement from L1d commit. Retirement is a pre-condition for commit, but that's all. (A large store buffer can impact interrupt latency, because there's no way to discard / roll it back; stores that have left the ROB need to happen for correctness.) I left out OoO exec from my calculation, which could maybe be significant for timing WRT. loads in low IPC code. – Peter Cordes Jul 12 '18 at 11:24
  • But yeah, things can vary wildly, which is why I can confidently rule out a microsecond, but I'm only claiming an order of magnitude for my 1 us quick estimate of worst-case latency. – Peter Cordes Jul 12 '18 at 11:25
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    Consider a shared-memory system with multiple sockets where the two threads are on two different sockets. How much time does it for one thread to get the data of the other? If all the cores are very busy doing stuff, can it take more than a second in the worst case? – Hadi Brais Jul 12 '18 at 11:28
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    @BeeOnRope: I linked to my answer on another question. The last section of that answer has more details about SKL079, and my conclusions. If anyone could test mfence on HSW to see if it blocks OoO exec, that would be cool. Nice idea comparing the HSW numbers; maybe they attempted to make mfence more efficient in SKL but ended up reverting it. I had been assuming that earlier uarches were more efficient, but maybe not. – Peter Cordes Jul 12 '18 at 19:57

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