int main (int __argc, char * * __argv) { peo :: init (__argc, __argv); if (getNodeRank()==1) std::cout<<"\n\nTest : multistart\n\n"; std::vector < double > v; if (getNodeRank()==1) std::cout<<"\n\nBefore :"; for (unsigned i = 0; i< 10; i++) { v.push_back(i); if (getNodeRank()==1) std::cout<<"\n"<<v[i]; } Algorithm algo; peoMultiStart < double > initParallel (algo); peoWrapper parallelAlgo (initParallel, v); initParallel.setOwner(parallelAlgo); peo :: run( ); peo :: finalize( ); if (getNodeRank()==1) { std::cout<<"\n\nAfter :\n"; for (unsigned i = 0; i< 10; i++) std::cout<<v[i]<<"\n"; } }
void initDebugging () { mkdir (DEBUG_PATH, S_IRWXU); // files.push_back (stdout); char buff [MAX_BUFF_SIZE]; sprintf (buff, "%s/%d", DEBUG_PATH, getNodeRank ()); files.push_back (fopen (buff, "w")); }
int main (int __argc, char *__argv[]) { peo :: init( __argc, __argv ); if (getNodeRank()==1) std::cout<<"\n\nTest : PSO Global Best\n\n"; rng.reseed (10); RingTopology topologyMig; eoGenContinue < Indi > genContPara (10); eoCombinedContinue <Indi> continuatorPara (genContPara); eoCheckPoint<Indi> checkpoint(continuatorPara); peoEvalFunc<Indi, double, const Indi& > plainEval(f); peoPopEval< Indi > eval(plainEval); eoUniformGenerator < double >uGen (0, 1.); eoInitFixedLength < Indi > random (2, uGen); eoUniformGenerator < double >sGen (-1., 1.); eoVelocityInitFixedLength < Indi > veloRandom (2, sGen); eoFirstIsBestInit < Indi > localInit; eoRealVectorBounds bndsFlight(2,0,1.); eoStandardFlight < Indi > flight(bndsFlight); eoPop < Indi > pop; pop.append (10, random); eoLinearTopology<Indi> topology(2); eoRealVectorBounds bnds(2,-1.,1.); eoStandardVelocity < Indi > velocity (topology,1,0.5,2.,bnds); eoInitializer <Indi> init(eval,veloRandom,localInit,topology,pop); eoPeriodicContinue< Indi > mig_cont( 2 ); peoPSOSelect<Indi> mig_selec(topology); peoGlobalBestVelocity<Indi> mig_replac (2.,velocity); eoContinuator<Indi> cont(mig_cont, pop); eoSelector <Indi, eoPop<Indi> > mig_select (mig_selec,1,pop); eoReplace <Indi, eoPop<Indi> > mig_replace (mig_replac,pop); eoGenContinue < Indi > genContPara2 (10); eoCombinedContinue <Indi> continuatorPara2 (genContPara2); eoCheckPoint<Indi> checkpoint2(continuatorPara2); peoEvalFunc<Indi, double, const Indi& > plainEval2(f); peoPopEval< Indi > eval2(plainEval2); eoUniformGenerator < double >uGen2 (0, 1.); eoInitFixedLength < Indi > random2 (2, uGen2); eoUniformGenerator < double >sGen2 (-1., 1.); eoVelocityInitFixedLength < Indi > veloRandom2 (2, sGen2); eoFirstIsBestInit < Indi > localInit2; eoRealVectorBounds bndsFlight2(2,0,1.); eoStandardFlight < Indi > flight2(bndsFlight2); eoPop < Indi > pop2; pop2.append (10, random2); eoLinearTopology<Indi> topology2(2); eoRealVectorBounds bnds2(2,-1.,1.); eoStandardVelocity < Indi > velocity2 (topology2,1,0.5,2.,bnds2); eoInitializer <Indi> init2(eval2,veloRandom2,localInit2,topology2,pop2); eoPeriodicContinue< Indi > mig_cont2( 2 ); peoPSOSelect<Indi> mig_selec2(topology2); peoGlobalBestVelocity<Indi> mig_replac2 (2.,velocity2); eoContinuator<Indi> cont2(mig_cont2,pop2); eoSelector <Indi, eoPop<Indi> > mig_select2 (mig_selec2,1,pop2); eoReplace <Indi, eoPop<Indi> > mig_replace2 (mig_replac2,pop2); peoAsyncIslandMig< eoPop<Indi>, eoPop<Indi> > mig(cont,mig_select, mig_replace, topologyMig); checkpoint.add( mig ); peoAsyncIslandMig< eoPop<Indi>, eoPop<Indi> > mig2(cont2,mig_select2, mig_replace2, topologyMig); checkpoint2.add( mig2 ); eoSyncEasyPSO <Indi> psa(init,checkpoint,eval, velocity, flight); peoWrapper parallelPSO( psa, pop); eval.setOwner(parallelPSO); mig.setOwner(parallelPSO); eoSyncEasyPSO <Indi> psa2(init2,checkpoint2,eval2, velocity2, flight2); peoWrapper parallelPSO2( psa2, pop2); eval2.setOwner(parallelPSO2); mig2.setOwner(parallelPSO2); peo :: run(); peo :: finalize(); if (getNodeRank()==1) { pop.sort(); pop2.sort(); std::cout << "Final population :\n" << pop << std::endl; std::cout << "Final population :\n" << pop2 << std::endl; } }
uint32_t DataHDDIOTensorQuantized::getBlockSize_( const uint32_t pos ) const { const uint32_t r = getNodeRank( pos ); return r*r*r*sizeof(byte); }
uint32_t DataHDDIOTensorBasic::getBlockSize_( const uint32_t pos ) const { const uint32_t r = getNodeRank( pos ); return r*r*r*sizeof(float); }