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  1. New example migrated for Geant4 Version 10.0 Andrea Dotti Example still needs cleanup. For this reason for the moment we keep it separate from sequential version of the code

01.25.2009 Xin Dong: This example came from the original sequential program FullCMS. The original program is changed here to support parallel computing with multiple threads. All events are assigned to each worker thread in a round robin fashion. All threads share most detector data
including physics table and physics vector for some physics processes.
The master process initializes the data in a regular way. However, worker
threads initialize thread private data only.

We use the previous trick to introduce parallelism by implementating a new G4RunaManager subclass. However, both Geant4 kernel and CLHEP is changed accordingly. The original README is attached. Compile this example just as the original FullCMS. The executable file is named as ParmainApplication. One more argument is needed to give the number of workers. For example, use:

$G4BIN/$G4SYSTEM/ParmainApplication bench1.g4 8

to run this program. The third argument "8" is the number of worker threads that will be created. So the total number of threads for this application is 9.

The original README:


$Id: README,v 1.1 2007/10/24 12:38:34 gcosmo Exp $

Full CMS Benchmark

In this directory you can find a CPU benchmark test of Geant4 based on the full CMS detector, imported via a .gdml file.

To select a Physics List you have to define one of the following environmental variables:

  • LHEP : for the LHEP Physics List;
  • QGSP : for the QGSP Physics List;
  • QGSP_EMV : for the QGSP_EMV Physics List;
  • QGSC : for the QGSC Physics List;
  • FTFP : for the FTFP Physics List;
  • QGSP_BIC : for the QGSP_BIC Physics List;
  • QGSP_BERT : for the QGSP_BERT Physics List. For example, if you want to use QGSP_EMV Physics List you can do:
    export QGSP_EMV=1 or, equivalently: make QGSP_EMV=1

To build the application, first setup your environmental variables (the Bash-shell setup file, setup.sh , shows an example), and then do: make XXX=1 where "XXX" is the name of the Physics List, or, equivalently: export XXX=1 ; make and you get the executable: $G4BIN/$G4SYSTEM/mainApplication and to run it: $G4BIN/$G4SYSTEM/mainApplication bench1.g4

You can run this application with the following macro file:

  • bench1.g4 : 4000 events, each consisting of a beam particle shot into the full CMS detector, with a uniform magnetic field of 4 Tesla along the Z-axis. The beam particle has the following characteristics: o random particle type (draw with equal probability between: mu-, mu+, e-, e+, gamma, pi-, pi+, kaon-, kaon+, kaon0L, neutron, proton, anti_neutron, anti_proton, deuteron, triton, alpha, lambda, sigma+, sigma-, xi-, xi0, anti_lambda, anti_sigma+, anti_sigma-, anti_xi-, anti_xi0, omega-, anti_omega- ) o random kinetic energy (draw uniformily in the interval: 1 - 100 GeV ) o starting at the origin (0,0,0) o with initial random direction (draw uniformily in 4*pi). NB) You can change any of the above choices (for instance shooting always 50 GeV pi- in a given, fixed direction) by modifying the file: src/MyPrimaryGeneratorAction.cc .

The CPU time for this test can be obtained in two ways (which should be, more or less, in agreement):

  • Look at the value "User=..." at the end of the running, after the line "Run Summary": this is the total time, in seconds, for all (4000) events, excluding the initialization.
  • Use: time $G4BIN/$G4SYSTEM/mainApplication bench1.g4 when launching the program: you would get, at the end of the program, the value: "user ..." which is the total time for all (4000) events, including the initialization.

Finally, notice that the macro file starts with the same seed number (taken from the file start.rndm ), so if you run twice in the same machine you should get the same result, although the time can vary slightly due to the different condition of the machine.