Firstly, I know this [type of] question is frequently asked, so let me preface this by saying I've read as much as I can, and I still don't know what the deal is.
I've parallelized a massive outer for loop. Number of loop iterations varies, typically between 20-150, but the loop body does a huge amount of work, calling on a lot of local intensive linear algebra routines (as in, the code is part of the source and not an external dependency). Within the loop body there is 1000+ calls to these routines, but they're all totally independent of one another, so I figured it would be a prime candidate for parallelism. The loop code is C++, but it calls a lot of subroutines written in C.
Code looks like this;
<declare and initialize shared variables here>
#ifdef _OPENMP
#pragma omp parallel for
private(....)
shared(....)
firstprivate(....) schedule(runtime)
#endif
for(tst = 0; tst < ntest; tst++) {
// Lots of functionality (science!)
// Calls to other deep functions which manipulate private variables only
// Call to function which has 1000 loop iterations doing matrix manipulation
// With no exaggeration, there are probably millions
// of for-loop iterations in this body, in the various functions called.
// They also do lots of mallocing and freeing
// Finally generated some calculated_values
shared_array1[tst] = calculated_value1;
shared_array2[tst] = calculated_value2;
shared_array3[tst] = calculated_value3;
} // end of parallel and for
// final tidy up
There shouldn't, I believe, be any synchronization at all - the only time the threads access a shared variable are the shared_arrays
, and they access unique points in those arrays, indexed by tst
.
Thing is, when I up the number of threads (on a multicore cluster!) The speeds we're seeing (where we invoke this loop 5 times) are as follows;
Elapsed time System time
Serial: 188.149 1.031
2 thrds: 148.542 6.788
4 thrds: 309.586 424.037 # SAY WHAT?
8 thrds: 230.290 568.166
16 thrds: 219.133 799.780
Things which may be noticeable are the massive jump in System time between 2 and 4 threads, and the fact the elapsed time doubles as we move from 2 to 4, and then slowly decreases.
I've tried with a huge range of OMP_SCHEDULE
parameters but no luck. Is this related to the fact each thread is using malloc/new and free/delete a lot? This has consistently been run with 8GBs memory - but I'm guessing that's not a problem. Frankly, the huge rise in system time makes it look like the threads might be blocking, but I have no idea why that would happen.
UPDATE 1
I really thought the false sharing was going to be the problem, so re-wrote the code so that the loops store their calculated values in thread-local arrays, and then copy these arrays across to the shared array at the end. Sadly this didn't have any impact, though I almost don't believe it myself.
Following @cmeerw's advice, I ran strace -f, and after all the initialization there are just millions of lines of
[pid 58067] futex(0x35ca58bb40, FUTEX_WAKE_PRIVATE, 1 <unfinished ...>
[pid 58066] <... futex resumed> ) = -1 EAGAIN (Resource temporarily unavailable)
[pid 58065] <... futex resumed> ) = -1 EAGAIN (Resource temporarily unavailable)
[pid 57684] <... futex resumed> ) = 0
[pid 58067] <... futex resumed> ) = 0
[pid 58066] futex(0x35ca58bb40, FUTEX_WAKE_PRIVATE, 1 <unfinished ...>
[pid 58065] futex(0x35ca58bb40, FUTEX_WAKE_PRIVATE, 1 <unfinished ...>
[pid 58067] futex(0x35ca58bb40, FUTEX_WAKE_PRIVATE, 1 <unfinished ...>
[pid 58066] <... futex resumed> ) = 0
[pid 57684] futex(0x35ca58bb40, FUTEX_WAIT_PRIVATE, 2, NULL <unfinished ...>
[pid 58065] <... futex resumed> ) = 0
[pid 58067] <... futex resumed> ) = 0
[pid 57684] <... futex resumed> ) = -1 EAGAIN (Resource temporarily unavailable)
[pid 58066] futex(0x35ca58bb40, FUTEX_WAIT_PRIVATE, 2, NULL <unfinished ...>
[pid 58065] futex(0x35ca58bb40, FUTEX_WAKE_PRIVATE, 1 <unfinished ...>
[pid 58066] <... futex resumed> ) = -1 EAGAIN (Resource temporarily unavailable)
[pid 57684] futex(0x35ca58bb40, FUTEX_WAKE_PRIVATE, 1 <unfinished ...>
[pid 58065] <... futex resumed> ) = 0
[pid 58066] futex(0x35ca58bb40, FUTEX_WAKE_PRIVATE, 1 <unfinished ...>
[pid 57684] <... futex resumed> ) = 0
[pid 58067] futex(0x35ca58bb40, FUTEX_WAIT_PRIVATE, 2, NULL <unfinished ...>
[pid 58066] <... futex resumed> ) = 0
[pid 58065] futex(0x35ca58bb40, FUTEX_WAKE_PRIVATE, 1 <unfinished ...>
[pid 58067] <... futex resumed> ) = -1 EAGAIN (Resource temporarily unavailable)
[pid 58066] futex(0x35ca58bb40, FUTEX_WAIT_PRIVATE, 2, NULL <unfinished ...>
[pid 57684] futex(0x35ca58bb40, FUTEX_WAKE_PRIVATE, 1 <unfinished ...>
[pid 58065] <... futex resumed> ) = 0
[pid 58067] futex(0x35ca58bb40, FUTEX_WAKE_PRIVATE, 1 <unfinished ...>
[pid 58066] <... futex resumed> ) = -1 EAGAIN (Resource temporarily unavailable)
[pid 57684] <... futex resumed> ) = 0
[pid 58067] <... futex resumed> ) = 0
[pid 58066] futex(0x35ca58bb40, FUTEX_WAKE_PRIVATE, 1 <unfinished ...>
[pid 58065] futex(0x35ca58bb40, FUTEX_WAIT_PRIVATE, 2, NULL <unfinished ...>
[pid 58066] <... futex resumed> ) = 0
[pid 58065] <... futex resumed> ) = -1 EAGAIN (Resource temporarily unavailable)
[pid 58066] futex(0x35ca58bb40, FUTEX_WAIT_PRIVATE, 2, NULL <unfinished ...>
[pid 57684] futex(0x35ca58bb40, FUTEX_WAKE_PRIVATE, 1 <unfinished ...>
[pid 58067] futex(0x35ca58bb40, FUTEX_WAIT_PRIVATE, 2, NULL <unfinished ...>
[pid 58066] <... futex resumed> ) = -1 EAGAIN (Resource temporarily unavailable)
[pid 58065] futex(0x35ca58bb40, FUTEX_WAKE_PRIVATE, 1 <unfinished ...>
[pid 57684] <... futex resumed> ) = 0
Anyone have any ideas what means? Looks like the threads are context switching way too often, or just blocking and unblocking? When I strace
the same implementation with OMP_NUM_THREADS
set to 0 I get none of this at all. For some comparison, the logfile generated when 1 thread is used is 486 KB , and the log file generated when 4 threads are used is 266 MB.
In other words, the parallel version invokes an extra 4170104 lines of log file...
UPDATE 2
As suggested by Tom, I tried binding threads to specific processors to no avail. We're in OpenMP 3.1, so I set the environment variable using export OMP_PROC_BIND=true
. Same size logfile and same timeframe.
UPDATE 3
The plot thickens. Having only profiled on the cluster so far, I installed GNU GCC 4.7 via Macports and compiled (with openMP) on my Macbook for the first time (Apple's GCC-4.2.1 throws up a compiler bug when OpenMP is enabled, which is why I hadn't compiled and run it in parallel locally until now). On the Macbook, you see basically the trend you'd expect
C-code time
Serial: ~34 seconds
2 thrds: ~21 seconds
4 thrds: ~14 seconds
8 thrds: ~12 seconds
16 thrds: ~9 seconds
We see dimishing returns towards the ends, though this is hardly surprising as a couple of the data sets we're iterating over on this test data have <16 members (so, we're generating 16 threads for, say a for-loop
with 7 iterations).
So, now the question remains - WHY does the cluster's performance degrade so badly. I'm going to try on a different quadcore linuxbox tonight. The cluster compiles with GNU-GCC 4.6.3, but I can't believe that in itself is going to make such a difference?
Neither ltrace
nor GDB
are installed on the cluster (and I can't get them on for various reasons). If my linuxbox gives cluster-like performance I'll run the corresponding ltrace
analysis there.
UPDATE 4
Oh my. I duel booted my Macbook Pro into Ubuntu (12.04) and re-ran the code. It all runs (which is somewhat reassuring) but I see the same, weird bad-performance behavior I see on the clusters, and the same run of millions of futex
calls. Given the only difference between my local machine in Ubuntu and in OSX is software (and I'm using the same compiler and libraries - presumably there aren't different glibc
implementations for OSX and Ubuntu!) I'm now wondering if this is something to do with how Linux schedules/distributes threads. Any case, being on my local machine makes everything a million times easier, so I'm going to go ahead and ltrace -f
it and see what I can find. I wrote a work around for the clusters which forks()
off a separate process, and gives a perfect 1/2 in the runtime, so it's definitely possible to get the parallelism going...
See Question&Answers more detail:
os