Let's see if we can get this moved to chat — sehe 2 mins ago
12:06 PM
@sehe thank your for your detailed reply and critique on the design i was pursuing. A lot of the code is experimental. For instance I created the thread pool to push onto the queue cause I was observing jitter (spikes of upto 35 microsecs) and my suspicion was the original single pusher thread was still blocked working. I'm not sure what's wrong with the atomic flag load/store combination in place? Could you explain this. Isn't the acquire/release fence synchronized across all threads ? This was my first shot at variadics, that's why the clumsiness around boost::function and stuff. — Aditya Sihag 6 hours ago
@sehe I'm also trying to make enqueue a non-blocking call, even if it be called from a single thread. — Aditya Sihag 6 hours ago
> I created the thread pool to push onto the queue cause I was observing jitter (spikes of upto 35 microsecs) and my suspicion was the original single pusher thread was still blocked working
Firstly, Boost Asio is not a lock free queue, AFAIK. So posting to that queue is not a way to remove jitter.
Secondly, there's the problem that I mentioned in my answer: you can't move the formatting to the "asynchronous processing" part, because you will get arguments that are by ref and will not be safe to access from another thread, unknown amount of time later.
If you want to mitigate this, you could pass all the arguments by value but this will create a lot more jitter (spurious latencies), because copying the arguments is not free (especially not if it's something like
std::string
or even more expensive. So you can't really remove the cost, you can only replace it by the cost of copying (which is often exactly the same amount of work as formatting in the first place)
@InnocentBystander Just to be constructive as well, I've added my idea of what constitutes a much simpler start: Live On Coliru - (I'm pretty certain is more efficient to boot, OP) — sehe 11 hours ago
> I'm not sure what's wrong with the atomic flag load/store combination in place? Could you explain this
> the explicit memory-order load/stores give me bad vibes too. The way they're written would make sense only if exactly two threads are involved in the flag, but this is in no way apparent to me at the moment (threads are created all around).
After I've refactored into a "cleaner" solution I realize that indeed the
pop()
thread was on a single thread, and iff you can prove that the Log
class is used from a single thread only, this makes the synchronization on the flag
flag (... use descriptive names!) safe. However, the other use:
Can't really be explained. What are you trying to achieve here? This adds no value over the thread safety guarantee of
spsc_queue
itself
And, I do get the impression that you introduced the
io_service
thread pool in order to psuh from background threads ("make push non-blocking"). This means your design is broken (you cannot use spsc_queue
in this situation) and also the memory order is wrong (same thing goes for acquire/release
pairs)
Okay, so what I would further optimize is the queue itself: I'm not convinved that
boost::lockfree::detail::consume_via_copy
from std::string will "do the right thing". You could, instead, store "smart" pointers to a pool allocated boost::array<char, 1000>
, perhaps with the corresponding array_sink
and iostream<array_sink>
objects cached.
This make moving items on/off the queue extremely lightweight, at the cost of writing a "queue element" type that abstracts the complexity of managing the lifetime/free-marking of these preallocated things. Also, it might not be "okay" for your application to keep
1024*1000
bytes allocated just for logging (I don't know).
This is why I didn't continue to provide this (my rule is: make it simple and efficient; as soon as adding optimizations starts increasing complexity, WAIT for your profiler to tell you that you really need it)
room topic changed to On lockfree logging, queuing and memory order: see stackoverflow.com/q/28254996/85371 [c++] [lock-free] [memory-order] [spsc-queue]
1:05 PM
@sehe Hi. I'm thought process was that since spsc doesnt support multiple threads pushing to the queue, if I estiblish a spin lock around the push itself, I could trade off some occasional latency in multiple spins for the benefit of having a logging structure that is thread safe.
At the very heart of the problem, I want to have the enqueue function to be asynchronous. So it should actually take the variadic contents and copy them to a buffer (linear work), and just return while delegating the rest of the work of pushing onto the queue to a thread -> hence the io_service and post setup which I went about.
That way I can potentially have a logger that doesnt block for more than some nanoseconds on the calling thread (which is simple the time to copy the contents of the log message onto the buffer that is then handled by the thread)
That way I can potentially have a logger that doesnt block for more than some nanoseconds on the calling thread (which is simple the time to copy the contents of the log message onto the buffer that is then handled by the thread)
@AdityaSihag SPSC literally doesn't support pushing from more than one thread. Iff you wanted to work around that with synchronization, you'd need full memory barriers (making your acquire/release still wrong)
I would not be comfortable guaranteeing that this is enough to make spsc safe with more than one threads pushing (note that you won't see this on all architectures, it's aperfect source for Heisenbugs)
The re-write you have posted is quite slow, I'm not sure how spsc lierally doesn't support pushing from more than one thread ? Cause if I remove the variadic arguments and make enqueue accept just a string, then I can actually print different thread id's inside the push function. And since I have the spin lock, at any given point only one thread is accessing the queue through push.
Ultimately the goal is to produce a logger that has nanosecond latency on the thread that calls enqueue for reasonably sized lines (say 20 or so words -> representated as a combination of char *, string, and nume…
Ultimately the goal is to produce a logger that has nanosecond latency on the thread that calls enqueue for reasonably sized lines (say 20 or so words -> representated as a combination of char *, string, and nume…
the nanosecond latency can be achieved provided the work of type coversion from variadic inputs to stream / string is done asynchronously. Obviously as you pointed out this requires the original variadic components at some point to be copied. I'm certain a single copy onto a char buffer that is thread local will do the job. But the call to enqueue must then return, it can't go on to even do the work of type conversion to stream / string on the calling thread
1:31 PM
@AdityaSihag "quite slow" - that statement is "quite funny". Do you have a benchmark that you can share (the code)
Note how they do not say "one thread at a time". This is because they use optimal memory ordering on their atomic ringbuffer indices and it will go wrong if more than one thread is participating.
Note again: Not all architectures expose this (notable, Intel doesn't behave differently with acq/rel vs. cst ordering, AFAIK). But it's still the requirement
hmm no, i'm pretty rookie, but i still want to crack this problem of sub micro second latency on the calling thread. Any suggestions on how to pursue from here ? The latency choke point is the variadic to stream conversion, and the fact that it happens on the enqueue calling thread. SPSC condition of being called by 1 thrd can be met by just limiting the thread pool size to 1, &passing the data to be logged to a buffer which then io_service posts to convert to stream and push to queue, correct ?
1:51 PM
There's a much higher chance you can optimize this in the calling code, than generically in the logging framework (although, once you've figured out usual patterns that callers use to ottimize things you could provide facilities to make this easier)
the benchmark is simply setting my original piece of code i supplied to have one thread in the thread pool (so i loops from 0 to 1 in the main function). In addition define enqueue to take a string instead of variadics. from main call enqueue with l.enqueue(boost::bind<std::string>(&Log::push,&l,"let's print out this line"));. Enqueu itself is just a template function template <typename G> void enqueue(G g){io_service->post(g)}
2:03 PM
doing that will produce an average over 1000000 such enqueue calls of .9 micro per call for this 5 worded single-typed sentence. However for single iteration tests it clocks about 3-5 micro.
2:17 PM
posting the benchmark, i realize i'm actually clocking 1 microsecond for a single iteration on my server, the 3-5 micro benchmark is from my laptop. But then this 1 micro second is for a single-typed log info. The moment i have multiple types, i need to convert them to a stream / string which throws this whole setup awry. Posting the code that yields 1 micro benchmark on my server, give me minute
[aditya@W2WNSEALGO16 src]$ ../bin/emm
3 microsec
[aditya@W2WNSEALGO16 src]$ ../bin/emm
7 microsec
[aditya@W2WNSEALGO16 src]$ ../bin/emm
7 microsec
[aditya@W2WNSEALGO16 src]$ ../bin/emm
7 microsec
[aditya@W2WNSEALGO16 src]$ ../bin/emm
4 microsec
[aditya@W2WNSEALGO16 src]$ ../bin/emm
3 microsec
[aditya@W2WNSEALGO16 src]$ ../bin/emm
7 microsec
[aditya@W2WNSEALGO16 src]$ ../bin/emm
7 microsec
[aditya@W2WNSEALGO16 src]$ ../bin/emm
6 microsec
[aditya@W2WNSEALGO16 src]$ ../bin/emm
6 microsec
[aditya@W2WNSEALGO16 src]$ ../bin/emm
3 microsec
[aditya@W2WNSEALGO16 src]$ ../bin/emm
7 microsec
[aditya@W2WNSEALGO16 src]$ ../bin/emm
7 microsec
[aditya@W2WNSEALGO16 src]$ ../bin/emm
7 microsec
[aditya@W2WNSEALGO16 src]$ ../bin/emm
4 microsec
[aditya@W2WNSEALGO16 src]$ ../bin/emm
3 microsec
[aditya@W2WNSEALGO16 src]$ ../bin/emm
7 microsec
[aditya@W2WNSEALGO16 src]$ ../bin/emm
7 microsec
[aditya@W2WNSEALGO16 src]$ ../bin/emm
6 microsec
[aditya@W2WNSEALGO16 src]$ ../bin/emm
6 microsec
[aditya@W2WNSEALGO16 src]$ ../bin/emm
@AdityaSihag downloads.sehe.nl/stackoverflow/q28254996/nonvariadic.html Disregard the obvious warm up (this is to "/dev/null")
github.com/rmartinho/nonius, it's with exactly your code from here but wrapped in a nonius benchmark:
NONIUS_BENCHMARK("nonvariadic", [](nonius::chronometer meter) { std::vector<int32_t> pushCores; for (int i = 0; i < 1; ++i) { pushCores.push_back(i); } // pushCores.push_back(16); pushCores.push_back(17), pushCores.push_back(18), pushCores.push_back(19); Log l("/dev/null",1,1024,pushCores); meter.measure([&l](int i) { l.enqueue(boost::bind(&Log::push,&l,"let's print out this line")); }); })
I'm not improving anything yet (although my version is clearly much faster: downloads.sehe.nl/stackoverflow/q28254996/mine.html (that's with the unmodified thing I posted yesterday, see dir). And it does use variadics:
3:38 PM
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