dna/moleculardna/ecoli.C

0001 //-------------------------------------------------------------------------------//
0002 // This macrofile was developed by Konstantinos Chatzipapas at LP2iB (ex. CENBG) //
0003 // in collaboration with the whole team of molecularDNA Geant4-DNA example       //
0004 // For any question please contact through:                                      //
0005 // k.chatzipapas@yahoo.com                                                       //
0006 //-------------------------------------------------------------------------------//
0007 //
0008 // This macro requires the molecular-dna.root file generated from molecularDNA example
0009 // To run this file just insert this command to the terminal:
0010 // root .X ecoli.C
0011 // ROOT6.x should be installed
0012 //
0013 //***************************************//
0014 // Please define the parameters below    //
0015 // ifile, r3, Nbp (as shown in terminal) //
0016 //***************************************//
0017
0018 {
0019 //*******************************************************************************//
0020 // If you need to add multiple root outputs, by multithreading, use this command:
0021 system ("hadd -O -f molecular-dna.root molecular-dna_t*.root");
0022
0023 // Define these parameters of the simulation
0024 char ifile[256] = "molecular-dna.root";  // input filepath
0025 Double_t r3 = 900e-9 * 400e-9 * 400e-9;  // a * b * c   // Chromosome size, as defined in the mac file, but in meters. If sphere, a=b=c
0026 Double_t Nbp = 4.629360; // Mbp // Length of the DNA chain in Mbp
0027 Double_t mass = 997 * 4 * 3.141592 * r3 / 3 ;  // waterDensity * 4/3 * pi * r3 in kg
0028 ///////////////////////////////////////////////////////////////////////////////////
0029 //*******************************************************************************//
0030
0031 typedef std::pair <int64_t, int64_t> ipair;
0032 bool greaterPair(const ipair &l, const ipair &r);
0033 bool smallerPair(const ipair &l, const ipair &r);
0034
0035 void BinLogX(TH1 *h);
0036
0037 gROOT->Reset();
0038 gStyle->SetPalette(1);
0039 gROOT->SetStyle("Plain");
0040 gStyle->SetOptStat(00000);
0041
0042 // Initialize output histograms
0043 TCanvas *cfragment = new TCanvas("cfragment","DNA Fragments Distribution", 900, 120, 600,400);
0044 cfragment->SetLogx();
0045 cfragment->SetLogy();
0046 TH1F *h1fragments = new TH1F("h1fragments","h1fragments",40,0,5);
0047 BinLogX(h1fragments);
0048
0049 TCanvas *c1 = new TCanvas("c1", "Molecular DNA - Damage Quantification", 60, 120, 800, 800);
0050 c1->SetBorderSize(0);
0051 c1->SetFillColor(0);
0052 c1->SetFillStyle(4000);
0053 gPad->SetLeftMargin(0.13);
0054
0055 TPad* pad1 = new TPad("pad1","Species", 0, 0.51, 0.49, 1);
0056 pad1->SetBorderSize(0);
0057 pad1->SetFillColor(0);
0058 pad1->SetFillStyle(4000);
0059 pad1->SetLeftMargin(0.15);
0060 pad1->SetRightMargin(0.01);
0061 pad1->SetBottomMargin(0.2);
0062
0063 TPad* pad2 = new TPad("pad2","Damage Yield", 0.51, 0.5, 1, 1);
0064 pad2->SetBorderSize(0);
0065 pad2->SetFillColor(0);
0066 pad2->SetFillStyle(4000);
0067 pad2->SetLeftMargin(0.15);
0068 pad2->SetRightMargin(0.05);
0069 pad2->SetBottomMargin(0.2);
0070
0071 TPad* pad3 = new TPad("pad3","Breaks Yield SSB", 0, 0, 0.49, 0.49);
0072 pad3->SetBorderSize(0);
0073 pad3->SetFillColor(0);
0074 pad3->SetFillStyle(4000);
0075 pad3->SetLeftMargin(0.15);
0076 pad3->SetRightMargin(0.01);
0077 //pad3->SetTopMargin(0.2);
0078 pad3->SetBottomMargin(0.2);
0079
0080 TPad* pad4 = new TPad("pad4","Breaks Yield DSB", 0.51, 0, 1, 0.49);
0081 pad4->SetBorderSize(0);
0082 pad4->SetFillColor(0);
0083 pad4->SetFillStyle(4000);
0084 pad4->SetLeftMargin(0.15);
0085 pad4->SetRightMargin(0.05);
0086 //pad3->SetTopMargin(0.2);
0087 pad4->SetBottomMargin(0.2);
0088
0089 pad1->Draw();
0090 pad2->Draw();
0091 pad3->Draw();
0092 pad4->Draw();
0093
0094 // Open root file
0095 TFile *f = TFile::Open(ifile);
0096
0097 // Initialize Variables
0098 Int_t EB, ES, OHB, OHS, HB, HS, FL;
0099 Int_t total_EB, total_ES, total_OHB, total_OHS, total_HB, total_HS, total_FL;
0100 Float_t total_EB2, total_ES2, total_OHB2, total_OHS2, total_HB2, total_HS2, total_FL2;
0101 Float_t SD_EB, SD_ES, SD_OHB, SD_OHS, SD_HB, SD_HS;
0102 Float_t SD_SSB, SD_SSBp, SD_SSB2p, SD_sSSB, SD_SSBd, SD_SSBi, SD_SSBm;
0103 Float_t SD_DSB, SD_DSBp, SD_DSBpp, SD_sDSB, SD_DSBd, SD_DSBi, SD_DSBm, SD_DSBh;
0104
0105 Int_t SSB, SSBp, SSB2p;
0106 Int_t total_SSB, total_SSBp, total_SSB2p;
0107 Float_t total_SSB2, total_SSBp2, total_SSB2p2;
0108 Int_t DSB, DSBp, DSBpp;
0109 Int_t total_DSB, total_DSBp, total_DSBpp;
0110 Float_t total_DSB2, total_DSBp2, total_DSBpp2;
0111
0112 Int_t SSBd, SSBi, SSBm;
0113 Int_t total_sSSB, total_SSBd, total_SSBi, total_SSBm;
0114 Float_t total_sSSB2, total_SSBd2, total_SSBi2, total_SSBm2;
0115 Int_t DSBd, DSBi, DSBm, DSBh;
0116 Int_t total_sDSB, total_DSBd, total_DSBi, total_DSBm, total_DSBh;
0117 Float_t total_sDSB2, total_DSBd2, total_DSBi2, total_DSBm2, total_DSBh2;
0118
0119 Double_t dose = 0;
0120 Double_t SD_dose = 0;
0121
0122 Double_t EB_yield = 0; Double_t ES_yield = 0; Double_t OHB_yield = 0; Double_t OHS_yield = 0; Double_t HB_yield = 0; Double_t HS_yield = 0;
0123 Double_t SD_EB_yield = 0; Double_t SD_ES_yield = 0; Double_t SD_OHB_yield = 0; Double_t SD_OHS_yield = 0; Double_t SD_HB_yield = 0; Double_t SD_HS_yield = 0;
0124
0125 Double_t SSB_yield = 0; Double_t SSBp_yield = 0; Double_t SSB2p_yield = 0;
0126 Double_t SD_SSB_yield = 0; Double_t SD_SSBp_yield = 0; Double_t SD_SSB2p_yield = 0;
0127 Double_t DSB_yield = 0; Double_t DSBp_yield = 0; Double_t DSBpp_yield = 0;
0128 Double_t SD_DSB_yield = 0; Double_t SD_DSBp_yield = 0; Double_t SD_DSBpp_yield = 0;
0129
0130 Double_t sSSB_yield = 0; Double_t SSBi_yield = 0; Double_t SSBd_yield = 0; Double_t SSBm_yield = 0;
0131 Double_t SD_sSSB_yield = 0; Double_t SD_SSBi_yield = 0; Double_t SD_SSBd_yield = 0; Double_t SD_SSBm_yield = 0;
0132 Double_t sDSB_yield = 0; Double_t DSBi_yield = 0; Double_t DSBd_yield = 0; Double_t DSBm_yield = 0; Double_t DSBh_yield = 0;
0133 Double_t SD_sDSB_yield = 0; Double_t SD_DSBi_yield = 0; Double_t SD_DSBd_yield = 0; Double_t SD_DSBm_yield = 0; Double_t SD_DSBh_yield = 0;
0134
0135 total_EB  = 0; total_ES = 0; total_OHB = 0; total_OHS = 0; total_HB = 0; total_HS = 0;
0136
0137 total_SSB  = 0; total_SSBp = 0; total_SSB2p = 0;
0138 total_SSB2  = 0; total_SSBp2 = 0; total_SSB2p2 = 0;
0139 total_DSB  = 0; total_DSBp = 0; total_DSBpp = 0;
0140 total_DSB2  = 0; total_DSBp2 = 0; total_DSBpp2 = 0;
0141
0142 total_sSSB = 0; total_SSBd = 0; total_SSBi = 0; total_SSBm = 0;
0143 total_sSSB2 = 0; total_SSBd2 = 0; total_SSBi2 = 0; total_SSBm2 = 0;
0144 total_sDSB = 0; total_DSBd = 0; total_DSBi = 0; total_DSBm = 0; total_DSBh = 0;
0145 total_sDSB2 = 0; total_DSBd2 = 0; total_DSBi2 = 0; total_DSBm2 = 0;  total_DSBh2 = 0;
0146
0147 Double_t eVtoJ = 1.60218e-19;
0148 Double_t EnergyDeposited_eV = 0;
0149 Double_t acc_edep = 0;
0150 Double_t acc_edep2 = 0;
0151
0152 Double_t Energy;
0153 Double_t BPID;
0154 Char_t Primary;
0155 char *primaryName = new char[32];
0156 char *type= new char[256];
0157
0158 // Read trees and leaves from root file, and give values to variables
0159 TTree* tree = (TTree*) f->Get("tuples/primary_source");
0160 Float_t number = (Float_t) tree->GetEntries();
0161
0162 if (number<2) {
0163   std::cout << "Not enough entries in the \"primary_source\" TTree (" << (long)number << " entries)\n";
0164   gApplication->Terminate(0);
0165 }
0166
0167 vector<pair<int,int64_t>> DSBBPID;
0168
0169 // For reading species production
0170 tree = (TTree*) f->Get("tuples/damage");
0171 tree->SetBranchAddress("Primary",           &Primary);
0172 tree->SetBranchAddress("Energy",            &Energy);
0173 tree->SetBranchAddress("EaqBaseHits",       &EB);
0174 tree->SetBranchAddress("EaqStrandHits",     &ES);
0175 tree->SetBranchAddress("OHBaseHits",        &OHB);
0176 tree->SetBranchAddress("OHStrandHits",      &OHS);
0177 tree->SetBranchAddress("HBaseHits",         &HB);
0178 tree->SetBranchAddress("HStrandHits",       &HS);
0179 tree->SetBranchAddress("TypeClassification", type);
0180 tree->SetBranchAddress("BasePair",          &BPID);
0181
0182
0183 Long64_t nentries = tree->GetEntries();
0184 for(int i = 0;i<nentries;i++){
0185   tree->GetEntry(i);
0186
0187   total_EB   += EB;
0188   total_EB2  += pow(EB,2);
0189   total_ES   += ES;
0190   total_ES2  += pow(ES,2);
0191   total_OHB  += OHB;
0192   total_OHB2 += pow(OHB,2);
0193   total_OHS  += OHS;
0194   total_OHS2 += pow(OHS,2);
0195   total_HB   += HB;
0196   total_HB2  += pow(HB,2);
0197   total_HS   += HS;
0198   total_HS2  += pow(HS,2);
0199
0200   if((string)type=="DSB"||(string)type=="DSB+"||(string)type=="DSB++"){
0201     //cout << "DSB:"<<type<<endl;
0202     DSBBPID.push_back(make_pair(i,(int64_t)BPID));
0203     }
0204
0205   }
0206
0207 // Find the number of fragments that have been produced, but first test if there are enough breaks.
0208 // If no more than 2 DSBs exist in the DSBBPID vector ( DSBBPID.size() is 0 or 1 ),
0209 // the subtraction DSBBPID.size() - 1 makes the loop condition evaluate to ie < -1 (in unsigned terms,
0210 // this becomes a large number, which is incorrect) and leads to undefined behavior (crash).
0211 if (DSBBPID.size() < 2) {
0212     std::cerr << "Not enough damage to create fragments distribution." << std::endl;
0213     //return;
0214 }
0215 if (DSBBPID.size() >= 2) {
0216   // Sort DSBs from the one with lower ID value to the one with higher ID value
0217   sort(DSBBPID.begin(),  DSBBPID.end(), smallerPair);
0218   for(int ie = 0;ie<DSBBPID.size()-1;ie++){
0219     int64_t dsbfragment = DSBBPID[ie+1].second-DSBBPID[ie].second;
0220
0221     double val       = (double)dsbfragment/1000.;
0222     double meanw     = h1fragments->GetBinCenter(h1fragments->FindBin(val));
0223     double binw      = h1fragments->GetBinWidth (h1fragments->FindBin(val));
0224     h1fragments->Fill(val,1./binw/1000);//bp-1
0225     //cout <<"val:"<<val<<endl;
0226     }
0227 }
0228
0229 // Calculate the SEM
0230 SD_EB  = sqrt(abs(((total_EB2  / number) - pow(total_EB  / number,2)))/(number -1));
0231 SD_ES  = sqrt(abs(((total_ES2  / number) - pow(total_ES  / number,2)))/(number -1));
0232 SD_OHB = sqrt(abs(((total_OHB2 / number) - pow(total_OHB / number,2)))/(number -1));
0233 SD_OHS = sqrt(abs(((total_OHS2 / number) - pow(total_OHS / number,2)))/(number -1));
0234 SD_HB  = sqrt(abs(((total_HB2  / number) - pow(total_HB  / number,2)))/(number -1));
0235 SD_HS  = sqrt(abs(((total_HS2  / number) - pow(total_HS  / number,2)))/(number -1));
0236
0237 // Read damage classification SSB, SSB+, 2SSB, DSB, DSB+, DSB++
0238 // As they have been defined in: Nikjoo, H., O’Neill, O., Goodhead, T., & Terrissol, M. 1997,
0239 // Computational modelling of low-energy electron-induced DNA damage by early physical
0240 // and chemical events, International Journal of Radiation Biology, 71, 467.
0241 tree = (TTree *) f->Get("tuples/classification");
0242 tree->SetBranchAddress("Primary",&Primary);
0243 tree->SetBranchAddress("Energy", &Energy);
0244 tree->SetBranchAddress("SSB",    &SSB);
0245 tree->SetBranchAddress("SSBp",   &SSBp);
0246 tree->SetBranchAddress("2SSB",   &SSB2p);
0247 tree->SetBranchAddress("DSB",    &DSB);
0248 tree->SetBranchAddress("DSBp",   &DSBp);
0249 tree->SetBranchAddress("DSBpp",  &DSBpp);
0250
0251
0252 Long64_t nentriesC = tree->GetEntries();
0253 for(int i = 0;i<nentriesC;i++){
0254   tree->GetEntry(i);
0255
0256   total_SSBp   += SSBp;
0257   total_SSBp2  += pow(SSBp,2);
0258   total_SSB2p  += SSB2p;
0259   total_SSB2p2 += pow(SSB2p,2);
0260   total_SSB    += SSB;
0261   total_SSB2   += pow(SSB,2);
0262
0263   total_DSBp   += DSBp;
0264   total_DSBp2  += pow(DSBp,2);
0265   total_DSBpp  += DSBpp;
0266   total_DSBpp2 += pow(DSBpp,2);
0267   total_DSB    += DSB;
0268   total_DSB2   += pow(DSB,2);
0269
0270   }
0271
0272 // Calculate the SEM
0273 SD_SSB   = sqrt(abs(((total_SSB2   / number) - pow(total_SSB   / number,2)))/(number -1));
0274 SD_SSBp  = sqrt(abs(((total_SSBp2  / number) - pow(total_SSBp  / number,2)))/(number -1));
0275 SD_SSB2p = sqrt(abs(((total_SSB2p2 / number) - pow(total_SSB2p / number,2)))/(number -1));
0276
0277 SD_DSB   = sqrt(abs(((total_DSB2   / number) - pow(total_DSB   / number,2)))/(number -1));
0278 SD_DSBp  = sqrt(abs(((total_DSBp2  / number) - pow(total_DSBp  / number,2)))/(number -1));
0279 SD_DSBpp = sqrt(abs(((total_DSBpp2 / number) - pow(total_DSBpp / number,2)))/(number -1));
0280
0281 // Read damage classification SSBd, SSBi, SSBm, DSBd, DSBi, DSBm, DSBh
0282 // As they have been defined in: Nikjoo, H., O’Neill, O., Goodhead, T., & Terrissol, M. 1997,
0283 // Computational modelling of low-energy electron-induced DNA damage by early physical
0284 // and chemical events, International Journal of Radiation Biology, 71, 467.
0285 tree = (TTree *) f->Get("tuples/source");
0286 tree->SetBranchAddress("Primary",primaryName);
0287 tree->SetBranchAddress("Energy", &Energy);
0288 tree->SetBranchAddress("SSBd",   &SSBd);
0289 tree->SetBranchAddress("SSBi",   &SSBi);
0290 tree->SetBranchAddress("SSBm",   &SSBm);
0291 tree->SetBranchAddress("DSBd",   &DSBd);
0292 tree->SetBranchAddress("DSBi",   &DSBi);
0293 tree->SetBranchAddress("DSBm",   &DSBm);
0294 tree->SetBranchAddress("DSBh",   &DSBh);
0295
0296 Long64_t nentriesS = tree->GetEntries();
0297 for(int i = 0;i<nentriesS;i++){
0298   tree->GetEntry(i);
0299
0300   total_SSBd += SSBd;
0301   total_SSBd2 += pow((SSBd),2);
0302   total_SSBi += SSBi;
0303   total_SSBi2 += pow((SSBi),2);
0304   total_SSBm += SSBm;
0305   total_SSBm2 += pow((SSBm),2);
0306   total_sSSB += SSBd + SSBi + SSBm;
0307   total_sSSB2 += pow((SSBd+SSBi+SSBm),2);
0308
0309   total_DSBd  += DSBd;
0310   total_DSBd2 += pow(DSBd,2);
0311   total_DSBi  += DSBi;
0312   total_DSBi2 += pow(DSBi,2);
0313   total_DSBm  += DSBm;
0314   total_DSBm2 += pow(DSBm,2);
0315   total_DSBh  += DSBh;
0316   total_DSBh2 += pow(DSBh,2);
0317   total_sDSB  += DSBd + DSBi + DSBm + DSBh;
0318   total_sDSB2 += pow((DSBd+DSBi+DSBm+DSBh),2);
0319
0320   }
0321
0322 // Calculate the SEM
0323 SD_sSSB = sqrt(abs(((total_sSSB2 / number) - pow(total_sSSB / number,2)))/(number -1));
0324 SD_SSBd = sqrt(abs(((total_SSBd2 / number) - pow(total_SSBd / number,2)))/(number -1));
0325 SD_SSBi = sqrt(abs(((total_SSBi2 / number) - pow(total_SSBi / number,2)))/(number -1));
0326 SD_SSBm = sqrt(abs(((total_SSBm2 / number) - pow(total_SSBm / number,2)))/(number -1));
0327
0328 SD_sDSB = sqrt(abs(((total_sDSB2 / number) - pow(total_sDSB / number,2)))/(number -1));
0329 SD_DSBd = sqrt(abs(((total_DSBd2 / number) - pow(total_DSBd / number,2)))/(number -1));
0330 SD_DSBi = sqrt(abs(((total_DSBi2 / number) - pow(total_DSBi / number,2)))/(number -1));
0331 SD_DSBm = sqrt(abs(((total_DSBm2 / number) - pow(total_DSBm / number,2)))/(number -1));
0332 SD_DSBh = sqrt(abs(((total_DSBh2 / number) - pow(total_DSBh / number,2)))/(number -1));
0333
0334 // Measure the Deposited Energy in the whole volume that includes DNA chain (chromosome)
0335
0336 tree = (TTree *) f->Get("tuples/chromosome_hits");
0337 tree->SetBranchAddress("e_chromosome_kev",&EnergyDeposited_eV);
0338 nentries = tree->GetEntries();
0339 for(int i = 0;i<nentries;i++){
0340   tree->GetEntry(i);
0341   acc_edep += EnergyDeposited_eV *1e3;
0342   acc_edep2 += EnergyDeposited_eV *EnergyDeposited_eV *1e6;
0343 }
0344 tree->SetBranchAddress("e_dna_kev",&EnergyDeposited_eV);
0345 nentries = tree->GetEntries();
0346 for(int i = 0;i<nentries;i++){
0347   tree->GetEntry(i);
0348   acc_edep += EnergyDeposited_eV *1e3;
0349   acc_edep2 += EnergyDeposited_eV *EnergyDeposited_eV *1e6;
0350 }
0351
0352 // Close the root file to free space
0353 f->Close();
0354
0355 // Calculate the absorbed dose
0356 dose = acc_edep * eVtoJ / mass;
0357
0358 // This is a normalization factor to produce the output in Gy-1 Gbp-1, or else.
0359 // Default value is 1 to produce the result in Gy-1 Mbp-1
0360 // It changes Mbp to Gbp. Some other changes may be needed in graphs section (name of axes)
0361 double norm = 1;
0362
0363 // Calculate the yields, together with their error
0364 EB_yield  = (Double_t) total_EB  / dose / Nbp;
0365 ES_yield  = (Double_t) total_ES  / dose / Nbp;
0366 OHB_yield = (Double_t) total_OHB / dose / Nbp;
0367 OHS_yield = (Double_t) total_OHS / dose / Nbp;
0368 HB_yield  = (Double_t) total_HB  / dose / Nbp;
0369 HS_yield  = (Double_t) total_HS  / dose / Nbp;
0370
0371 SD_EB_yield  = SD_EB  / dose / Nbp;
0372 SD_ES_yield  = SD_ES  / dose / Nbp;
0373 SD_OHB_yield = SD_OHB / dose / Nbp;
0374 SD_OHS_yield = SD_OHS / dose / Nbp;
0375 SD_HB_yield  = SD_HB  / dose / Nbp;
0376 SD_HS_yield  = SD_HS  / dose / Nbp;
0377
0378
0379 SSB_yield   = (Double_t) norm * total_SSB   / dose / Nbp;
0380 SSBp_yield  = (Double_t) norm * total_SSBp  / dose / Nbp;
0381 SSB2p_yield = (Double_t) norm * total_SSB2p / dose / Nbp;
0382
0383 DSB_yield   = (Double_t) norm * total_DSB   / dose / Nbp;
0384 DSBp_yield  = (Double_t) norm * total_DSBp  / dose / Nbp;
0385 DSBpp_yield = (Double_t) norm * total_DSBpp / dose / Nbp;
0386
0387 SD_SSB_yield   = norm * SD_SSB   / dose / Nbp;
0388 SD_SSBp_yield  = norm * SD_SSBp  / dose / Nbp;
0389 SD_SSB2p_yield = norm * SD_SSB2p / dose / Nbp;
0390
0391 SD_DSB_yield   = norm * SD_DSB   / dose / Nbp;
0392 SD_DSBp_yield  = norm * SD_DSBp  / dose / Nbp;
0393 SD_DSBpp_yield = norm * SD_DSBpp / dose / Nbp;
0394
0395
0396 sSSB_yield = (Double_t) norm * total_sSSB / dose / Nbp;
0397 SSBi_yield = (Double_t) norm * total_SSBi / dose / Nbp;
0398 SSBd_yield = (Double_t) norm * total_SSBd / dose / Nbp;
0399 SSBm_yield = (Double_t) norm * total_SSBm / dose / Nbp;
0400
0401 sDSB_yield = (Double_t) norm * total_sDSB / dose / Nbp;
0402 DSBi_yield = (Double_t) norm * total_DSBi / dose / Nbp;
0403 DSBd_yield = (Double_t) norm * total_DSBd / dose / Nbp;
0404 DSBm_yield = (Double_t) norm * total_DSBm / dose / Nbp;
0405 DSBh_yield = (Double_t) norm * total_DSBh / dose / Nbp;
0406
0407 SD_sSSB_yield = norm * SD_sSSB / dose / Nbp;
0408 SD_SSBi_yield = norm * SD_SSBi / dose / Nbp;
0409 SD_SSBd_yield = norm * SD_SSBd / dose / Nbp;
0410 SD_SSBm_yield = norm * SD_SSBm / dose / Nbp;
0411
0412 SD_sDSB_yield = norm * SD_sDSB / dose / Nbp;
0413 SD_DSBi_yield = norm * SD_DSBi / dose / Nbp;
0414 SD_DSBd_yield = norm * SD_DSBd / dose / Nbp;
0415 SD_DSBm_yield = norm * SD_DSBm / dose / Nbp;
0416 SD_DSBh_yield = norm * SD_DSBh / dose / Nbp;
0417
0418
0419 // Print output in terminal
0420
0421 float total_SSB_totalYield = SSB_yield + SSBp_yield + SSB2p_yield;
0422 float total_DSB_totalYield = DSB_yield + DSBp_yield + DSBpp_yield;
0423
0424 cout<<"\n"                      <<ifile         <<'\n'
0425     <<"\nDose Absorbed (Gy): "  <<dose          <<'\n'
0426     <<"Particle : "             <<primaryName   <<'\t'
0427     <<"Energy (MeV) : "         <<Energy        <<'\t'
0428     <<"Number of Primaries : "  <<number        <<'\n'
0429     <<"  Output Damage : "                      <<'\n'<<'\t'
0430     <<"     Species Hits (Gy-1 Mbp-1) "      <<'\n'<<'\t'
0431     <<"EaqBaseHits   : "     <<EB_yield     <<"   \t"      <<" error %: "   <<100*SD_EB_yield/EB_yield        <<'\n'<<'\t'
0432     <<"EaqStrandHits : "     <<ES_yield     <<"   \t"      <<" error %: "   <<100*SD_ES_yield/ES_yield        <<'\n'<<'\t'
0433     <<"OHBaseHits    : "     <<OHB_yield    <<"   \t"      <<" error %: "   <<100*SD_OHB_yield/OHB_yield      <<'\n'<<'\t'
0434     <<"OHStrandHits  : "     <<OHS_yield    <<"   \t"      <<" error %: "   <<100*SD_OHS_yield/OHS_yield      <<'\n'<<'\t'
0435     <<"HBaseHits     : "     <<HB_yield     <<"   \t"      <<" error %: "   <<100*SD_HB_yield/HB_yield        <<'\n'<<'\t'
0436     <<"HStrandHits   : "     <<HS_yield     <<"   \t"      <<" error %: "   <<100*SD_HS_yield/HS_yield        <<'\n'<<'\n'<<'\t'
0437     <<"     Damage yield (Gy-1 Mbp-1) "      <<'\n'<<'\t'
0438     <<"SSB           : "     <<SSB_yield    <<"   \t"      <<" error %: "   <<100*SD_SSB_yield/SSB_yield      <<'\n'<<'\t'
0439     <<"SSB+          : "     <<SSBp_yield   <<"   \t"      <<" error %: "   <<100*SD_SSBp_yield/SSBp_yield    <<'\n'<<'\t'
0440     <<"2SSB          : "     <<SSB2p_yield  <<"   \t"      <<" error %: "   <<100*SD_SSB2p_yield/SSB2p_yield  <<'\n'<<'\t'
0441     <<"SSB total     : "     <<total_SSB_totalYield        <<'\n'<<'\t'
0442     <<"DSB           : "     <<DSB_yield    <<"   \t"      <<" error %: "   <<100*SD_DSB_yield/DSB_yield     <<'\n'<<'\t'
0443     <<"DSB+          : "     <<DSBp_yield   <<"   \t"      <<" error %: "   <<100*SD_DSBp_yield/DSBp_yield   <<'\n'<<'\t'
0444     <<"DSB++         : "     <<DSBpp_yield  <<"   \t"      <<" error %: "   <<100*SD_DSBpp_yield/DSBpp_yield <<'\n'<<'\t'
0445     <<"DSB total     : "     <<total_DSB_totalYield        <<'\n'<<'\n'<<'\t'
0446     <<"     Breaks yield (Gy-1 Mbp-1) "      <<'\n'<<'\t'
0447     <<"SSB direct    : "     <<SSBd_yield   <<"   \t"      <<" error %: "   <<100*SD_SSBd_yield/SSBd_yield   <<'\n'<<'\t'
0448     <<"SSB indirect  : "     <<SSBi_yield   <<"   \t"      <<" error %: "   <<100*SD_SSBi_yield/SSBi_yield   <<'\n'<<'\t'
0449     <<"SSB mixed     : "     <<SSBm_yield   <<"   \t"      <<" error %: "   <<100*SD_SSBm_yield/SSBi_yield   <<'\n'<<'\t'
0450     <<"SSB total     : "     <<sSSB_yield   <<"   \t"      <<" error %: "   <<100*SD_sSSB_yield/sSSB_yield   <<'\n'<<'\t'
0451     <<"DSB direct    : "     <<DSBd_yield   <<"   \t"      <<" error %: "   <<100*SD_DSBd_yield/DSBd_yield   <<'\n'<<'\t'
0452     <<"DSB indirect  : "     <<DSBi_yield   <<"   \t"      <<" error %: "   <<100*SD_DSBi_yield/DSBi_yield   <<'\n'<<'\t'
0453     <<"DSB mixed     : "     <<DSBm_yield   <<"   \t"      <<" error %: "   <<100*SD_DSBm_yield/DSBm_yield   <<'\n'<<'\t'
0454     <<"DSB hybrid    : "     <<DSBh_yield   <<"   \t"      <<" error %: "   <<100*SD_DSBh_yield/DSBh_yield   <<'\n'<<'\t'
0455     <<"DSB total     : "     <<sDSB_yield   <<"   \t"      <<" error %: "   <<100*SD_sDSB_yield/sDSB_yield   <<'\n'<<'\n'<<'\t'
0456     <<"SSB/DSB       : "     <<sSSB_yield/sDSB_yield       <<'\n'<<'\n';
0457
0458
0459 // Plot Histograms
0460
0461 cfragment->GetCanvas()->cd();
0462 h1fragments->SetStats(false);
0463 h1fragments->SetMarkerSize(0.1);
0464 h1fragments->SetMarkerColor(kRed);
0465 h1fragments->SetLineColor  (kRed);
0466 h1fragments->Scale(1./(Nbp*1e6)); //bp^-1
0467 h1fragments->SetTitle("");
0468 h1fragments->SetYTitle("Number of Fragments (bp^{-2})");
0469 h1fragments->SetXTitle("Fragment Length (kbp)");
0470 h1fragments->SetAxisRange(1,3e3);
0471 h1fragments->SetMaximum(3e-08);
0472 h1fragments->SetMinimum(1e-12);
0473 h1fragments->Draw();
0474
0475
0476 c1->GetCanvas()->cd();
0477 pad1->cd();
0478 const Int_t n = 6;
0479 Double_t x[n] = {1,2,3,4,5,6};
0480 Double_t y[n] = {EB_yield,ES_yield,OHB_yield,OHS_yield,HB_yield,HS_yield};
0481 Double_t err_y[n] = {SD_EB_yield,SD_ES_yield,SD_OHB_yield,SD_OHS_yield,SD_HB_yield,SD_HS_yield};
0482 TGraph* gr = new TGraphErrors(n,x,y,0,err_y);
0483 gr->SetTitle("Species");
0484 gr->GetXaxis()->SetBinLabel(9, "EaqBaseHits");
0485 gr->GetXaxis()->SetBinLabel(25,"EaqStrandHits");
0486 gr->GetXaxis()->SetBinLabel(42,"OHBaseHits");
0487 gr->GetXaxis()->SetBinLabel(58,"OHStrandHits");
0488 gr->GetXaxis()->SetBinLabel(75,"HBaseHits");
0489 gr->GetXaxis()->SetBinLabel(92,"HStrandHits");
0490 gr->GetYaxis()->SetTitle("Species Hits (Gy^{-1} Mbp^{-1})");
0491 gr->GetYaxis()->SetTitleOffset(2);
0492
0493 gr->SetFillColor(49);
0494 gr->Draw("ba");
0495
0496
0497 pad2->cd();
0498 Double_t x2[n] = {1,2,3,4,5,6};
0499 Double_t y2[n] = {SSBp_yield,SSB2p_yield,SSB_yield,DSBp_yield,DSBpp_yield,DSB_yield};
0500 Double_t err_y2[n] = {SD_SSBp_yield,SD_SSB2p_yield,SD_SSB_yield,SD_DSBp_yield,SD_DSBpp_yield,SD_DSB_yield};
0501 TGraph* gr2 = new TGraphErrors(n,x2,y2,0,err_y2);
0502 gr2->SetTitle("Damage Yield");
0503 gr2->GetXaxis()->SetBinLabel(9, "SSB+");
0504 gr2->GetXaxis()->SetBinLabel(25,"2SSB");
0505 gr2->GetXaxis()->SetBinLabel(42,"SSB");
0506 gr2->GetXaxis()->SetBinLabel(58,"DSB+");
0507 gr2->GetXaxis()->SetBinLabel(75,"DSB++");
0508 gr2->GetXaxis()->SetBinLabel(92,"DSB");
0509 gr2->GetYaxis()->SetTitle("Damage yield (Gy^{-1} Mbp^{-1})");
0510 //gr2->GetYaxis()->SetTitle("Damage yield (Gy^{-1} Gbp^{-1})");
0511 gr2->GetYaxis()->SetTitleOffset(2);
0512
0513 gr2->SetFillColor(8);
0514 gr2->Draw("ba");
0515
0516
0517 pad3->cd();
0518 const Int_t m = 4;
0519 Double_t x3[m] = {1,2,3,4};
0520 Double_t y3[m] = {SSBd_yield,SSBi_yield,SSBm_yield,sSSB_yield};
0521 Double_t err_y3[m] = {SD_SSBd_yield,SD_SSBi_yield,SD_SSBm_yield,SD_sSSB_yield};
0522 TGraph* gr3 = new TGraphErrors(m,x3,y3,0,err_y3);
0523 gr3->SetTitle("Breaks Yield");
0524 gr3->GetXaxis()->SetBinLabel(8, "SSB direct");
0525 gr3->GetXaxis()->SetBinLabel(35,"SSB indirect");
0526 gr3->GetXaxis()->SetBinLabel(64,"SSB mixed");
0527 gr3->GetXaxis()->SetBinLabel(92,"SSB all");
0528 gr3->GetYaxis()->SetTitle("Breaks yield (Gy^{-1} Mbp^{-1})");
0529 //gr3->GetYaxis()->SetTitle("SSB yield (Gy^{-1} Gbp^{-1})");
0530 gr3->GetYaxis()->SetTitleOffset(2);
0531
0532 gr3->SetFillColor(7);
0533 gr3->Draw("ba");
0534
0535
0536 pad4->cd();
0537 const Int_t k = 5;
0538 Double_t x4[k] = {1,2,3,4,5};
0539 Double_t y4[k] = {DSBd_yield,DSBi_yield,DSBm_yield,DSBh_yield,sDSB_yield};
0540 Double_t err_y4[k] = {SD_DSBd_yield,SD_DSBi_yield,SD_DSBm_yield,SD_DSBh_yield,SD_sDSB_yield};
0541 TGraph* gr4 = new TGraphErrors(k,x4,y4,0,err_y4);
0542 gr4->SetTitle("Breaks Yield");
0543 gr4->GetXaxis()->SetBinLabel(8,"DSB direct");
0544 gr4->GetXaxis()->SetBinLabel(29,"DSB indirect");
0545 gr4->GetXaxis()->SetBinLabel(50,"DSB mixed");
0546 gr4->GetXaxis()->SetBinLabel(71,"DSB hybrid");
0547 gr4->GetXaxis()->SetBinLabel(92,"DSB all");
0548 gr4->GetYaxis()->SetTitle("Breaks yield (Gy^{-1} Mbp^{-1})");
0549 //gr4->GetYaxis()->SetTitle("DSB yield (Gy^{-1} Gbp^{-1})");
0550 gr4->GetYaxis()->SetTitleOffset(2);
0551
0552 gr4->SetFillColor(4);
0553 gr4->Draw("ba");
0554
0555 }
0556
0557 // Some important bools that are needed to run the root macro file
0558 bool greaterPair(const ipair& l, const ipair& r){return l.second > r.second;}
0559 bool smallerPair(const ipair& l, const ipair& r){return l.second < r.second;}
0560
0561 void BinLogX(TH1 *h) {
0562   TAxis *axis = h->GetXaxis();
0563   int bins = axis->GetNbins();
0564   Axis_t from = axis->GetXmin();
0565   Axis_t to = axis->GetXmax();
0566   Axis_t width = (to - from) / bins;
0567   Axis_t *new_bins = new Axis_t[bins + 1];
0568   for (int i = 0; i <= bins; i++) {
0569     new_bins[i] = TMath::Power(10, from + i * width);
0570   }
0571   axis->Set(bins, new_bins);
0572   delete[] new_bins;
0573
0574 }