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Geant4/examples/advanced/dna/moleculardna/human_cell_alphas.C

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Differences between /examples/advanced/dna/moleculardna/human_cell_alphas.C (Version 11.3.0) and /examples/advanced/dna/moleculardna/human_cell_alphas.C (Version 6.0.p1)


  1 //--------------------------------------------      1 
  2 // This macrofile was developed by Konstantino    
  3 // in collaboration with the whole team of mol    
  4 // Publication: K. Chatzipapas, et al., Phys.     
  5 // For any question please contact through:       
  6 // chatzipa@cenbg.in2p3.fr                        
  7 //--------------------------------------------    
  8                                                   
  9 // This macro requires the molecular-dna.root     
 10                                                   
 11 {                                                 
 12 //********************************************    
 13 // If you need to add multiple root outputs, b    
 14 // system ("hadd -O -f molecular-dna.root mole    
 15                                                   
 16 // Define these parameters of the simulation      
 17 char ifile[256] = "molecular-dna.root";  // in    
 18                                                   
 19 //for HTB                                         
 20 Double_t r3 = 8550e-9 * 2500e-9 * 6425e-9; //     
 21 Double_t Nbp = 6454.227202; // Mbp // Length o    
 22                                                   
 23 // for MCF                                        
 24 //Double_t r3 = 7005e-9 * 2500e-9 * 5300e-9; /    
 25 //Double_t Nbp = 6424.831996; // Mbp // Length    
 26                                                   
 27 Double_t mass = 997 * 4 * 3.141592 * r3 / 3 ;     
 28 //////////////////////////////////////////////    
 29 //********************************************    
 30                                                   
 31 typedef std::pair <int64_t, int64_t> ipair;       
 32 bool greaterPair(const ipair &l, const ipair &    
 33 bool smallerPair(const ipair &l, const ipair &    
 34                                                   
 35 void BinLogX(TH1 *h);                             
 36                                                   
 37 gROOT->Reset();                                   
 38 gStyle->SetPalette(1);                            
 39 gROOT->SetStyle("Plain");                         
 40 gStyle->SetOptStat(00000);                        
 41                                                   
 42 // Initialize output histograms                   
 43 TCanvas *cfragment = new TCanvas("cfragment","    
 44 cfragment->SetLogx();                             
 45 cfragment->SetLogy();                             
 46 TH1F *h1fragments = new TH1F("h1fragments","h1    
 47 BinLogX(h1fragments);                             
 48                                                   
 49 TCanvas *c1 = new TCanvas("c1", "Molecular DNA    
 50 c1->SetBorderSize(0);                             
 51 c1->SetFillColor(0);                              
 52 c1->SetFillStyle(4000);                           
 53 gPad->SetLeftMargin(0.13);                        
 54                                                   
 55 TPad* pad1 = new TPad("pad1","Species", 0, 0.5    
 56 pad1->SetBorderSize(0);                           
 57 pad1->SetFillColor(0);                            
 58 pad1->SetFillStyle(4000);                         
 59 pad1->SetLeftMargin(0.15);                        
 60 pad1->SetRightMargin(0.01);                       
 61 pad1->SetBottomMargin(0.2);                       
 62                                                   
 63 TPad* pad2 = new TPad("pad2","Damage Yield", 0    
 64 pad2->SetBorderSize(0);                           
 65 pad2->SetFillColor(0);                            
 66 pad2->SetFillStyle(4000);                         
 67 pad2->SetLeftMargin(0.15);                        
 68 pad2->SetRightMargin(0.05);                       
 69 pad2->SetBottomMargin(0.2);                       
 70                                                   
 71 TPad* pad3 = new TPad("pad3","Breaks Yield SSB    
 72 pad3->SetBorderSize(0);                           
 73 pad3->SetFillColor(0);                            
 74 pad3->SetFillStyle(4000);                         
 75 pad3->SetLeftMargin(0.15);                        
 76 pad3->SetRightMargin(0.01);                       
 77 //pad3->SetTopMargin(0.2);                        
 78 pad3->SetBottomMargin(0.2);                       
 79                                                   
 80 TPad* pad4 = new TPad("pad4","Breaks Yield DSB    
 81 pad4->SetBorderSize(0);                           
 82 pad4->SetFillColor(0);                            
 83 pad4->SetFillStyle(4000);                         
 84 pad4->SetLeftMargin(0.15);                        
 85 pad4->SetRightMargin(0.05);                       
 86 //pad3->SetTopMargin(0.2);                        
 87 pad4->SetBottomMargin(0.2);                       
 88                                                   
 89 pad1->Draw();                                     
 90 pad2->Draw();                                     
 91 pad3->Draw();                                     
 92 pad4->Draw();                                     
 93                                                   
 94 // Open root file                                 
 95 TFile *f = TFile::Open(ifile);                    
 96                                                   
 97 // Initialize Variables                           
 98 Int_t EB, ES, OHB, OHS, HB, HS, FL;               
 99 Int_t total_EB, total_ES, total_OHB, total_OHS    
100 Float_t total_EB2, total_ES2, total_OHB2, tota    
101 Float_t SD_EB, SD_ES, SD_OHB, SD_OHS, SD_HB, S    
102 Float_t SD_SSB, SD_SSBp, SD_SSB2p, SD_sSSB, SD    
103 Float_t SD_DSB, SD_DSBp, SD_DSBpp, SD_sDSB, SD    
104                                                   
105 Int_t SSB, SSBp, SSB2p;                           
106 Int_t total_SSB, total_SSBp, total_SSB2p;         
107 Float_t total_SSB2, total_SSBp2, total_SSB2p2;    
108 Int_t DSB, DSBp, DSBpp;                           
109 Int_t total_DSB, total_DSBp, total_DSBpp;         
110 Float_t total_DSB2, total_DSBp2, total_DSBpp2;    
111                                                   
112 Int_t SSBd, SSBi, SSBm;                           
113 Int_t total_sSSB, total_SSBd, total_SSBi, tota    
114 Float_t total_sSSB2, total_SSBd2, total_SSBi2,    
115 Int_t DSBd, DSBi, DSBm, DSBh;                     
116 Int_t total_sDSB, total_DSBd, total_DSBi, tota    
117 Float_t total_sDSB2, total_DSBd2, total_DSBi2,    
118                                                   
119 Double_t dose = 0;                                
120 Double_t SD_dose = 0;                             
121                                                   
122 Double_t EB_yield = 0; Double_t ES_yield = 0;     
123 Double_t SD_EB_yield = 0; Double_t SD_ES_yield    
124                                                   
125 Double_t SSB_yield = 0; Double_t SSBp_yield =     
126 Double_t SD_SSB_yield = 0; Double_t SD_SSBp_yi    
127 Double_t DSB_yield = 0; Double_t DSBp_yield =     
128 Double_t SD_DSB_yield = 0; Double_t SD_DSBp_yi    
129                                                   
130 Double_t sSSB_yield = 0; Double_t SSBi_yield =    
131 Double_t SD_sSSB_yield = 0; Double_t SD_SSBi_y    
132 Double_t sDSB_yield = 0; Double_t DSBi_yield =    
133 Double_t SD_sDSB_yield = 0; Double_t SD_DSBi_y    
134                                                   
135 total_EB  = 0; total_ES = 0; total_OHB = 0; to    
136                                                   
137 total_SSB  = 0; total_SSBp = 0; total_SSB2p =     
138 total_SSB2  = 0; total_SSBp2 = 0; total_SSB2p2    
139 total_DSB  = 0; total_DSBp = 0; total_DSBpp =     
140 total_DSB2  = 0; total_DSBp2 = 0; total_DSBpp2    
141                                                   
142 total_sSSB = 0; total_SSBd = 0; total_SSBi = 0    
143 total_sSSB2 = 0; total_SSBd2 = 0; total_SSBi2     
144 total_sDSB = 0; total_DSBd = 0; total_DSBi = 0    
145 total_sDSB2 = 0; total_DSBd2 = 0; total_DSBi2     
146                                                   
147 Double_t eVtoJ = 1.60218e-19;                     
148 Double_t EnergyDeposited_eV = 0;                  
149 Double_t acc_edep = 0;                            
150 Double_t acc_edep2 = 0;                           
151                                                   
152 Double_t Energy;                                  
153 Double_t BPID;                                    
154 Char_t Primary;                                   
155 char *primaryName = new char[32];                 
156 char *type= new char[256];                        
157                                                   
158 // Read trees and leaves from root file, and g    
159 TTree* tree = (TTree*) f->Get("tuples/primary_    
160 Float_t number = (Float_t) tree->GetEntries();    
161                                                   
162 vector<pair<int,int64_t>> DSBBPID;                
163                                                   
164 // For reading species production                 
165 tree = (TTree*) f->Get("tuples/damage");          
166 tree->SetBranchAddress("Primary",           &P    
167 tree->SetBranchAddress("Energy",            &E    
168 tree->SetBranchAddress("EaqBaseHits",       &E    
169 tree->SetBranchAddress("EaqStrandHits",     &E    
170 tree->SetBranchAddress("OHBaseHits",        &O    
171 tree->SetBranchAddress("OHStrandHits",      &O    
172 tree->SetBranchAddress("HBaseHits",         &H    
173 tree->SetBranchAddress("HStrandHits",       &H    
174 tree->SetBranchAddress("TypeClassification", t    
175 tree->SetBranchAddress("BasePair",          &B    
176                                                   
177                                                   
178 Long64_t nentries = tree->GetEntries();           
179 for(int i = 0;i<nentries;i++){                    
180   tree->GetEntry(i);                              
181                                                   
182   total_EB   += EB;                               
183   total_EB2  += pow(EB,2);                        
184   total_ES   += ES;                               
185   total_ES2  += pow(ES,2);                        
186   total_OHB  += OHB;                              
187   total_OHB2 += pow(OHB,2);                       
188   total_OHS  += OHS;                              
189   total_OHS2 += pow(OHS,2);                       
190   total_HB   += HB;                               
191   total_HB2  += pow(HB,2);                        
192   total_HS   += HS;                               
193   total_HS2  += pow(HS,2);                        
194                                                   
195   if((string)type=="DSB"||(string)type=="DSB+"    
196     //cout << "DSB:"<<type<<endl;                 
197     DSBBPID.push_back(make_pair(i,(int64_t)BPI    
198     }                                             
199                                                   
200   }                                               
201                                                   
202 // Sort DSBs from the one with lower ID value     
203 // Then find the number of fragments that have    
204 sort(DSBBPID.begin(),  DSBBPID.end(), smallerP    
205 for(int ie = 0;ie<DSBBPID.size()-1;ie++){         
206   int64_t dsbfragment = DSBBPID[ie+1].second-D    
207                                                   
208   double val       = (double)dsbfragment/1000.    
209   double meanw     = h1fragments->GetBinCenter    
210   double binw      = h1fragments->GetBinWidth     
211   h1fragments->Fill(val,1./binw/1000);//bp-1      
212   //cout <<"val:"<<val<<endl;                     
213   }                                               
214                                                   
215 // Calculate the standard deviation of species    
216 SD_EB  = sqrt(((total_EB2  / number) - pow(tot    
217 SD_ES  = sqrt(((total_ES2  / number) - pow(tot    
218 SD_OHB = sqrt(((total_OHB2 / number) - pow(tot    
219 SD_OHS = sqrt(((total_OHS2 / number) - pow(tot    
220 SD_HB  = sqrt(((total_HB2  / number) - pow(tot    
221 SD_HS  = sqrt(((total_HS2  / number) - pow(tot    
222                                                   
223 // Read damage classification SSB, SSB+, 2SSB,    
224 // As they have been defined in: Nikjoo, H., O    
225 // Computational modelling of low-energy elect    
226 // and chemical events, International Journal     
227 tree = (TTree *) f->Get("tuples/classification    
228 tree->SetBranchAddress("Primary",&Primary);       
229 tree->SetBranchAddress("Energy", &Energy);        
230 tree->SetBranchAddress("SSB",    &SSB);           
231 tree->SetBranchAddress("SSBp",   &SSBp);          
232 // Check                                          
233 //tree->SetBranchAddress("SSB2",   &SSB2p);       
234 tree->SetBranchAddress("2SSB",   &SSB2p);         
235 //                                                
236 tree->SetBranchAddress("DSB",    &DSB);           
237 tree->SetBranchAddress("DSBp",   &DSBp);          
238 tree->SetBranchAddress("DSBpp",  &DSBpp);         
239                                                   
240                                                   
241 Long64_t nentriesC = tree->GetEntries();          
242 for(int i = 0;i<nentriesC;i++){                   
243   tree->GetEntry(i);                              
244                                                   
245   total_SSBp   += SSBp;                           
246   total_SSBp2  += pow(SSBp,2);                    
247   total_SSB2p  += SSB2p;                          
248   total_SSB2p2 += pow(SSB2p,2);                   
249   total_SSB    += SSB;                            
250   total_SSB2   += pow(SSB,2);                     
251                                                   
252   total_DSBp   += DSBp;                           
253   total_DSBp2  += pow(DSBp,2);                    
254   total_DSBpp  += DSBpp;                          
255   total_DSBpp2 += pow(DSBpp,2);                   
256   total_DSB    += DSB;                            
257   total_DSB2   += pow(DSB,2);                     
258                                                   
259   }                                               
260                                                   
261 // Calculate the standard deviation               
262 SD_SSB   = sqrt(((total_SSB2   / number) - pow    
263 SD_SSBp  = sqrt(((total_SSBp2  / number) - pow    
264 SD_SSB2p = sqrt(((total_SSB2p2 / number) - pow    
265                                                   
266 SD_DSB   = sqrt(((total_DSB2   / number) - pow    
267 SD_DSBp  = sqrt(((total_DSBp2  / number) - pow    
268 SD_DSBpp = sqrt(((total_DSBpp2 / number) - pow    
269                                                   
270 // Read damage classification SSBd, SSBi, SSBm    
271 // As they have been defined in: Nikjoo, H., O    
272 // Computational modelling of low-energy elect    
273 // and chemical events, International Journal     
274 tree = (TTree *) f->Get("tuples/source");         
275 tree->SetBranchAddress("Primary",primaryName);    
276 tree->SetBranchAddress("Energy", &Energy);        
277 tree->SetBranchAddress("SSBd",   &SSBd);          
278 tree->SetBranchAddress("SSBi",   &SSBi);          
279 tree->SetBranchAddress("SSBm",   &SSBm);          
280 tree->SetBranchAddress("DSBd",   &DSBd);          
281 tree->SetBranchAddress("DSBi",   &DSBi);          
282 tree->SetBranchAddress("DSBm",   &DSBm);          
283 tree->SetBranchAddress("DSBh",   &DSBh);          
284                                                   
285 Long64_t nentriesS = tree->GetEntries();          
286 for(int i = 0;i<nentriesS;i++){                   
287   tree->GetEntry(i);                              
288                                                   
289   total_SSBd += SSBd;                             
290   total_SSBd2 += pow((SSBd),2);                   
291   total_SSBi += SSBi;                             
292   total_SSBi2 += pow((SSBi),2);                   
293   total_SSBm += SSBm;                             
294   total_SSBm2 += pow((SSBm),2);                   
295   total_sSSB += SSBd + SSBi + SSBm;               
296   total_sSSB2 += pow((SSBd+SSBi+SSBm),2);         
297                                                   
298   total_DSBd  += DSBd;                            
299   total_DSBd2 += pow(DSBd,2);                     
300   total_DSBi  += DSBi;                            
301   total_DSBi2 += pow(DSBi,2);                     
302   total_DSBm  += DSBm;                            
303   total_DSBm2 += pow(DSBm,2);                     
304   total_DSBh  += DSBh;                            
305   total_DSBh2 += pow(DSBh,2);                     
306   total_sDSB  += DSBd + DSBi + DSBm + DSBh;       
307   total_sDSB2 += pow((DSBd+DSBi+DSBm+DSBh),2);    
308                                                   
309   }                                               
310                                                   
311 // Calculate the standard deviation               
312 SD_sSSB = sqrt(((total_sSSB2 / number) - pow(t    
313 SD_SSBd = sqrt(((total_SSBd2 / number) - pow(t    
314 SD_SSBi = sqrt(((total_SSBi2 / number) - pow(t    
315 SD_SSBm = sqrt(((total_SSBm2 / number) - pow(t    
316                                                   
317 SD_sDSB = sqrt(((total_sDSB2 / number) - pow(t    
318 SD_DSBd = sqrt(((total_DSBd2 / number) - pow(t    
319 SD_DSBi = sqrt(((total_DSBi2 / number) - pow(t    
320 SD_DSBm = sqrt(((total_DSBm2 / number) - pow(t    
321 SD_DSBh = sqrt(((total_DSBh2 / number) - pow(t    
322                                                   
323                                                   
324 // Measure the Deposited Energy in the whole v    
325                                                   
326 tree = (TTree *) f->Get("tuples/chromosome_hit    
327 tree->SetBranchAddress("e_chromosome_kev",&Ene    
328 nentries = tree->GetEntries();                    
329 for(int i = 0;i<nentries;i++){                    
330   tree->GetEntry(i);                              
331   acc_edep += EnergyDeposited_eV *1e3;            
332   acc_edep2 += EnergyDeposited_eV *EnergyDepos    
333 }                                                 
334 tree->SetBranchAddress("e_dna_kev",&EnergyDepo    
335 nentries = tree->GetEntries();                    
336 for(int i = 0;i<nentries;i++){                    
337   tree->GetEntry(i);                              
338   acc_edep += EnergyDeposited_eV *1e3;            
339   acc_edep2 += EnergyDeposited_eV *EnergyDepos    
340 }                                                 
341                                                   
342 // Close the root file to free space              
343 f->Close();                                       
344                                                   
345 // Calculate the absorbed dose                    
346 dose = acc_edep * eVtoJ / mass;                   
347 cout << acc_edep << "\n";                         
348                                                   
349 // This is a normalization factor to produce t    
350 // Default value is 1 to produce the result in    
351 // It changes Mbp to Gbp. Some other changes m    
352 double norm = 1000;                               
353                                                   
354 // Calculate the yields, together with their s    
355 EB_yield  = (Double_t) total_EB  / dose / Nbp;    
356 ES_yield  = (Double_t) total_ES  / dose / Nbp;    
357 OHB_yield = (Double_t) total_OHB / dose / Nbp;    
358 OHS_yield = (Double_t) total_OHS / dose / Nbp;    
359 HB_yield  = (Double_t) total_HB  / dose / Nbp;    
360 HS_yield  = (Double_t) total_HS  / dose / Nbp;    
361                                                   
362 SD_EB_yield  = SD_EB  / dose / Nbp;               
363 SD_ES_yield  = SD_ES  / dose / Nbp;               
364 SD_OHB_yield = SD_OHB / dose / Nbp;               
365 SD_OHS_yield = SD_OHS / dose / Nbp;               
366 SD_HB_yield  = SD_HB  / dose / Nbp;               
367 SD_HS_yield  = SD_HS  / dose / Nbp;               
368                                                   
369                                                   
370 SSB_yield   = (Double_t) norm * total_SSB   /     
371 SSBp_yield  = (Double_t) norm * total_SSBp  /     
372 SSB2p_yield = (Double_t) norm * total_SSB2p /     
373                                                   
374 DSB_yield   = (Double_t) norm * total_DSB   /     
375 DSBp_yield  = (Double_t) norm * total_DSBp  /     
376 DSBpp_yield = (Double_t) norm * total_DSBpp /     
377                                                   
378 SD_SSB_yield   = norm * SD_SSB   / dose / Nbp;    
379 SD_SSBp_yield  = norm * SD_SSBp  / dose / Nbp;    
380 SD_SSB2p_yield = norm * SD_SSB2p / dose / Nbp;    
381                                                   
382 SD_DSB_yield   = norm * SD_DSB   / dose / Nbp;    
383 SD_DSBp_yield  = norm * SD_DSBp  / dose / Nbp;    
384 SD_DSBpp_yield = norm * SD_DSBpp / dose / Nbp;    
385                                                   
386                                                   
387 sSSB_yield = (Double_t) norm * total_sSSB / do    
388 SSBi_yield = (Double_t) norm * total_SSBi / do    
389 SSBd_yield = (Double_t) norm * total_SSBd / do    
390 SSBm_yield = (Double_t) norm * total_SSBm / do    
391                                                   
392 sDSB_yield = (Double_t) norm * total_sDSB / do    
393 DSBi_yield = (Double_t) norm * total_DSBi / do    
394 DSBd_yield = (Double_t) norm * total_DSBd / do    
395 DSBm_yield = (Double_t) norm * total_DSBm / do    
396 DSBh_yield = (Double_t) norm * total_DSBh / do    
397                                                   
398 SD_sSSB_yield = norm * SD_sSSB / dose / Nbp;      
399 SD_SSBi_yield = norm * SD_SSBi / dose / Nbp;      
400 SD_SSBd_yield = norm * SD_SSBd / dose / Nbp;      
401 SD_SSBm_yield = norm * SD_SSBm / dose / Nbp;      
402                                                   
403 SD_sDSB_yield = norm * SD_sDSB / dose / Nbp;      
404 SD_DSBi_yield = norm * SD_DSBi / dose / Nbp;      
405 SD_DSBd_yield = norm * SD_DSBd / dose / Nbp;      
406 SD_DSBm_yield = norm * SD_DSBm / dose / Nbp;      
407 SD_DSBh_yield = norm * SD_DSBh / dose / Nbp;      
408                                                   
409                                                   
410 // Print output in terminal                       
411                                                   
412 float total_SSB_totalYield = SSB_yield + SSBp_    
413 float total_DSB_totalYield = DSB_yield + DSBp_    
414                                                   
415 cout<<"\n"                      <<ifile           
416     <<"\nDose Absorbed (Gy): "  <<dose            
417     <<"Particle : "             <<primaryName     
418     <<"Energy (MeV) : "         <<Energy          
419     <<"Number of Primaries : "  <<number          
420     <<"  Output Damage : "                        
421     <<"     Species Hits (Gy-1 Mbp-1) "      <    
422     <<"EaqBaseHits   : "     <<EB_yield     <<    
423     <<"EaqStrandHits : "     <<ES_yield     <<    
424     <<"OHBaseHits    : "     <<OHB_yield    <<    
425     <<"OHStrandHits  : "     <<OHS_yield    <<    
426     <<"HBaseHits     : "     <<HB_yield     <<    
427     <<"HStrandHits   : "     <<HS_yield     <<    
428     <<"     Damage yield (Gy-1 Gbp-1) "      <    
429     <<"SSB           : "     <<SSB_yield    <<    
430     <<"SSB+          : "     <<SSBp_yield   <<    
431     <<"2SSB          : "     <<SSB2p_yield  <<    
432     <<"SSB total     : "     <<total_SSB_total    
433     <<"DSB           : "     <<DSB_yield    <<    
434     <<"DSB+          : "     <<DSBp_yield   <<    
435     <<"DSB++         : "     <<DSBpp_yield  <<    
436     <<"DSB total     : "     <<total_DSB_total    
437     <<"     Breaks yield (Gy-1 Gbp-1) "      <    
438     <<"SSB direct    : "     <<SSBd_yield   <<    
439     <<"SSB indirect  : "     <<SSBi_yield   <<    
440     <<"SSB mixed     : "     <<SSBm_yield   <<    
441     <<"SSB total     : "     <<sSSB_yield   <<    
442     <<"DSB direct    : "     <<DSBd_yield   <<    
443     <<"DSB indirect  : "     <<DSBi_yield   <<    
444     <<"DSB mixed     : "     <<DSBm_yield   <<    
445     <<"DSB hybrid    : "     <<DSBh_yield   <<    
446     <<"DSB total     : "     <<sDSB_yield   <<    
447     <<"SSB/DSB       : "     <<sSSB_yield/sDSB    
448                                                   
449                                                   
450 // Plot Histograms                                
451                                                   
452 cfragment->GetCanvas()->cd();                     
453 h1fragments->SetStats(false);                     
454 h1fragments->SetMarkerSize(0.1);                  
455 h1fragments->SetMarkerColor(kRed);                
456 h1fragments->SetLineColor  (kRed);                
457 h1fragments->Scale(1./(Nbp*1e6)); //bp^-1         
458 h1fragments->SetTitle("");                        
459 h1fragments->SetYTitle("Number of Fragments (b    
460 h1fragments->SetXTitle("Fragment Length (kbp)"    
461 h1fragments->SetAxisRange(10,1e4);                
462 h1fragments->SetMaximum(3e-11);                   
463 h1fragments->SetMinimum(1e-15);                   
464 h1fragments->Draw();                              
465                                                   
466                                                   
467 c1->GetCanvas()->cd();                            
468 pad1->cd();                                       
469 const Int_t n = 6;                                
470 Double_t x[n] = {1,2,3,4,5,6};                    
471 Double_t y[n] = {EB_yield,ES_yield,OHB_yield,O    
472 Double_t err_y[n] = {SD_EB_yield,SD_ES_yield,S    
473 TGraph* gr = new TGraphErrors(n,x,y,0,err_y);     
474 gr->SetTitle("Species");                          
475 gr->GetXaxis()->SetBinLabel(9, "EaqBaseHits");    
476 gr->GetXaxis()->SetBinLabel(25,"EaqStrandHits"    
477 gr->GetXaxis()->SetBinLabel(42,"OHBaseHits");     
478 gr->GetXaxis()->SetBinLabel(58,"OHStrandHits")    
479 gr->GetXaxis()->SetBinLabel(75,"HBaseHits");      
480 gr->GetXaxis()->SetBinLabel(92,"HStrandHits");    
481 gr->GetYaxis()->SetTitle("Species Hits (Gy^{-1    
482 gr->GetYaxis()->SetTitleOffset(2);                
483                                                   
484 gr->SetFillColor(49);                             
485 gr->Draw("ba");                                   
486                                                   
487                                                   
488 pad2->cd();                                       
489 Double_t x2[n] = {1,2,3,4,5,6};                   
490 Double_t y2[n] = {SSBp_yield,SSB2p_yield,SSB_y    
491 Double_t err_y2[n] = {SD_SSBp_yield,SD_SSB2p_y    
492 TGraph* gr2 = new TGraphErrors(n,x2,y2,0,err_y    
493 gr2->SetTitle("Damage Yield");                    
494 gr2->GetXaxis()->SetBinLabel(9, "SSB+");          
495 gr2->GetXaxis()->SetBinLabel(25,"2SSB");          
496 gr2->GetXaxis()->SetBinLabel(42,"SSB");           
497 gr2->GetXaxis()->SetBinLabel(58,"DSB+");          
498 gr2->GetXaxis()->SetBinLabel(75,"DSB++");         
499 gr2->GetXaxis()->SetBinLabel(92,"DSB");           
500 //gr2->GetYaxis()->SetTitle("Damage yield (Gy^    
501 gr2->GetYaxis()->SetTitle("Damage yield (Gy^{-    
502 gr2->GetYaxis()->SetTitleOffset(2);               
503                                                   
504 gr2->SetFillColor(8);                             
505 gr2->Draw("ba");                                  
506                                                   
507                                                   
508 pad3->cd();                                       
509 const Int_t m = 4;                                
510 Double_t x3[m] = {1,2,3,4};                       
511 Double_t y3[m] = {SSBd_yield,SSBi_yield,SSBm_y    
512 Double_t err_y3[m] = {SD_SSBd_yield,SD_SSBi_yi    
513 TGraph* gr3 = new TGraphErrors(m,x3,y3,0,err_y    
514 gr3->SetTitle("Breaks Yield");                    
515 gr3->GetXaxis()->SetBinLabel(8, "SSB direct");    
516 gr3->GetXaxis()->SetBinLabel(35,"SSB indirect"    
517 gr3->GetXaxis()->SetBinLabel(64,"SSB mixed");     
518 gr3->GetXaxis()->SetBinLabel(92,"SSB all");       
519 //gr3->GetYaxis()->SetTitle("Breaks yield (Gy^    
520 gr3->GetYaxis()->SetTitle("SSB yield (Gy^{-1}     
521 gr3->GetYaxis()->SetTitleOffset(2);               
522                                                   
523 gr3->SetFillColor(7);                             
524 gr3->Draw("ba");                                  
525                                                   
526                                                   
527 pad4->cd();                                       
528 const Int_t k = 5;                                
529 Double_t x4[k] = {1,2,3,4,5};                     
530 Double_t y4[k] = {DSBd_yield,DSBi_yield,DSBm_y    
531 Double_t err_y4[k] = {SD_DSBd_yield,SD_DSBi_yi    
532 TGraph* gr4 = new TGraphErrors(k,x4,y4,0,err_y    
533 gr4->SetTitle("Breaks Yield");                    
534 gr4->GetXaxis()->SetBinLabel(8,"DSB direct");     
535 gr4->GetXaxis()->SetBinLabel(29,"DSB indirect"    
536 gr4->GetXaxis()->SetBinLabel(50,"DSB mixed");     
537 gr4->GetXaxis()->SetBinLabel(71,"DSB hybrid");    
538 gr4->GetXaxis()->SetBinLabel(92,"DSB all");       
539 //gr4->GetYaxis()->SetTitle("Breaks yield (Gy^    
540 gr4->GetYaxis()->SetTitle("DSB yield (Gy^{-1}     
541 gr4->GetYaxis()->SetTitleOffset(2);               
542                                                   
543 gr4->SetFillColor(4);                             
544 gr4->Draw("ba");                                  
545                                                   
546 }                                                 
547                                                   
548 // Some important bools that are needed to run    
549 bool greaterPair(const ipair& l, const ipair&     
550 bool smallerPair(const ipair& l, const ipair&     
551                                                   
552 void BinLogX(TH1 *h) {                            
553   TAxis *axis = h->GetXaxis();                    
554   int bins = axis->GetNbins();                    
555   Axis_t from = axis->GetXmin();                  
556   Axis_t to = axis->GetXmax();                    
557   Axis_t width = (to - from) / bins;              
558   Axis_t *new_bins = new Axis_t[bins + 1];        
559   for (int i = 0; i <= bins; i++) {               
560     new_bins[i] = TMath::Power(10, from + i *     
561   }                                               
562   axis->Set(bins, new_bins);                      
563   delete[] new_bins;                              
564                                                   
565 }                                                 
566