HPC/Applications/lammps
Benchmark
Using a sample workload from Sanket ("run9"), I tested various OpenMPI options on both node types.
LAMMPS performs best on gen2 nodes without extra options, and pretty well on gen1 nodes over ethernet(!).
Job tag | Node type | Interconnect | Additional OpenMPI options | Relative speed (1000 steps/3 hours) |
Notes |
---|---|---|---|---|---|
gen1 | gen1 | IB | (none) | 36 | |
gen1srqpin | gen1 | IB | -mca btl_openib_use_srq 1 -mca mpi_paffinity_alone 1 |
39 | |
gen1eth | gen1 | Ethernet | -mca btl self,tcp | 44 | fastest for gen1 |
gen2eth | gen2 | Ethernet | -mca btl self,tcp | 49 | |
gen2srq | gen2 | IB | -mca btl_openib_use_srq 1 | 59 | |
gen2 | gen2 | IB | (none) | 59 | fastest for gen2 |
Sample job file gen1
#!/bin/bash
#PBS -l nodes=10:ppn=8:gen1
#PBS -l walltime=1:00:00:00
#PBS -N <jobname>
#PBS -A <account>
#
#PBS -o job.out
#PBS -e job.err
#PBS -m ea
# change into the directory where qsub will be executed
cd $PBS_O_WORKDIR
mpirun -machinefile $PBS_NODEFILE \
-np $(wc -l < $PBS_NODEFILE) \
-mca btl self,tcp \
lmp_openmpi < lammps.in > lammps.out 2> lammps.err
Sample job file gen2
#!/bin/bash
#PBS -l nodes=10:ppn=8:gen2
#PBS -l walltime=1:00:00:00
#PBS -N <jobname>
#PBS -A <account>
#
#PBS -o job.out
#PBS -e job.err
#PBS -m ea
# change into the directory where qsub will be executed
cd $PBS_O_WORKDIR
mpirun -machinefile $PBS_NODEFILE \
-np $(wc -l < $PBS_NODEFILE) \
lmp_openmpi < lammps.in > lammps.out 2> lammps.err
MPI/OpenMP hybrid parallel runs
LAMMPS modules since 2012 are compiled with yes-user-omp
, permitting multi-threaded runs of selected pair styles, and in particular MPI/OpenMP hybrid parallel runs.
Be careful how to allocate CPU cores on compute nodes. Note the following:
- The number of MPI tasks running on a node is determined by the qsub
ppn=...
parameter. - The number of threads that each MPI task runs with is determined by the environment variable
OMP_NUM_THREADS
, which is 1 by default on Carbon. - The number of physical cores per node for gen1 and gen2 nodes is 8.
- gen2 nodes have hyperthreading active, meaning there are 16 logical cores per node. However:
- My (stern) own benchmarks for memory-intensive programs were underwhelming.
- The LAMMPS OpenMP author reports the same (near the end of the section):
Using threads on hyper-threading enabled cores is usually counterproductive, as the cost in additional memory bandwidth requirements is not offset by the gain in CPU utilization through hyper-threading.
- Reserve entire nodes by adding near the top of the job file:
#PBS -l naccesspolicy=SINGLEJOB
#!/bin/bash
#PBS -l nodes=2:ppn=4
#PBS -l walltime=1:00:00
#PBS -l naccesspolicy=SINGLEJOB
...
ppn_mpi=$( uniq -c $PBS_NODEFILE | awk '{print $1; exit}' ) # grab first (and usually only) ppn value of the job
ppn_logical=8 # number of cores on first execution node
#ppn_logical=12 # experimental: 3-to-2 oversubscription of physical cores (hyperthreading)
OMP_NUM_THREADS=$(( ppn_phys / ppn_mpi )) # calculate number of threads available per MPI process
mpirun -x OMP_NUM_THREADS \
-machinefile $PBS_NODEFILE \
-np $(wc -l < $PBS_NODEFILE) \
lmp_openmpi \
-sf omp \
-in in.script
LAMMPS echoes it parallelization scheme first thing in the output:
LAMMPS (10 Feb 2012) using 3 OpenMP thread(s) per MPI task ... 2 by 2 by 2 MPI processor grid Lattice spacing in x,y,z = 3.52 4.97803 4.97803 ...
and near the end:
Loop time of 11.473 on 24 procs (8 MPI x 3 OpenMP) for 100 steps with 32000 atoms
To learn more:
- HPC/Submitting_Jobs/Advanced node selection#Multithreading (OpenMP)
- Hints on using the OMP package
- Command-line options (explanation for -sf style or -suffix style)