GW parallel strategies: Difference between revisions
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'''This modules contains very general discussions of the parallel environment of Yambo. | |||
<!-- | |||
Still the actual run of the code is specific to the CECAM cluster. If you want to run it just replace the parallel queue instructions with simple MPI commands. THIS PAGE NEEDS TO BE UPDATED''' | |||
--> | |||
In this tutorial we will see how to setup the variables governing the parallel execution of yambo in order to perform efficient calculations in terms of both cpu time and memory to solution. As a test case we will consider the hBN 2D material. Because of its reduced dimensionality, GW calculations turns out to be very delicate. Beside the usual convergence studies with respect to k-points and sums-over-bands, in low dimensional systems a sensible amount of vacuum is required in order to treat the system as isolated, translating into a large number of plane-waves. As for other tutorials, it is important to stress that this tutorial it is meant to illustrate the functionality of the key variables and to run in reasonable time, so it has not the purpose to reach the desired accuracy to reproduce experimental results. Moreover please also note that scaling performance illustrated below may be significantly dependent on the underlying parallel architecture. Nevertheless, general considerations are tentatively drawn in discussing the results. | In this tutorial we will see how to setup the variables governing the parallel execution of yambo in order to perform efficient calculations in terms of both cpu time and memory to solution. As a test case we will consider the hBN 2D material. Because of its reduced dimensionality, GW calculations turns out to be very delicate. Beside the usual convergence studies with respect to k-points and sums-over-bands, in low dimensional systems a sensible amount of vacuum is required in order to treat the system as isolated, translating into a large number of plane-waves. As for other tutorials, it is important to stress that this tutorial it is meant to illustrate the functionality of the key variables and to run in reasonable time, so it has not the purpose to reach the desired accuracy to reproduce experimental results. Moreover please also note that scaling performance illustrated below may be significantly dependent on the underlying parallel architecture. Nevertheless, general considerations are tentatively drawn in discussing the results. | ||
== Getting familiar with yambo in parallel == | == Getting familiar with yambo in parallel == | ||
Let's start by copying the tutorial files in the cluster and unzip them in the folder you will run the tutorial. | |||
$ mkdir YAMBO_TUTORIALS | |||
$ cd YAMBO_TUTORIALS | |||
$ cp $path/hBN-2D-para.tar.gz ./ | |||
$ cp | |||
$ tar -zxvf hBN-2D-para.tar.gz | $ tar -zxvf hBN-2D-para.tar.gz | ||
$ cd ./hBN-2D-para/YAMBO | |||
$ cd | |||
Under the YAMBO folder, together with the SAVE folder, you will see the run.sh script | Under the YAMBO folder, together with the SAVE folder, you will see the run.sh script | ||
$ ls | $ ls | ||
parse_qp.py parse_ytiming.py SAVE | |||
First run the initialization as usual. | First, run the initialization as usual. | ||
Then you need to generate the input file for a GW run. | Then you need to generate the input file for a GW run. | ||
$ yambo -g n -p p -F yambo_gw.in | $ yambo -g n -p p -F yambo_gw.in | ||
After setting the variables in red, the new input file should look like the following: | |||
$ cat yambo_gw.in | $ cat yambo_gw.in | ||
ppa # [R Xp] Plasmon Pole Approximation | ppa # [R Xp] Plasmon Pole Approximation | ||
gw0 # [R GW] GoWo Quasiparticle energy levels | gw0 # [R GW] GoWo Quasiparticle energy levels | ||
HF_and_locXC # [R XX] Hartree-Fock Self-energy and Vxc | HF_and_locXC # [R XX] Hartree-Fock Self-energy and Vxc | ||
em1d # [R Xd] Dynamical Inverse Dielectric Matrix | em1d # [R Xd] Dynamical Inverse Dielectric Matrix | ||
X_Threads= 0 # [OPENMP/X] Number of threads for response functions | |||
DIP_Threads= 0 # [OPENMP/X] Number of threads for dipoles | |||
SE_Threads= 0 # [OPENMP/GW] Number of threads for self-energy | |||
EXXRLvcs= 21817 RL # [XX] Exchange RL components | EXXRLvcs= 21817 RL # [XX] Exchange RL components | ||
VXCRLvcs= 21817 RL # [XC] XCpotential RL components | |||
Chimod= "" # [X] IP/Hartree/ALDA/LRC/BSfxc | Chimod= "" # [X] IP/Hartree/ALDA/LRC/BSfxc | ||
% BndsRnXp | % BndsRnXp | ||
1 | <span style="color: red"> | 1 | <span style="color: red">300</span> | # [Xp] Polarization function bands | ||
% | % | ||
NGsBlkXp= <span style="color: red">4 Ry</span> # [Xp] Response block size | NGsBlkXp= <span style="color: red">4 Ry</span> # [Xp] Response block size | ||
Line 58: | Line 43: | ||
PPAPntXp= 27.21138 eV # [Xp] PPA imaginary energy | PPAPntXp= 27.21138 eV # [Xp] PPA imaginary energy | ||
% GbndRnge | % GbndRnge | ||
1 | <span style="color: red"> | 1 | <span style="color: red">300</span> | # [GW] G[W] bands range | ||
% | % | ||
GDamping= 0.10000 eV # [GW] G[W] damping | GDamping= 0.10000 eV # [GW] G[W] damping | ||
Line 64: | Line 49: | ||
DysSolver= "n" # [GW] Dyson Equation solver ("n","s","g") | DysSolver= "n" # [GW] Dyson Equation solver ("n","s","g") | ||
%QPkrange # [GW] QP generalized Kpoint/Band indices | %QPkrange # [GW] QP generalized Kpoint/Band indices | ||
1| <span style="color: red">1| | 1| <span style="color: red">4| 1| 8</span>| | ||
% | % | ||
Now you need to create a submission script. here below an example (run.sh) based on the SLURM scheduler. In the case of other schedulers, the header should be updated accordingly. | |||
$ cat run.sh | $ cat run.sh | ||
Line 74: | Line 59: | ||
#SBATCH -t 06:00:00 | #SBATCH -t 06:00:00 | ||
#SBATCH -J test | #SBATCH -J test | ||
#SBATCH -- | #SBATCH --partition=<span style="color:red"><queue name></span> | ||
#SBATCH --tasks-per-node=<span style="color:red">1</span> | #SBATCH --tasks-per-node=<span style="color:red">1</span> | ||
#SBATCH --cpus-per-task=<span style="color:red">1</span> | |||
nodes=1 | nodes=1 | ||
tasks_per_node=<span style="color:red">1</span> | |||
nthreads=1 | nthreads=1 | ||
ncpu=`echo $nodes $ | ncpu=`echo $nodes $tasks_per_node | awk '{print $1*$2}'` | ||
module purge | module purge | ||
module load | module load <span style="color:red"><needed modules></span> | ||
module load | module load <span style="color:red"><more modules></span> | ||
bindir=/ | bindir=<span style="color:red"><path to yambo bindir></span> | ||
export OMP_NUM_THREADS=$nthreads | export OMP_NUM_THREADS=$nthreads | ||
Line 97: | Line 84: | ||
cp -f $filein0 $filein | cp -f $filein0 $filein | ||
cat >> $filein << EOF | cat >> $filein << EOF | ||
DIP_CPU= "1 $ncpu 1" # [PARALLEL] CPUs for each role | |||
DIP_ROLEs= "k c v" # [PARALLEL] CPUs roles (k,c,v) | |||
X_Threads= 0 | DIP_Threads= 0 # [OPENMP/X] Number of threads for dipoles | ||
X_and_IO_CPU= "1 1 1 $ncpu 1" # [PARALLEL] CPUs for each role | |||
SE_CPU= " | X_and_IO_ROLEs= "q g k c v" # [PARALLEL] CPUs roles (q,g,k,c,v) | ||
SE_ROLEs= "q qp b" | X_and_IO_nCPU_LinAlg_INV= $ncpu # [PARALLEL] CPUs for Linear Algebra | ||
X_Threads= 0 # [OPENMP/X] Number of threads for response functions | |||
SE_CPU= " 1 $ncpu 1" # [PARALLEL] CPUs for each role | |||
SE_ROLEs= "q qp b" # [PARALLEL] CPUs roles (q,qp,b) | |||
SE_Threads= 0 | SE_Threads= 0 | ||
Line 109: | Line 99: | ||
echo "Running on $ncpu MPI, $nthreads OpenMP threads" | echo "Running on $ncpu MPI, $nthreads OpenMP threads" | ||
mpirun -np $ncpu $bindir/yambo -F $filein -J $jdir -C $cdir | |||
As soon as you are ready submit the job. | As soon as you are ready to submit the job. | ||
$ sbatch run.sh | $ sbatch run.sh | ||
Line 119: | Line 109: | ||
As you can see, monitoring the log file produced by yambo, the run takes some time, although | As you can see, monitoring the log file produced by yambo, the run takes some time, although | ||
we are using minimal parameters. | we are using minimal parameters. | ||
The status of the jobs can be monitored via: | |||
$ squeue -u $USER # to inspect the status of jobs | |||
# (hint: make a unix alias, if you like) | |||
$ scancel <jobid> # to delete jobs in the queue | |||
== Pure MPI scaling with default parallelization scheme == | == Pure MPI scaling with default parallelization scheme == | ||
Meanwhile we can run the code in parallel. Let's use 16 MPI | Meanwhile we can run the code in parallel. Let's use consider the case of a node having 16 cores (you can try to adapt the following discussion to the actual maximum number of | ||
To this end modify the | cores/node you have in your system). As a first run, we'll use 16 MPI tasks, still with a single thread. | ||
To this end modify the run.sh script changing | |||
#SBATCH --tasks-per-node=<span style="color:red">16</span> | #SBATCH --tasks-per-node=<span style="color:red">16</span> | ||
#SBATCH --cpus-per-task=<span style="color:red">1</span> | |||
ntasks_per_node=<span style="color:red">16</span> | |||
nthreads=<span style="color:red">1</span> | |||
This time the code should be much faster. | This time the code should be much faster. | ||
Once the run is over try to run the simulation also on 2, 4, 8. | Once the run is over try to run the simulation also on 2, 4, 8 MPI tasks. | ||
Each time please remember to change both the number of tasks per node and the | Each time, please remember to change both the number of tasks per node both in the header and in the <code>ntasks_per_node</code> variable. | ||
Finally, you can try to produce a scaling plot. | |||
To analyze the data you can use the phyton | To analyze the data you can use the phyton script parse_ytiming.py run which is provided. | ||
You can use it running | You can use it running | ||
$ ./ | $ ./parse_ytiming.py run*/r-* | ||
You should obtain something like that (but with more columns) | You should obtain something like that (but with more columns) | ||
# ncores | # ncores dip Xo X io_X io_WF Sgm_x Sgm_c (REDUX) WALL_TIME | ||
1 | 1 4.7337s 13m39.00s 0.1500s 0.0241s 0.2487s 34.2143s 15m7.00s 0.0000s 29m29s | ||
4 1.6019s 218.7982s 0.0882s 0.0283s 0.2077s 9.3338s 242.4438s 0.0001s 07m54s | |||
8 1.0755s 127.3209s 0.0974s 0.0291s 0.2134s 5.4490s 140.7788s 0.6926s 04m38s | |||
12 0.7510s 89.1649s 0.1015s 0.0299s 0.2068s 4.2961s 109.1227s 0.0007s 03m26s | |||
16 | 16 0.7653s 68.2550s 0.1048s 0.0309s 0.2463s 2.9211s 72.6220s 0.2799s 02m27s | ||
Plot the execution time vs the number of MPI tasks | Plot the execution time vs the number of MPI tasks | ||
and check (do a log plot) how far you are from the ideal linear scaling. | and check (do a log plot) how far you are from the ideal linear scaling. | ||
Below a similar plot | Below a similar plot produced on a local cluster equipped with two Intel(R) Xeon(R) Silver 4208 CPU @ 2.10GHz processors per node (16 physical cares/node). | ||
[[File: | [[File:scaling_MPI_corvina.jpg|750px|center]] | ||
'''tips:''' <br> | |||
* not all runlevels scale in in the same way <br> | |||
* you should never overload the available number of cores | |||
== Pure OpenMP scaling == | == Pure OpenMP scaling == | ||
Line 157: | Line 158: | ||
Next step is instead to check the OpenMP scaling. | Next step is instead to check the OpenMP scaling. | ||
Set back | Set back | ||
#SBATCH --tasks-per-node=<span style="color:red">16</span> | #SBATCH --tasks-per-node=<span style="color:red">1</span> | ||
#SBATCH --cpus-per-task=<span style="color:red">16</span> | |||
and now use | and now use | ||
ntasks_per_node=<span style="color:red">1</span> | |||
nthreads=<span style="color:red">16</span> | nthreads=<span style="color:red">16</span> | ||
ncpu | |||
Since we are already using 16 threads, we cannot also distribute among MPI tasks, i.e. ncpu will result equal to 1. | |||
Try setting nthreads to 16, 8, 4 and 2 and again to plot the execution time vs the number of threads using the python script. | |||
Again you should be able to produce data similar to the following. In the following we stopped increasing the number of threads up to 8 because of the | |||
specific architecture used in the runs (a dual socket machine with 8 cores/socket). | |||
# ncores threads dip Xo X io_X io_WF Sgm_x Sgm_c WALL_TIME | |||
1 1 4.7337s 13m39.00s 0.1500s 0.0241s 0.2487s 34.2143s 15m7.00s 29m29s | |||
2 2 3.1971s 549.1491s 0.2248s 0.0298s 0.2491s 17.6552s 584.3692s 19m17s | |||
4 4 2.9419s 358.5202s 0.1928s 0.0289s 0.2590s 9.2010s 421.2219s 13m15s | |||
8 8 2.7992s 344.3342s 0.2332s 0.0325s 0.2543s 5.4334s 362.6982s 11m58s | |||
'''tips:''' <br> | |||
* OpenMP usually shares the memory among threads, but not always <br> | |||
* you should never overload the available number of cores <br> | |||
* in principle, we could overload the cores setting more threads than the available total number of cores since a single core allows multi-thread operations | |||
== MPI vs OpenMP scaling == | == MPI vs OpenMP scaling == | ||
Which is scaling better ? MPI or OpenMP ? | Which is scaling better ? MPI or OpenMP? | ||
How is the memory distributed ? | How is the memory distributed? | ||
Now you can try running | Now you can try running simulations with hybrid strategies. | ||
Try for example setting: | Try for example setting: | ||
#SBATCH --tasks-per-node=<span style="color:red"> | #SBATCH --tasks-per-node=<span style="color:red">8</span> | ||
#SBATCH --cpus-per-task=<span style="color:red">2</span> | |||
ntasks_per_node= <span style="color:red">8</span> | |||
nthreads= <span style="color:red">2</span> | |||
We can try to do scaling keeping the total number of | We can try to do scaling keeping the total number of threads per node (ntasks_per_node * nthreads) equal to 16. | ||
Parsing the data we will obtain something similar to | Parsing the data we will obtain something similar to | ||
# ncores MPI threads dip Xo X io_X io_WF Sgm_x Sgm_c WALL_TIME | |||
16 2 8 3.6816s 386.0552s 0.0856s 0.0268s 0.2163s 18.9077s 530.0875s 15m43s | |||
16 4 4 0.9950s 82.5070s 0.1098s 0.0299s 0.2051s 3.0837s 122.6565s 03m32s | |||
16 8 2 0.8524s 72.6708s 0.0986s 0.0293s 0.2282s 3.0379s 88.1589s 02m48s | |||
16 16 1 0.7653s 68.2550s 0.1048s 0.0309s 0.2463s 2.9211s 72.6220s 02m27s | |||
As you can see here the total CPU time decreases more and more moving the parallelization from | As you can see here the total CPU time decreases more and more moving the parallelization from the OpenMP to the MPI level. | ||
Sigma_c in particular scales better. | Sigma_c in particular scales better. Nevertheless, note that the relative performance of the different parallel configurations | ||
may strongly depend on the actual machine you are running on. | |||
However CPU time is not the only parameter you need to check. | However, CPU time is not the only parameter you need to check. | ||
The <b>total memory usage</b> is also very critical since the GW method may have a large memory footprint. | |||
If you have compiled yambo with the flag <code>--enable-memory-profile</code>, the memory usage is tracked and the maximum allocated mem | |||
is printed in the report file, and can be extracted typing: | |||
$ grep "Max memory used" <report_file> | |||
<!-- | |||
If you compare for example the two extreme cases (you can use) | If you compare for example the two extreme cases (you can use) | ||
$ grep Gb | $ grep Gb run_MPI1_OMP*/l* | grep Alloc (use this for the case with only one MPI proc) | ||
$ grep Gb | $ grep Gb run_MPI*_OMP*/LOG/l*_1 | grep Alloc (use this for the case with more than one MPI proc) | ||
For the case | For the case | ||
Line 219: | Line 235: | ||
Multiplying by 16 you obtain an estimate of the total memory: 0.091*16=1.456 (0.076*16=1.216) | Multiplying by 16 you obtain an estimate of the total memory: 0.091*16=1.456 (0.076*16=1.216) | ||
These last two numbers have to be compared with 0.321 (0.306) | These last two numbers have to be compared with 0.321 (0.306) | ||
--> | |||
In general yambo can distribute memory when using MPI parallelism (though the actual amount depends on the distribution of MPI tasks across MPI levels). | |||
OpenMP | Nevertheless, some memory replication is still present. In general, within the node OpenMP helps in easing the memory usage. Therefore, in cases where the node memori is | ||
tight, one may consider changing some MPI tasks for OpenMP threads within the node. | |||
Using a hybrid scheme you may also consider running yambo on mode than one node. | |||
To run on two nodes for example you need to set | |||
#SBATCH -N <span style="color:red">2</span> | |||
nodes=<span style="color:red">2</span> | |||
accordingly you can now set | |||
nthreads= <span style="color:red">4</span> | |||
This time you will use 32 cores with (16 per node) 4 OpenMP threads and 2*16/4=8 MPI tasks. | |||
'''tips:''' <br> | |||
* in real life calculations running on n_cores > 100, it is a good idea to adopt a hybrid approach <br> | |||
* with OpenMP, you cannot exit the single node, with MPI you can | |||
== Advanced: Comparing different parallelization schemes (optional) == | == Advanced: Comparing different parallelization schemes (optional) == | ||
Up to now we used the default parallelization scheme. | Up to now, we used the default parallelization scheme. | ||
Yambo also allows you to tune the parameters which controls the parallelization scheme. | Yambo also allows you to tune the parameters which controls the parallelization scheme. | ||
To this end you can open again the job.sh script and modify the section where the yambo input | To this end, you can open again the job.sh script and modify the section where the yambo input | ||
variables are set | variables are set | ||
X_and_IO_CPU= "<span style="color:red">1 1 1 $ncpu 1</span>" # [PARALLEL] CPUs for each role | |||
X_and_IO_ROLEs= "q g k c v" # [PARALLEL] CPUs roles (q,g,k,c,v) | |||
# | #X_and_IO_nCPU_LinAlg_INV= $ncpu # [PARALLEL] CPUs for Linear Algebra | ||
X_Threads= 0 # [OPENMP/X] Number of threads for response functions | X_Threads= 0 # [OPENMP/X] Number of threads for response functions | ||
DIP_Threads= 0 # [OPENMP/X] Number of threads for dipoles | DIP_Threads= 0 # [OPENMP/X] Number of threads for dipoles | ||
SE_CPU= "<span style="color:red">1 1 $ncpu</span>" | SE_CPU= "<span style="color:red">1 1 $ncpu</span>" # [PARALLEL] CPUs for each role | ||
SE_ROLEs= "q qp b" | SE_ROLEs= "q qp b" # [PARALLEL] CPUs roles (q,qp,b) | ||
SE_Threads= 0 | SE_Threads= 0 | ||
In particular " | In particular, "X_and_IO_CPU" sets how the MPI Tasks are distributed in the calculation of the response function. | ||
The possibilities are shown in the " | The possibilities are shown in the "X_and_IO_ROLEs". The same holds for "SE_CPU" and "SE_ROLEs" which control | ||
how MPI Tasks are distributed in the calculation of the response function. | how MPI Tasks are distributed in the calculation of the response function. | ||
Please try different parallelization schemes and check the performances of Yambo. | Please try different parallelization schemes and check the performances of Yambo. | ||
In | In doing so, you should also change the jobname in the run.sh script | ||
For more details see also the [[Using_Yambo_in_parallel|Parallel module]] | label=MPI${ncpu}_OMP${nthreads}<span style="color:red">_scheme1</span> | ||
Using the python script, you can then check how speed, memory and load balance between the CPUs are affected. | |||
For more details, see also the [[Using_Yambo_in_parallel|Parallel module]] | |||
'''tips: <br>''' | |||
* the product of the numbers entering each variable (i.e. X_and_IO_CPU and SE_CPU) times the number of threads should always match the total number of cores (unless you want to overload the cores taking advantage of multi-threads) <br> | |||
* using the X_Threads and SE_Threads variables, you can think about setting different Hybrid schemes in between the screening and the self-energy runlevel. | |||
* memory better scales if you parallelize on bands (c v b) <br> | |||
* parallelization on k-points performs similarly to parallelization on bands, but memory requires more memory <br> | |||
* parallelization on q-points requires much less communication in between the MPI tasks. It may be useful if you run on more than one node and the internode connection is slow | |||
<br> | <br> |
Latest revision as of 20:46, 30 May 2023
This modules contains very general discussions of the parallel environment of Yambo. In this tutorial we will see how to setup the variables governing the parallel execution of yambo in order to perform efficient calculations in terms of both cpu time and memory to solution. As a test case we will consider the hBN 2D material. Because of its reduced dimensionality, GW calculations turns out to be very delicate. Beside the usual convergence studies with respect to k-points and sums-over-bands, in low dimensional systems a sensible amount of vacuum is required in order to treat the system as isolated, translating into a large number of plane-waves. As for other tutorials, it is important to stress that this tutorial it is meant to illustrate the functionality of the key variables and to run in reasonable time, so it has not the purpose to reach the desired accuracy to reproduce experimental results. Moreover please also note that scaling performance illustrated below may be significantly dependent on the underlying parallel architecture. Nevertheless, general considerations are tentatively drawn in discussing the results.
Getting familiar with yambo in parallel
Let's start by copying the tutorial files in the cluster and unzip them in the folder you will run the tutorial.
$ mkdir YAMBO_TUTORIALS $ cd YAMBO_TUTORIALS $ cp $path/hBN-2D-para.tar.gz ./ $ tar -zxvf hBN-2D-para.tar.gz $ cd ./hBN-2D-para/YAMBO
Under the YAMBO folder, together with the SAVE folder, you will see the run.sh script
$ ls parse_qp.py parse_ytiming.py SAVE
First, run the initialization as usual. Then you need to generate the input file for a GW run.
$ yambo -g n -p p -F yambo_gw.in
After setting the variables in red, the new input file should look like the following:
$ cat yambo_gw.in
ppa # [R Xp] Plasmon Pole Approximation gw0 # [R GW] GoWo Quasiparticle energy levels HF_and_locXC # [R XX] Hartree-Fock Self-energy and Vxc em1d # [R Xd] Dynamical Inverse Dielectric Matrix X_Threads= 0 # [OPENMP/X] Number of threads for response functions DIP_Threads= 0 # [OPENMP/X] Number of threads for dipoles SE_Threads= 0 # [OPENMP/GW] Number of threads for self-energy EXXRLvcs= 21817 RL # [XX] Exchange RL components VXCRLvcs= 21817 RL # [XC] XCpotential RL components Chimod= "" # [X] IP/Hartree/ALDA/LRC/BSfxc % BndsRnXp 1 | 300 | # [Xp] Polarization function bands % NGsBlkXp= 4 Ry # [Xp] Response block size % LongDrXp 1.000000 | 0.000000 | 0.000000 | # [Xp] [cc] Electric Field % PPAPntXp= 27.21138 eV # [Xp] PPA imaginary energy % GbndRnge 1 | 300 | # [GW] G[W] bands range % GDamping= 0.10000 eV # [GW] G[W] damping dScStep= 0.10000 eV # [GW] Energy step to evaluate Z factors DysSolver= "n" # [GW] Dyson Equation solver ("n","s","g") %QPkrange # [GW] QP generalized Kpoint/Band indices 1| 4| 1| 8| %
Now you need to create a submission script. here below an example (run.sh) based on the SLURM scheduler. In the case of other schedulers, the header should be updated accordingly.
$ cat run.sh #!/bin/bash #SBATCH -N 1 #SBATCH -t 06:00:00 #SBATCH -J test #SBATCH --partition=<queue name> #SBATCH --tasks-per-node=1 #SBATCH --cpus-per-task=1 nodes=1 tasks_per_node=1 nthreads=1 ncpu=`echo $nodes $tasks_per_node | awk '{print $1*$2}'` module purge module load <needed modules> module load <more modules> bindir=<path to yambo bindir> export OMP_NUM_THREADS=$nthreads label=MPI${ncpu}_OMP${nthreads} jdir=run_${label} cdir=run_${label}.out filein0=yambo_gw.in filein=yambo_gw_${label}.in cp -f $filein0 $filein cat >> $filein << EOF DIP_CPU= "1 $ncpu 1" # [PARALLEL] CPUs for each role DIP_ROLEs= "k c v" # [PARALLEL] CPUs roles (k,c,v) DIP_Threads= 0 # [OPENMP/X] Number of threads for dipoles X_and_IO_CPU= "1 1 1 $ncpu 1" # [PARALLEL] CPUs for each role X_and_IO_ROLEs= "q g k c v" # [PARALLEL] CPUs roles (q,g,k,c,v) X_and_IO_nCPU_LinAlg_INV= $ncpu # [PARALLEL] CPUs for Linear Algebra X_Threads= 0 # [OPENMP/X] Number of threads for response functions SE_CPU= " 1 $ncpu 1" # [PARALLEL] CPUs for each role SE_ROLEs= "q qp b" # [PARALLEL] CPUs roles (q,qp,b) SE_Threads= 0 EOF echo "Running on $ncpu MPI, $nthreads OpenMP threads" mpirun -np $ncpu $bindir/yambo -F $filein -J $jdir -C $cdir
As soon as you are ready to submit the job.
$ sbatch run.sh
Yambo calculates the GW-qp corrections running on 1 MPI process with a single thread. As you can see, monitoring the log file produced by yambo, the run takes some time, although we are using minimal parameters.
The status of the jobs can be monitored via:
$ squeue -u $USER # to inspect the status of jobs # (hint: make a unix alias, if you like) $ scancel <jobid> # to delete jobs in the queue
Pure MPI scaling with default parallelization scheme
Meanwhile we can run the code in parallel. Let's use consider the case of a node having 16 cores (you can try to adapt the following discussion to the actual maximum number of cores/node you have in your system). As a first run, we'll use 16 MPI tasks, still with a single thread. To this end modify the run.sh script changing
#SBATCH --tasks-per-node=16 #SBATCH --cpus-per-task=1
ntasks_per_node=16 nthreads=1
This time the code should be much faster.
Once the run is over try to run the simulation also on 2, 4, 8 MPI tasks.
Each time, please remember to change both the number of tasks per node both in the header and in the ntasks_per_node
variable.
Finally, you can try to produce a scaling plot.
To analyze the data you can use the phyton script parse_ytiming.py run which is provided.
You can use it running
$ ./parse_ytiming.py run*/r-*
You should obtain something like that (but with more columns)
# ncores dip Xo X io_X io_WF Sgm_x Sgm_c (REDUX) WALL_TIME 1 4.7337s 13m39.00s 0.1500s 0.0241s 0.2487s 34.2143s 15m7.00s 0.0000s 29m29s 4 1.6019s 218.7982s 0.0882s 0.0283s 0.2077s 9.3338s 242.4438s 0.0001s 07m54s 8 1.0755s 127.3209s 0.0974s 0.0291s 0.2134s 5.4490s 140.7788s 0.6926s 04m38s 12 0.7510s 89.1649s 0.1015s 0.0299s 0.2068s 4.2961s 109.1227s 0.0007s 03m26s 16 0.7653s 68.2550s 0.1048s 0.0309s 0.2463s 2.9211s 72.6220s 0.2799s 02m27s
Plot the execution time vs the number of MPI tasks
and check (do a log plot) how far you are from the ideal linear scaling.
Below a similar plot produced on a local cluster equipped with two Intel(R) Xeon(R) Silver 4208 CPU @ 2.10GHz processors per node (16 physical cares/node).
tips:
- not all runlevels scale in in the same way
- you should never overload the available number of cores
Pure OpenMP scaling
Next step is instead to check the OpenMP scaling. Set back
#SBATCH --tasks-per-node=1 #SBATCH --cpus-per-task=16
and now use
ntasks_per_node=1 nthreads=16
Since we are already using 16 threads, we cannot also distribute among MPI tasks, i.e. ncpu will result equal to 1. Try setting nthreads to 16, 8, 4 and 2 and again to plot the execution time vs the number of threads using the python script. Again you should be able to produce data similar to the following. In the following we stopped increasing the number of threads up to 8 because of the specific architecture used in the runs (a dual socket machine with 8 cores/socket).
# ncores threads dip Xo X io_X io_WF Sgm_x Sgm_c WALL_TIME 1 1 4.7337s 13m39.00s 0.1500s 0.0241s 0.2487s 34.2143s 15m7.00s 29m29s 2 2 3.1971s 549.1491s 0.2248s 0.0298s 0.2491s 17.6552s 584.3692s 19m17s 4 4 2.9419s 358.5202s 0.1928s 0.0289s 0.2590s 9.2010s 421.2219s 13m15s 8 8 2.7992s 344.3342s 0.2332s 0.0325s 0.2543s 5.4334s 362.6982s 11m58s
tips:
- OpenMP usually shares the memory among threads, but not always
- you should never overload the available number of cores
- in principle, we could overload the cores setting more threads than the available total number of cores since a single core allows multi-thread operations
MPI vs OpenMP scaling
Which is scaling better ? MPI or OpenMP? How is the memory distributed?
Now you can try running simulations with hybrid strategies. Try for example setting:
#SBATCH --tasks-per-node=8 #SBATCH --cpus-per-task=2
ntasks_per_node= 8 nthreads= 2
We can try to do scaling keeping the total number of threads per node (ntasks_per_node * nthreads) equal to 16. Parsing the data we will obtain something similar to
# ncores MPI threads dip Xo X io_X io_WF Sgm_x Sgm_c WALL_TIME 16 2 8 3.6816s 386.0552s 0.0856s 0.0268s 0.2163s 18.9077s 530.0875s 15m43s 16 4 4 0.9950s 82.5070s 0.1098s 0.0299s 0.2051s 3.0837s 122.6565s 03m32s 16 8 2 0.8524s 72.6708s 0.0986s 0.0293s 0.2282s 3.0379s 88.1589s 02m48s 16 16 1 0.7653s 68.2550s 0.1048s 0.0309s 0.2463s 2.9211s 72.6220s 02m27s
As you can see here the total CPU time decreases more and more moving the parallelization from the OpenMP to the MPI level. Sigma_c in particular scales better. Nevertheless, note that the relative performance of the different parallel configurations may strongly depend on the actual machine you are running on.
However, CPU time is not the only parameter you need to check.
The total memory usage is also very critical since the GW method may have a large memory footprint.
If you have compiled yambo with the flag --enable-memory-profile
, the memory usage is tracked and the maximum allocated mem
is printed in the report file, and can be extracted typing:
$ grep "Max memory used" <report_file>
In general yambo can distribute memory when using MPI parallelism (though the actual amount depends on the distribution of MPI tasks across MPI levels). Nevertheless, some memory replication is still present. In general, within the node OpenMP helps in easing the memory usage. Therefore, in cases where the node memori is tight, one may consider changing some MPI tasks for OpenMP threads within the node.
Using a hybrid scheme you may also consider running yambo on mode than one node.
To run on two nodes for example you need to set
#SBATCH -N 2 nodes=2
accordingly you can now set
nthreads= 4
This time you will use 32 cores with (16 per node) 4 OpenMP threads and 2*16/4=8 MPI tasks.
tips:
- in real life calculations running on n_cores > 100, it is a good idea to adopt a hybrid approach
- with OpenMP, you cannot exit the single node, with MPI you can
Advanced: Comparing different parallelization schemes (optional)
Up to now, we used the default parallelization scheme. Yambo also allows you to tune the parameters which controls the parallelization scheme. To this end, you can open again the job.sh script and modify the section where the yambo input variables are set
X_and_IO_CPU= "1 1 1 $ncpu 1" # [PARALLEL] CPUs for each role X_and_IO_ROLEs= "q g k c v" # [PARALLEL] CPUs roles (q,g,k,c,v) #X_and_IO_nCPU_LinAlg_INV= $ncpu # [PARALLEL] CPUs for Linear Algebra X_Threads= 0 # [OPENMP/X] Number of threads for response functions DIP_Threads= 0 # [OPENMP/X] Number of threads for dipoles SE_CPU= "1 1 $ncpu" # [PARALLEL] CPUs for each role SE_ROLEs= "q qp b" # [PARALLEL] CPUs roles (q,qp,b) SE_Threads= 0
In particular, "X_and_IO_CPU" sets how the MPI Tasks are distributed in the calculation of the response function. The possibilities are shown in the "X_and_IO_ROLEs". The same holds for "SE_CPU" and "SE_ROLEs" which control how MPI Tasks are distributed in the calculation of the response function.
Please try different parallelization schemes and check the performances of Yambo. In doing so, you should also change the jobname in the run.sh script
label=MPI${ncpu}_OMP${nthreads}_scheme1
Using the python script, you can then check how speed, memory and load balance between the CPUs are affected. For more details, see also the Parallel module
tips:
- the product of the numbers entering each variable (i.e. X_and_IO_CPU and SE_CPU) times the number of threads should always match the total number of cores (unless you want to overload the cores taking advantage of multi-threads)
- using the X_Threads and SE_Threads variables, you can think about setting different Hybrid schemes in between the screening and the self-energy runlevel.
- memory better scales if you parallelize on bands (c v b)
- parallelization on k-points performs similarly to parallelization on bands, but memory requires more memory
- parallelization on q-points requires much less communication in between the MPI tasks. It may be useful if you run on more than one node and the internode connection is slow
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