// main04.cc is a part of the PYTHIA event generator. // Copyright (C) 2012 Torbjorn Sjostrand. // PYTHIA is licenced under the GNU GPL version 2, see COPYING for details. // Please respect the MCnet Guidelines, see GUIDELINES for details. // This is a simple test program. // It illustrates how to generate and study "total cross section" processes, // i.e. elastic, single and double diffractive, and the "minimum-bias" rest. // All input is specified in the main06.cmnd file. // Note that the "total" cross section does NOT include // the Coulomb contribution to elastic scattering, as switched on here. #include "Pythia.h" using namespace Pythia8; //========================================================================== int main() { // Generator. Shorthand for the event. Pythia pythia; Event& event = pythia.event; // Read in commands from external file. pythia.readFile("main04.cmnd"); // Extract settings to be used in the main program. int nEvent = pythia.mode("Main:numberOfEvents"); int nAbort = pythia.mode("Main:timesAllowErrors"); // Initialize. pythia.init(); // Book histograms: multiplicities and mean transverse momenta. Hist yChg("rapidity of charged particles; all", 100, -10., 10.); Hist nChg("number of charged particles; all", 100, -0.5, 799.5); Hist nChgSD("number of charged particles; single diffraction", 100, -0.5, 799.5); Hist nChgDD("number of charged particles, double diffractive", 100, -0.5, 799.5); Hist nChgCD("number of charged particles, central diffractive", 100, -0.5, 799.5); Hist nChgND("number of charged particles, non-diffractive", 100, -0.5, 799.5); Hist pTnChg("(n_charged) all", 100, -0.5, 799.5); Hist pTnChgSD("(n_charged) single diffraction", 100, -0.5, 799.5); Hist pTnChgDD("(n_charged) double diffraction", 100, -0.5, 799.5); Hist pTnChgCD("(n_charged) central diffraction", 100, -0.5, 799.5); Hist pTnChgND("(n_charged) non-diffractive ", 100, -0.5, 799.5); // Book histograms: ditto as function of separate subsystem mass. Hist mLogInel("log10(mass), by diffractive system", 100, 0., 5.); Hist nChgmLog("(log10(mass))", 100, 0., 5.); Hist pTmLog("_charged>(log10(mass))", 100, 0., 5.); // Book histograms: elastic/diffractive. Hist tSpecEl("elastic |t| spectrum", 100, 0., 1.); Hist tSpecElLog("elastic log10(|t|) spectrum", 100, -5., 0.); Hist tSpecSD("single diffractive |t| spectrum", 100, 0., 2.); Hist tSpecDD("double diffractive |t| spectrum", 100, 0., 5.); Hist tSpecCD("central diffractive |t| spectrum", 100, 0., 5.); Hist mSpec("diffractive mass spectrum", 100, 0., 100.); Hist mLogSpec("log10(diffractive mass spectrum)", 100, 0., 4.); // Book histograms: inelastic nondiffractive "minbias". double pTmax = 20.; double bMax = 4.; Hist pTspec("total pT_hard spectrum", 100, 0., pTmax); Hist pTspecND("nondiffractive pT_hard spectrum", 100, 0., pTmax); Hist bSpec("b impact parameter spectrum", 100, 0., bMax); Hist enhanceSpec("b enhancement spectrum", 100, 0., 10.); Hist number("number of interactions", 100, -0.5, 99.5); Hist pTb1("pT spectrum for b < 0.5", 100, 0., pTmax); Hist pTb2("pT spectrum for 0.5 < b < 1", 100, 0., pTmax); Hist pTb3("pT spectrum for 1 < b < 1.5", 100, 0., pTmax); Hist pTb4("pT spectrum for 1.5 < b", 100, 0., pTmax); Hist bpT1("b spectrum for pT < 2", 100, 0., bMax); Hist bpT2("b spectrum for 2 < pT < 5", 100, 0., bMax); Hist bpT3("b spectrum for 5 < pT < 15", 100, 0., bMax); Hist bpT4("b spectrum for 15 < pT", 100, 0., bMax); // Begin event loop. int iAbort = 0; for (int iEvent = 0; iEvent < nEvent; ++iEvent) { // Generate events. Quit if too many failures. if (!pythia.next()) { if (++iAbort < nAbort) continue; cout << " Event generation aborted prematurely, owing to error!\n"; break; } // Extract event classification. int code = pythia.info.code(); // Charged multiplicity and mean pT: all and by event class. int nch = 0; double pTsum = 0.; for (int i = 1; i < event.size(); ++i) if (event[i].isFinal() && event[i].isCharged()) { yChg.fill( event[i].y() ); ++nch; pTsum += event[i].pT(); } nChg.fill( nch ); if (nch > 0) pTnChg.fill( nch, pTsum/nch); if (code == 103 || code == 104) { nChgSD.fill( nch ); if (nch > 0) pTnChgSD.fill( nch, pTsum/nch); } else if (code == 105) { nChgDD.fill( nch ); if (nch > 0) pTnChgDD.fill( nch, pTsum/nch); } else if (code == 106) { nChgCD.fill( nch ); if (nch > 0) pTnChgCD.fill( nch, pTsum/nch); } else if (code == 101) { nChgND.fill( nch ); if (nch > 0) pTnChgND.fill( nch, pTsum/nch); double mLog = log10( event[0].m() ); mLogInel.fill( mLog ); nChgmLog.fill( mLog, nch ); if (nch > 0) pTmLog.fill( mLog, pTsum / nch ); } // Charged multiplicity and mean pT: per diffractive system. for (int iDiff = 0; iDiff < 3; ++iDiff) if ( (iDiff == 0 && pythia.info.isDiffractiveA()) || (iDiff == 1 && pythia.info.isDiffractiveB()) || (iDiff == 2 && pythia.info.isDiffractiveC()) ) { int ndiff = 0; double pTdiff = 0.; int nDoc = (iDiff < 2) ? 4 : 5; for (int i = nDoc + 1; i < event.size(); ++i) if (event[i].isFinal() && event[i].isCharged()) { // Trace back final particle to see which system it comes from. int k = i; do k = event[k].mother1(); while (k > nDoc); if (k == iDiff + 3) { ++ndiff; pTdiff += event[i].pT(); } } // Study diffractive mass spectrum. double mDiff = event[iDiff+3].m(); double mLog = log10( mDiff); mLogInel.fill( mLog ); nChgmLog.fill( mLog, ndiff ); if (ndiff > 0) pTmLog.fill( mLog, pTdiff / ndiff ); mSpec.fill( mDiff ); mLogSpec.fill( mLog ); } // Study pT spectrum of all hard collisions, no distinction. double pT = pythia.info.pTHat(); pTspec.fill( pT ); // Study t distribution of elastic/diffractive events. if (code > 101) { double tAbs = abs(pythia.info.tHat()); if (code == 102) { tSpecEl.fill(tAbs); tSpecElLog.fill(log10(tAbs)); } else if (code == 103 || code == 104) tSpecSD.fill(tAbs); else if (code == 105) tSpecDD.fill(tAbs); else if (code == 106) { double t1Abs = abs( (event[3].p() - event[1].p()).m2Calc() ); double t2Abs = abs( (event[4].p() - event[2].p()).m2Calc() ); tSpecCD.fill(t1Abs); tSpecCD.fill(t2Abs); } // Study nondiffractive inelastic events in (pT, b) space. } else { double b = pythia.info.bMPI(); double enhance = pythia.info.enhanceMPI(); int nMPI = pythia.info.nMPI(); pTspecND.fill( pT ); bSpec.fill( b ); enhanceSpec.fill( enhance ); number.fill( nMPI ); if (b < 0.5) pTb1.fill( pT ); else if (b < 1.0) pTb2.fill( pT ); else if (b < 1.5) pTb3.fill( pT ); else pTb4.fill( pT ); if (pT < 2.) bpT1.fill( b ); else if (pT < 5.) bpT2.fill( b ); else if (pT < 15.) bpT3.fill( b ); else bpT4.fill( b ); } // End of event loop. } // Final statistics and histograms. pythia.stat(); pTnChg /= nChg; pTnChgSD /= nChgSD; pTnChgDD /= nChgDD; pTnChgCD /= nChgCD; pTnChgND /= nChgND; nChgmLog /= mLogInel; pTmLog /= mLogInel; cout << yChg << nChg << nChgSD << nChgDD << nChgCD << nChgND << pTnChg << pTnChgSD << pTnChgDD << pTnChgCD << pTnChgND << mLogInel << nChgmLog << pTmLog << tSpecEl << tSpecElLog << tSpecSD << tSpecDD << tSpecCD << mSpec << mLogSpec << pTspec << pTspecND << bSpec << enhanceSpec << number << pTb1 << pTb2 << pTb3 << pTb4 << bpT1 << bpT2 << bpT3 << bpT4; // Done. return 0; }