6

I am aware of this and this, but I ask again as the first link is pretty old now, and the second link did not seem to reach a conclusive answer. Has any consensus developed?

My problem is simple:

I have a DO loop that has elements that may be run concurrently. Which method do I use ?

Below is code to generate particles on a simple cubic lattice.

  • npart is the number of particles
  • npart_edge & npart_face are that along an edge and a face, respectively
  • space is the lattice spacing
  • Rx, Ry, Rz are position arrays
  • x, y, z are temporary variables to decide positon on lattice

Note the difference that x,y and z have to be arrays in the CONCURRENT case, but not so in the OpenMP case because they can be defined as being PRIVATE.

So do I use DO CONCURRENT (which, as I understand from the links above, uses SIMD) :

DO CONCURRENT (i = 1, npart)
    x(i) = MODULO(i-1, npart_edge)
    Rx(i) = space*x(i)
    y(i) = MODULO( ( (i-1) / npart_edge ), npart_edge)
    Ry(i) = space*y(i)
    z(i) = (i-1) / npart_face
    Rz(i) = space*z(i)
END DO

Or do I use OpenMP?

!$OMP PARALLEL DEFAULT(SHARED) PRIVATE(x,y,z)
!$OMP DO
DO i = 1, npart
    x = MODULO(i-1, npart_edge)
    Rx(i) = space*x
    y = MODULO( ( (i-1) / npart_edge ), npart_edge)
    Ry(i) = space*y
    z = (i-1) / npart_face
    Rz(i) = space*z
END DO
!$OMP END DO
!$OMP END PARALLEL

My tests:

Placing 64 particles in a box of side 10:

$ ifort -qopenmp -real-size 64 omp.f90
$ ./a.out 
CPU time =  6.870000000000001E-003
Real time =  3.600000000000000E-003

$ ifort -real-size 64 concurrent.f90 
$ ./a.out 
CPU time =  6.699999999999979E-005
Real time =  0.000000000000000E+000

Placing 100000 particles in a box of side 100:

$ ifort -qopenmp -real-size 64 omp.f90
$ ./a.out 
CPU time =  8.213300000000000E-002
Real time =  1.280000000000000E-002

$ ifort -real-size 64 concurrent.f90 
$ ./a.out 
CPU time =  2.385000000000000E-003
Real time =  2.400000000000000E-003

Using the DO CONCURRENT construct seems to be giving me at least an order of magnitude better performance. This was done on an i7-4790K. Also, the advantage of concurrency seems to decrease with increasing size.

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  • 1
    The assertion about x, y and z needing to be arrays in the DO CONCURRENT case is not a language requirement. How DO CONCURRENT is implemented also depends very much on compiler capability - lazy compilers may just implement it as an ordinary serial loop without any vectorization or parallelization. So the answer is... "It depends."
    – IanH
    Jul 24, 2016 at 7:58
  • 1
    @IanH What do you mean when you say that it is not a language requirement? I say that they have to be arrays because otherwise, those operations cannot be done concurrently. Also, I've added as an edit, info on performance.
    – physkets
    Jul 24, 2016 at 8:38
  • 1
    So what is the question now? DO CONCURRENT vs. OpenMP in general? Or how do I make this piece of code run faster? These are to VERY different questions. The general answer is to use what is faster, of course. Jul 24, 2016 at 8:45
  • 1
    @IanH okay, I read it and now I understand. So all it means is that the processor is allowed to perform the iterations in arbitrary order, which may or may not be concurrent. It really is a case of bad naming.
    – physkets
    Jul 24, 2016 at 10:02
  • 2
    Just because we have a shiny new feature: some documentation of do concurrent. Jul 24, 2016 at 11:18

1 Answer 1

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DO CONCURRENT does not do any parallelization per se. The compiler may decide to parallelize it using threads or use SIMD instructions or even offload to a GPU. For threads you often have to instruct it to do so. For GPU offloading you need a particular compiler with particular options. Or (often!), the compiler just treats DO CONCURENT as a regular DO and uses SIMD if it would use them for the regular DO.

OpenMP is also not just threads, the compiler can use SIMD instructions if it wants. There is also omp simd directive, but that is only a suggestion to the compiler to use SIMD, it can be ignored.

You should try, measure and see. There is no single definitive answer. Not even for a given compiler, the less for all compilers.

If you would not use OpenMP anyway, I would give DO CONCURRENT a try to see if the automatic parallelizer does a better job with this construct. Chances are good that it will help. If your code is already in OpenMP, I do not see any point introducing DO CONCURRENT.

My practice is to use OpenMP and try to make sure the compiler vectorizes (SIMD) what it can. Especially because I use OpenMP all over my program anyway. DO CONCURRENT still has to prove it is actually useful. I am not convinced, yet, but some GPU examples look promising - however, real codes are often much more complex.


Your specific examples and the performance measurement:

Too little code is given and there are subtle points in every benchmarking. I wrote some simple code around your loops and did my own tests. I was careful NOT to include the thread creation into the timed block. You should not include $omp parallel into your timing. I also took the minimum real time over multiple computations because sometimes the first take is longer (certainly with DO CONCURRENT). CPU has various throttle modes and may need some time to spin-up. I also added SCHEDULE(STATIC).

npart=10000000
ifort -O3 concurrent.f90: 6.117300000000000E-002
ifort -O3 concurrent.f90 -parallel: 5.044600000000000E-002
ifort -O3 concurrent_omp.f90: 2.419600000000000E-002

npart=10000, default 8 threads (hyper-threading)
ifort -O3 concurrent.f90: 5.430000000000000E-004
ifort -O3 concurrent.f90 -parallel: 8.899999999999999E-005
ifort -O3 concurrent_omp.f90: 1.890000000000000E-004

npart=10000, OMP_NUM_THREADS=4 (ignore hyper-threading)
ifort -O3 concurrent.f90: 5.410000000000000E-004
ifort -O3 concurrent.f90 -parallel: 9.200000000000000E-005
ifort -O3 concurrent_omp.f90: 1.070000000000000E-004

Here, DO CONCURRENT seems to be somewhat faster for the small case, but not too much if we make sure to use the right number of cores. It is clearly slower for the big case. The -parallel option is clearly necessary for the automatic parallelization.

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  • I've added the info you requested earlier as an edit. Also, I do use openmp elsewhere in my code, but there, concurrency will not help.
    – physkets
    Jul 24, 2016 at 8:36
  • ifort -qparallel requests parallelization of do concurrent. With the options given above, there would be only simd vectorization, which appears to be more efficient for your problem size. If your inner loop length is at most 100, splitting it into threaded chunks would remove most of the advantage of simd vectorization. BLOCK may be used within DO CONCURRENT to avoid making arrays for local variables.
    – tim18
    Jul 24, 2016 at 12:18
  • Guessing that you run with hyperthreads enabled, you will need to check parallel performance with fewer than default number of threads, setting OMP_PLACES=cores, before you conclude that parallel is too inefficient. There is little reason to expect do concurrent auto-parallel to perform different from OpenMP.
    – tim18
    Jul 24, 2016 at 12:26
  • @tim18 Better comment under the question. This answer was written before the details were revealed and does not reflect them at all. Jul 24, 2016 at 12:31
  • @tim18 So if I put a BLOCK inside the DO loop, the local vars of each iteration are independent? Is that more efficient than making an array? Also, why should I set omp to not use hyperthreads?
    – physkets
    Jul 24, 2016 at 19:49

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