Changeset 8646 for trunk/MagicSoft
- Timestamp:
- 07/26/07 12:13:00 (17 years ago)
- Location:
- trunk/MagicSoft/Mars
- Files:
-
- 9 edited
Legend:
- Unmodified
- Added
- Removed
-
trunk/MagicSoft/Mars/Changelog
r8644 r8646 18 18 19 19 -*-*- END OF LINE -*-*- 20 21 2007/07/26 Thomas Bretz 22 23 * mfilter/MFMagicCuts.cc: 24 - implemented new disp-parametrization 25 - implemented new ghostbusting 26 - implemented possibility to use an external ghostbuster 27 - implemented possibility to use an external disp calculator 28 29 * mimage/MImgCleanStd.[h,cc]: 30 - implemented the cleaning in a recursive way. It should be 31 a little bit faster 32 - implemented post-cleaning using timing information 33 - implemented new options how to treat the removed single 34 core pixels 35 36 * mjobs/MJCut.cc: 37 - write an external ghostbuster to the output file if available 38 39 * mjtrain/MJTrainEnergy.cc, mjtrain/MJTrainSeparation.cc: 40 - set display name of MRanForestCalc as title instead of name 41 42 * mranforest/MRanForestCalc.cc: 43 - set fTitle as eventloop name instead of fName 44 45 46 47 2007/07/25 Thomas Bretz 48 49 * scripts/merppupdate: 50 - small fixes 51 52 20 53 21 54 2007/07/24 Thomas Bretz -
trunk/MagicSoft/Mars/mfilter/MFMagicCuts.cc
r8633 r8646 51 51 // 52 52 // c[0], c[5], c[6], c[7], c[8], c[9]: 53 // xi = c[0]+c[6]*pow(leakage1, c[7]); 53 // xi = c[0] + c[8]*slope + c[9]*leak + 54 // (lgsize>c[10])*c[11]*(lgsize-c[10])^2; 54 55 // p = xi*(1-width/length); 55 56 // sign1 = m3long-c[5] 56 // sign2 = (dist-c[ 9])*c[8]-slope57 // sign2 = (dist-c[7])*c[6]-slope 57 58 // disp = sign1<0 ||sign2<0 ? -disp : disp 58 // antisign1 = antim3long-c[5]59 // antisign2 = (antidist-c[9])*c[8]-antislope60 // antidisp = antisign1<0 || antisign2<0 ? -antidisp : antidisp61 59 // thetasq = disp^2 + dist^2 - 2*disp*dist*alpha 62 // antithetasq = antidisp^2 + antidist^2 - 2*antidisp*antidist*antialpha 60 // 61 // And the values with respect to the antisource position respectively. 62 // 63 63 // 64 64 // c[1]: … … 71 71 // 72 72 // HadronnessCut: 73 // c[1 0], c[11]:74 // had <= c[1 0]75 // 10^lgsize >= c[1 1]73 // c[13], c[14]: 74 // had <= c[13] 75 // 10^lgsize >= c[14] 76 76 // 77 77 // … … 81 81 // HadronnessCut: 82 82 // - none/nocut: No area cut 83 // - area: Area cut 84 // - all: same as area 83 // - area: Area cut <default> 84 // - hadronness: Cut in size and hadronness (c[10], c[11]) 85 // - all: area + hadronness 85 86 // 86 87 // ThetaCut: 87 // - none/nocut: no theta cut 88 // - none/nocut: no theta cut <default> 88 89 // - on: cut in theta only 89 90 // - off: anti-cut in anti-theta only 90 91 // - wobble: same as on|off (both) 91 92 // 93 // CalcDisp: 94 // - yes: Disp is calculated as defined above <default> 95 // - no: abs(Disp.fVal) from the parameter list is used instead 96 // 97 // CalcGhostbuster: 98 // - yes: The ghostbuster is calculated as defined above <default> 99 // - no: Ghostbuster.fVal<c[12] is used as ghostbusting condition 92 100 // 93 101 // Input Container: … … 99 107 // MHillasSrc 100 108 // [MHillasSrcAnti [MHillasSrc]] 109 // [Disp [MParameterD]] 110 // [Ghostbuster [MParameterD]] 101 111 // 102 112 // Output: … … 138 148 MFMagicCuts::MFMagicCuts(const char *name, const char *title) 139 149 : fHil(0), fHilSrc(0), fHilAnti(0), fHilExt(0), fNewImgPar(0), 140 fThetaSq(0), fDisp(0), fHadronness(0), fMatrix(0), fVariables(30), 141 fThetaCut(kNone), fHadronnessCut(kArea) 150 fThetaSq(0), fDisp(0), fHadronness(0), fMatrix(0), fVariables(20), 151 fThetaCut(kNone), fHadronnessCut(kArea), fCalcDisp(kTRUE), 152 fCalcGhostbuster(kTRUE) 142 153 { 143 154 fName = name ? name : "MFMagicCuts"; … … 159 170 AddToBranchList("MNewImagePar.fLeakage1"); 160 171 AddToBranchList("Hadronness.fVal"); 161 /* 162 fVariables[0] = 1.42547; // Xi 163 fVariables[1] = 0.233773; // Theta^2 164 fVariables[2] = 0.2539460; // Area[0] 165 fVariables[3] = 5.2149800; // Area[1] 166 fVariables[4] = 0.1139130; // Area[2] 167 fVariables[5] = -0.0889; // M3long 168 fVariables[6] = 0.18; // Xi(theta) 169 fVariables[7] = 0.18; // Xi(theta) 170 */ 172 AddToBranchList("Disp.fVal"); 173 AddToBranchList("Ghostbuster.fVal"); 171 174 } 172 175 … … 190 193 if (!fThetaSq) 191 194 return kFALSE; 192 fDisp = (MParameterD*)pList->FindCreateObj("MParameterD", "Disp"); 195 196 if (!fCalcDisp) 197 fDisp = (MParameterD*)pList->FindObject("Disp", "MParameterD"); 198 else 199 fDisp = (MParameterD*)pList->FindCreateObj("MParameterD", "Disp"); 193 200 if (!fDisp) 194 return kFALSE; 201 { 202 *fLog << err << "Disp [MParameterD] not found... aborting." << endl; 203 return kFALSE; 204 } 205 206 if (!fCalcGhostbuster) 207 fGhostbuster = (MParameterD*)pList->FindObject("Ghostbuster", "MParameterD"); 208 else 209 fGhostbuster = (MParameterD*)pList->FindCreateObj("MParameterD", "Ghostbuster"); 210 if (!fGhostbuster) 211 { 212 *fLog << err << "Ghostbuster [MParameterD] not found... aborting." << endl; 213 return kFALSE; 214 } 195 215 196 216 // propagate Theta cut to the parameter list … … 297 317 fMap[kEM3Long] = fMatrix->AddColumn("MHillasExt.fM3Long*sign(MHillasSrc.fCosDeltaAlpha)*MGeomCam.fConvMm2Deg"); 298 318 299 fMap[kES rcSign]= fMatrix->AddColumn("sign(MHillasSrc.fCosDeltaAlpha)");319 fMap[kESign] = fMatrix->AddColumn("sign(MHillasSrc.fCosDeltaAlpha)"); 300 320 301 321 fMap[kESlope] = fMatrix->AddColumn("MHillasExt.fSlopeLong*sign(MHillasSrc.fCosDeltaAlpha)/MGeomCam.fConvMm2Deg"); 322 323 if (!fCalcDisp) 324 fMap[kEDisp] = fMatrix->AddColumn("abs(Disp.fVal)"); 325 326 if (!fCalcGhostbuster) 327 fMap[kEGhostbuster] = fMatrix->AddColumn("Ghostbuster.fVal"); 302 328 303 329 if (fThetaCut&kOff) … … 321 347 // If par!=NULL p is stored in this MParameterD 322 348 // 323 Double_t MFMagicCuts::GetThetaSq(Double_t p, Double_t wl, Double_td, Double_t a) const349 Double_t MFMagicCuts::GetThetaSq(Double_t p, Double_t d, Double_t a) const 324 350 { 325 351 // wl = width/l [1] … … 338 364 } 339 365 340 // --------------------------------------------------------------------------- 341 // 342 // Evaluate dynamical magic-cuts 343 // 344 Int_t MFMagicCuts::Process() 345 { 366 // -------------------------------------------------------------------------- 367 // 368 // Return abs(Disp.fVal) if disp calculation is switched off. 369 // Otherwise return (c0+c6*leak^c7)*(1-width/length) 370 // 371 Double_t MFMagicCuts::GetDisp(Double_t slope, Double_t lgsize) const 372 { 373 if (!fCalcDisp) 374 return fMatrix ? GetVal(kEDisp) : TMath::Abs(fDisp->GetVal()); 375 346 376 // Get some variables 347 const Double_t wdivl = fMatrix ? GetVal(kEWdivL) : fHil->GetWidth()/fHil->GetLength(); 348 const Double_t lgsize = fMatrix ? GetVal(kESize) : TMath::Log10(fHil->GetSize()); 349 const Double_t leak = fMatrix ? GetVal(kELeakage) : TMath::Log10(fNewImgPar->GetLeakage1()+1); 377 const Double_t wdivl = fMatrix ? GetVal(kEWdivL) : fHil->GetWidth()/fHil->GetLength(); 378 const Double_t leak = fMatrix ? GetVal(kELeakage) : TMath::Log10(fNewImgPar->GetLeakage1()+1); 350 379 351 380 // For simplicity 352 381 const Double_t *c = fVariables.GetArray(); 353 382 383 // As rule for root or MDataPhrase: 384 // ((M[3]>[3])*[4]*(M[3]-[3])^2 + [2]*M[2] + [1]*M[1] + [0])*M[0] 385 // 386 Double_t xi = c[0] + c[8]*slope + c[9]*leak; 387 if (lgsize>c[10]) 388 xi += (lgsize-c[10])*(lgsize-c[10])*c[11]; 389 390 const Double_t disp = xi*(1-wdivl); 391 392 return disp; 393 } 394 395 Bool_t MFMagicCuts::IsGhost(Double_t m3long, Double_t slope, Double_t dist) const 396 { 397 // For simplicity 398 const Double_t *c = fVariables.GetArray(); 399 400 if (!fCalcGhostbuster) 401 return (fMatrix ? GetVal(kEGhostbuster) : fGhostbuster->GetVal())<c[12]; 402 403 // Do Ghostbusting with slope and m3l 404 const Bool_t sign1 = m3long < c[5]; 405 const Bool_t sign2 = slope > (dist-c[7])*c[6]; 406 407 return sign1 || sign2; 408 } 409 410 // --------------------------------------------------------------------------- 411 // 412 // Evaluate dynamical magic-cuts 413 // 414 Int_t MFMagicCuts::Process() 415 { 416 // For simplicity 417 const Double_t *c = fVariables.GetArray(); 418 419 // Default if we return before the end 420 fResult = kFALSE; 421 354 422 // Value for Theta cut (Disp parametrization) 355 423 const Double_t cut = GetThetaSqCut(); 356 const Double_t xi = c[0]+c[6]*pow(leak, c[7]);357 const Double_t disp = xi*(1-wdivl);358 359 // Default if we return before the end360 fResult = kFALSE;361 424 362 425 // ------------------- Most efficient cut ----------------------- 363 426 // ---------------------- Theta cut ON -------------------------- 364 const Double_t dist = fMatrix ? GetVal(kEDist) : fHilSrc->GetDist()*fMm2Deg; 365 const Double_t alpha = fMatrix ? GetVal(kEAlpha) : fHilSrc->GetAlpha(); 366 const Double_t sign = fMatrix ? GetVal(kESrcSign) : MMath::Sgn(fHilSrc->GetCosDeltaAlpha()); 367 const Double_t m3long = fMatrix ? GetVal(kEM3Long) : fHilExt->GetM3Long()*TMath::Sign(fMm2Deg, fHilSrc->GetCosDeltaAlpha()); 368 const Double_t slope = fMatrix ? GetVal(kESlope) : fHilExt->GetSlopeLong()/TMath::Sign(fMm2Deg, fHilSrc->GetCosDeltaAlpha()); 369 370 // Do Ghostbusting with slope and m3l 371 const Double_t sign1 = (dist-c[9])*c[8]-slope; 372 const Double_t sign2 = m3long-c[5]; 427 const Double_t dist = fMatrix ? GetVal(kEDist) : fHilSrc->GetDist()*fMm2Deg; 428 const Double_t alpha = fMatrix ? GetVal(kEAlpha) : fHilSrc->GetAlpha(); 429 const Double_t m3long = fMatrix ? GetVal(kEM3Long) : fHilExt->GetM3Long()*TMath::Sign(fMm2Deg, fHilSrc->GetCosDeltaAlpha()); 430 const Double_t slope = fMatrix ? GetVal(kESlope) : fHilExt->GetSlopeLong()/TMath::Sign(fMm2Deg, fHilSrc->GetCosDeltaAlpha()); 431 const Double_t sign = fMatrix ? GetVal(kESign) : MMath::Sgn(fHilSrc->GetCosDeltaAlpha()); 432 const Double_t lgsize = fMatrix ? GetVal(kESize) : TMath::Log10(fHil->GetSize()); 373 433 374 434 // Calculate disp including sign 375 const Double_t p = sign1<0 || sign2<0 ? -disp : disp;376 377 // Align disp along source direction depending on third moment 378 //const Double_t p = TMath::Sign(disp, m3long-c[5]);435 const Double_t disp = GetDisp(slope, lgsize); 436 const Double_t ghost = IsGhost(m3long, slope, dist); 437 438 const Double_t p = ghost ? -disp : disp; 379 439 380 440 // Align sign of disp along shower axis like m3long … … 382 442 383 443 // Calculate corresponding Theta^2 384 const Double_t thetasq = GetThetaSq(p, wdivl,dist, alpha);444 const Double_t thetasq = GetThetaSq(p, dist, alpha); 385 445 fThetaSq->SetVal(thetasq); 386 446 … … 405 465 { 406 466 const Double_t had = fMatrix ? GetVal(kEHadronness) : fHadronness->GetVal(); 407 if (had>c[1 0])467 if (had>c[13]) 408 468 return kTRUE; 409 469 410 if (TMath::Power(10, lgsize)<c[1 1])470 if (TMath::Power(10, lgsize)<c[14]) 411 471 return kTRUE; 412 472 } … … 422 482 const Double_t slopeanti = fMatrix ? GetVal(kESlopeAnti) : fHilExt->GetSlopeLong()/TMath::Sign(fMm2Deg, fHilAnti->GetCosDeltaAlpha()); 423 483 424 // Do Ghostbusting with slope and m3l425 const Double_t sign3 = (distanti-c[9])*c[8]-slopeanti;426 const Double_t sign4 = m3lanti-c[5]; 427 const Double_t panti = sign3<0 || sign4<0 ? -disp : disp;484 const Double_t dispanti = GetDisp(slopeanti, lgsize); 485 const Double_t ghostanti = IsGhost(m3lanti, slopeanti, lgsize); 486 487 const Double_t panti = ghostanti ? -dispanti : dispanti; 428 488 429 489 // Align disp along source direction depending on third moment 430 //const Double_t panti = TMath::Sign(disp, m3lanti-c[5]); 431 const Double_t thetasqanti = GetThetaSq(panti, wdivl, distanti, alphaanti); 490 const Double_t thetasqanti = GetThetaSq(panti, distanti, alphaanti); 432 491 433 492 if (thetasqanti<cut) … … 494 553 break; 495 554 } 555 if (fCalcDisp) 556 *fLog << "Disp is calculated from c0, c7, c8." << endl; 557 else 558 *fLog << "Disp.fVal from the parameter list is used as disp." << endl; 559 if (fCalcGhostbuster) 560 *fLog << "Ghostbusting is calculated from c5, c6, c7." << endl; 561 else 562 *fLog << "Ghostbuster.fVal from the parameter list is used for ghostbusting." << endl; 563 496 564 *fLog << "Filter is" << (IsInverted()?"":" not") << " inverted." << endl; 497 565 … … 568 636 rc = kTRUE; 569 637 } 638 570 639 if (IsEnvDefined(env, prefix, "HadronnessCut", print)) 571 640 { … … 586 655 } 587 656 657 if (IsEnvDefined(env, prefix, "CalcDisp", print)) 658 { 659 fCalcDisp = GetEnvValue(env, prefix, "CalcDisp", fCalcDisp); 660 rc = kTRUE; 661 } 662 663 if (IsEnvDefined(env, prefix, "CalcGhostbuster", print)) 664 { 665 fCalcGhostbuster = GetEnvValue(env, prefix, "CalcGhostbuster", fCalcGhostbuster); 666 rc = kTRUE; 667 } 668 588 669 if (IsEnvDefined(env, prefix, "File", print)) 589 670 { … … 605 686 } 606 687 return rc; 607 //return kTRUE; // means: can use default values 608 //return rc; // means: require something in resource file 609 } 688 } -
trunk/MagicSoft/Mars/mfilter/MFMagicCuts.h
r8619 r8646 43 43 enum { 44 44 kESize, kEAlpha, kEAlphaAnti, kEArea, kEDist, kEDistAnti, 45 kEM3Long, kEM3LongAnti, kEWdivL, kELeakage, kES rcSign,46 kESlope , kESlopeAnti, kEHadronness,45 kEM3Long, kEM3LongAnti, kEWdivL, kELeakage, kESlope, 46 kESlopeAnti, kEHadronness, kESign, kEDisp, kEGhostbuster, 47 47 kLastElement 48 48 }; … … 55 55 MParameterD *fThetaSq; //! Pointer to MParameterD container called ThetaSq 56 56 MParameterD *fDisp; //! Pointer to MParameterD container called Disp 57 MParameterD *fGhostbuster; //! Pointer to MParameterD container called Ghostbuster 57 58 MParameterD *fHadronness; //! Pointer to MParameterD container called Hadronness 58 59 … … 67 68 ThetaCut_t fThetaCut; // Which kind of theta cut should be evaluated 68 69 HadronnessCut_t fHadronnessCut; // Which kind of hadronness cut should be evaluated 70 Bool_t fCalcDisp; // Should we use Disp from the parameterlist? 71 Bool_t fCalcGhostbuster; // Should we use Ghostbuster from the parameterlist? 69 72 70 73 // MTask … … 76 79 77 80 // MFMagicCuts 81 Double_t GetDisp(Double_t slope, Double_t lgsize) const; 82 Bool_t IsGhost(Double_t m3long, Double_t slope, Double_t dist) const; 78 83 Double_t GetVal(Int_t i) const; 79 84 TString GetParam(Int_t i) const; 80 Double_t GetThetaSq(Double_t p, Double_t wl, Double_td, Double_t a) const;85 Double_t GetThetaSq(Double_t p, Double_t d, Double_t a) const; 81 86 82 87 public: … … 89 94 void SetThetaCut(ThetaCut_t c) { fThetaCut=c; } 90 95 void SetHadronnessCut(HadronnessCut_t c) { fHadronnessCut=c; } 96 void SetCalcDisp(Bool_t b=kTRUE) { fCalcDisp=b; } 97 void SetCalcGhostbuster(Bool_t b=kTRUE) { fCalcGhostbuster=b; } 91 98 92 99 // MFMagicCuts -
trunk/MagicSoft/Mars/mimage/MImgCleanStd.cc
r8554 r8646 21 21 ! Author(s): Stefan Ruegamer, 03/2006 <mailto:snruegam@astro.uni-wuerzburg.de> 22 22 ! 23 ! Copyright: MAGIC Software Development, 2000-200 623 ! Copyright: MAGIC Software Development, 2000-2007 24 24 ! 25 25 ! … … 279 279 // 280 280 // 281 // Class Version 4: 282 // ---------------- 283 // + Float_t fTimeLvl2; 284 // - Bool_t fKeepSinglePixels; 285 // + Bool_t fKeepIsolatedPixels; 286 // + Int_t fRecoverIsolatedPixels; 287 // 288 // 281 289 // Input Containers: 282 290 // MGeomCam … … 302 310 #include "MLogManip.h" 303 311 312 #include "MArrayI.h" 304 313 #include "MParList.h" 305 314 #include "MCameraData.h" … … 339 348 MImgCleanStd::MImgCleanStd(const Float_t lvl1, const Float_t lvl2, 340 349 const char *name, const char *title) 341 : fCleaningMethod(kStandard), fCleanLvl1(lvl1), 342 fCleanLvl2(lvl2), fCleanRings(1), fKeepSinglePixels(kFALSE), 343 fNamePedPhotCam(gsNamePedPhotCam), fNameGeomCam(gsNameGeomCam), 344 fNameSignalCam(gsNameSignalCam) 350 : fCleaningMethod(kStandard), fCleanLvl0(lvl1), fCleanLvl1(lvl1), 351 fCleanLvl2(lvl2), fTimeLvl1(1.5), fTimeLvl2(1.5), fCleanRings(1), 352 fKeepIsolatedPixels(kFALSE), fRecoverIsolatedPixels(0), 353 fPostCleanType(0), fNamePedPhotCam(gsNamePedPhotCam), 354 fNameGeomCam(gsNameGeomCam), fNameSignalCam(gsNameSignalCam) 345 355 { 346 356 fName = name ? name : gsDefName.Data(); 347 357 fTitle = title ? title : gsDefTitle.Data(); 358 } 359 360 void MImgCleanStd::ResetCleaning() const 361 { 362 // 363 // check the number of all pixels against the noise level and 364 // set them to 'unused' state if necessary 365 // 366 const UInt_t npixevt = fEvt->GetNumPixels(); 367 for (UInt_t idx=0; idx<npixevt; idx++) 368 { 369 MSignalPix &pix = (*fEvt)[idx]; 370 if (pix.IsPixelUnmapped()) 371 continue; 372 373 pix.SetPixelUnused(); 374 pix.SetPixelCore(kFALSE); 375 } 348 376 } 349 377 … … 367 395 // 368 396 // 369 void MImgCleanStd::CleanStep1() 370 { 397 Bool_t MImgCleanStd::HasCoreNeighbors(const MGeomPix &gpix) const 398 { 399 // if (fKeepIsolatedPixels) 400 // return kTRUE; 401 402 #ifdef DEBUG 371 403 const TArrayD &data = fData->GetData(); 404 #else 405 const Double_t *data = fData->GetData().GetArray(); 406 #endif 407 408 //loop on the neighbors to check if they are used 409 const Int_t n = gpix.GetNumNeighbors(); 410 for (Int_t i=0; i<n; i++) 411 { 412 const Int_t idx = gpix.GetNeighbor(i); 413 414 // Check if a neighborpixel of our core pixel is 415 // also a core pixel 416 if (data[idx]<=fCleanLvl1) 417 continue; 418 419 // Ignore unmapped pixels 420 MSignalPix &pix = (*fEvt)[idx]; 421 if (pix.IsPixelUnmapped()) 422 continue; 423 424 return kTRUE; 425 } 426 427 return kFALSE; 428 } 429 430 Bool_t MImgCleanStd::HasUsedNeighbors(const MGeomPix &gpix) const 431 { 432 //loop on the neighbors to check if they are used 433 const Int_t n = gpix.GetNumNeighbors(); 434 for (Int_t i=0; i<n; i++) 435 { 436 const Int_t idx = gpix.GetNeighbor(i); 437 438 MSignalPix &pix = (*fEvt)[idx]; 439 440 // Check if a neighborpixel of our core pixel is 441 // also a core pixel 442 if (pix.IsPixelUsed() && !pix.IsPixelUnmapped()) 443 return kTRUE; 444 } 445 446 return kFALSE; 447 } 448 449 450 void MImgCleanStd::SetUsedNeighbors(const MGeomPix &gpix, Int_t r) const 451 { 452 if (r>fCleanRings) 453 return; 454 455 #ifdef DEBUG 456 const TArrayD &data = fData->GetData(); 457 #else 458 const Double_t *data = fData->GetData().GetArray(); 459 #endif 460 461 // At least one neighbor has been identified as core, 462 // that means we will keep the pixel 463 const Int_t n = gpix.GetNumNeighbors(); 464 for (Int_t i=0; i<n; i++) 465 { 466 const Int_t idx = gpix.GetNeighbor(i); 467 468 MSignalPix &pix = (*fEvt)[idx]; 469 470 // If the pixel has been assigned to the same or a previous 471 // ring we don't have to proceed. We have to try to set the 472 // ring number of each pixel as low as possible. This means 473 // we are only allowed to increase the ring number. 474 if (pix.IsPixelUsed() && pix.GetRing()<=r) 475 continue; 476 477 // All pixels below the second cleaning level should be ignored 478 if (data[idx] <= fCleanLvl2) 479 continue; 480 481 // Ignore unmapped pixels (remark: used (aka. ring>0) 482 // and unmapped status is exclusive 483 if (pix.IsPixelUnmapped()) 484 continue; 485 486 // Set or reset the ring number 487 pix.SetRing(r); 488 489 // Step forward to the surrounding pixels 490 SetUsedNeighbors((*fCam)[idx], r+1); 491 } 492 } 493 494 // -------------------------------------------------------------------------- 495 // 496 // Here we do the cleaning. We search for all the possible core candidates 497 // and from them on we recursively search for used pixels with 498 // SetUsedNeighbors. To check the validity of a core pixel 499 // either fTimeLvl2 and/or HasCoreNeighbors is used. 500 // The size of all removed 501 Int_t MImgCleanStd::DoCleaning(Float_t &size) const 502 { 503 Int_t n = 0; 504 size = 0; 505 506 #ifdef DEBUG 507 const TArrayD &data = fData->GetData(); 508 #else 509 const Double_t *data = fData->GetData().GetArray(); 510 #endif 372 511 373 512 // … … 378 517 for (UInt_t idx=0; idx<npixevt; idx++) 379 518 { 380 // The default for pixels is "used" set by381 // MParContainer::Reset before processing382 if (data[idx]>fCleanLvl1)383 continue;384 385 // Setting a pixel to unused if it is unmapped would overwrite386 // the unmapped-status. Therefor this pixels are excluded.387 519 MSignalPix &pix = (*fEvt)[idx]; 388 if (!pix.IsPixelUnmapped()) 389 pix.SetPixelUnused(); 390 } 391 } 392 393 // -------------------------------------------------------------------------- 394 // 395 // Check if the survived pixel have a neighbor, that also 396 // survived. Set all single pixels Unused if !fKeepSinglePixels. Now we 397 // declare all pixels that survived previous CleanSteps as CorePixels. 398 // Return number of single pixels, and there cumulative size in size. 399 // 400 Short_t MImgCleanStd::CleanStep2(Float_t &size) 401 { 402 Short_t n=0; 403 size = 0; 404 520 521 // Check if this pixel is a possible candidate for a core pixel 522 if (data[idx] <= fCleanLvl1) 523 continue; 524 525 // Ignore unmapped pixels 526 if (pix.IsPixelUnmapped()) 527 continue; 528 529 const MGeomPix &gpix = (*fCam)[idx]; 530 531 // Check if the pixel is an isolated core pixel 532 if (!HasCoreNeighbors(gpix)) 533 { 534 // Count size and number of isolated core pixels 535 size += pix.GetNumPhotons(); 536 n++; 537 538 // If isolated pixels should not be kept or the pixel 539 // is lower than the cleaning level for isolated core 540 // pixels. It is not treated as core pixel. 541 if (!fKeepIsolatedPixels || data[idx]<=fCleanLvl0) 542 continue; 543 } 544 545 // Mark pixel as used and core 546 pix.SetPixelUsed(); 547 pix.SetPixelCore(); 548 549 // Check if neighbor pixels should be marked as used 550 // This is done recursively depening on fCleanRings 551 SetUsedNeighbors(gpix); 552 } 553 554 return n; 555 } 556 557 /* 558 Float_t MImgCleanStd::GetArrivalTimeNeighbor(const MGeomPix &gpix) const 559 { 560 Float_t min = FLT_MAX; 561 562 const Int_t n = gpix.GetNumNeighbors(); 563 for (int i=0; i<n; i++) 564 { 565 const Int_t idx = gpix.GetNeighbor(i); 566 567 const MSignalPix &pix = (*fEvt)[idx]; 568 // FIXME: Check also used pixels? 569 if (!pix.IsCorePixel()) 570 continue; 571 572 const Float_t tm = pix.GetArrivalTime(); 573 if (tm<min) 574 min = tm; 575 } 576 577 return tm; 578 } 579 580 void MImgCleanStd::CheckUsedPixelsForArrivalTime(Float_t timediff) const 581 { 582 const MArrayD &data = fData->GetData(); 583 584 // 585 // check the number of all pixels against the noise level and 586 // set them to 'unused' state if necessary 587 // 405 588 const UInt_t npixevt = fEvt->GetNumPixels(); 406 589 for (UInt_t idx=0; idx<npixevt; idx++) 407 590 { 408 // Exclude all unused (this includes all unmapped) pixels409 591 MSignalPix &pix = (*fEvt)[idx]; 592 593 // If pixel has previously been marked used, ignore 594 if (!pix.IsPixelUsed() || pix.IsPixelCore()) 595 continue; 596 597 const MGeomPix &gpix = (*fCam)[idx]; 598 599 // If isolated possible-corepixel doesn't have used 600 // neighbors, ignore it 601 const Float_t tm0 = pix.GetArrivalTime(); 602 const Float_t tm1 = GetArrivalTimeCoreNeighbor(gpix); 603 604 if (TMath::Abs(tm0-tm1)<timediff) 605 continue; 606 607 // Mark pixel as used and core 608 pix.SetPixelUnused(); 609 } 610 } 611 */ 612 613 Int_t MImgCleanStd::RecoverIsolatedPixels(Float_t &size) const 614 { 615 #ifdef DEBUG 616 const TArrayD &data = fData->GetData(); 617 #else 618 const Double_t *data = fData->GetData().GetArray(); 619 #endif 620 621 Int_t n = 0; 622 623 // 624 // check the number of all pixels against the noise level and 625 // set them to 'unused' state if necessary 626 // 627 const UInt_t npixevt = fEvt->GetNumPixels(); 628 for (UInt_t idx=0; idx<npixevt; idx++) 629 { 630 MSignalPix &pix = (*fEvt)[idx]; 631 632 // If pixel has previously been marked used, ignore 633 if (pix.IsPixelUsed()) 634 continue; 635 636 // If pixel is not a candidate for a core pixel, ignore 637 if (data[idx] <= fCleanLvl1) 638 continue; 639 640 const MGeomPix &gpix = (*fCam)[idx]; 641 642 // If isolated possible-corepixel doesn't have used 643 // neighbors, ignore it 644 if (!HasUsedNeighbors(gpix)) 645 continue; 646 647 // Mark pixel as used and core 648 pix.SetPixelUsed(); 649 pix.SetPixelCore(); 650 651 // Check if neighbor pixels should be marked as used 652 // This is done recursively depening on fCleanRings 653 SetUsedNeighbors(gpix); 654 655 size -= pix.GetNumPhotons(); 656 n++; 657 } 658 659 return n; 660 } 661 662 void MImgCleanStd::CleanTime(Int_t n, Double_t lvl) const 663 { 664 MArrayI indices; 665 666 const UInt_t npixevt = fEvt->GetNumPixels(); 667 for (UInt_t idx=0; idx<npixevt; idx++) 668 { 669 // check if pixel is used or not 670 const MSignalPix &pix = (*fEvt)[idx]; 410 671 if (!pix.IsPixelUsed()) 411 672 continue; 412 413 // check for 'used' neighbors of this pixel414 const MGeomPix &gpix = (*fCam)[idx];415 const Int_t nnmax = gpix.GetNumNeighbors(); 416 417 Bool_t hasNeighbor = kFALSE;418 419 //loop on the neighbors to check if they are used 420 for (Int_t j=0; j<nnmax; j++)673 674 // get arrival time 675 const Double_t tm0 = pix.GetArrivalTime(); 676 677 // loop over its neighbpors 678 const MGeomPix &gpix = (*fCam)[idx]; 679 680 Int_t cnt = 0; 681 for (Int_t i=0; i<gpix.GetNumNeighbors(); i++) 421 682 { 422 const Int_t idx2 = gpix.GetNeighbor(j); 423 424 // when you find an used neighbor (this excludes unused 425 // and unmapped pixels) break the loop 426 if ((*fEvt)[idx2].IsPixelUsed()) 427 { 428 hasNeighbor = kTRUE; 683 // Get index of neighbor 684 const Int_t idx2 = gpix.GetNeighbor(i); 685 686 // check if neighbor is used or not 687 const MSignalPix &npix = (*fEvt)[idx2]; 688 if (!npix.IsPixelUsed()) 689 continue; 690 691 // If this pixel is to far away (in arrival time) don't count 692 if (TMath::Abs(npix.GetArrivalTime()-tm0)>lvl) 693 continue; 694 695 // Now count the pixel. If we did not found n pixels yet 696 // which fullfill the condition, go on searching 697 if (++cnt>=n) 429 698 break; 430 }431 699 } 432 700 433 // If the pixel has at least one core-neighbor 434 // go on with the next pixel 435 if (hasNeighbor) 436 continue; 437 438 // If the pixel has no neighbors and the single pixels 439 // should not be kept turn the used- into an unused-status 440 if (!fKeepSinglePixels) 441 pix.SetPixelUnused(); 442 443 // count size and number of single core-pixels 444 size += pix.GetNumPhotons(); 445 n++; 446 } 447 448 // Now turn the used-status into the core-status 449 // (FIXME: A more intelligent handling of used/core in clean step1/2 450 // would make this loop obsolete!) 451 for (UInt_t idx=0; idx<npixevt; idx++) 452 { 453 MSignalPix &pix = (*fEvt)[idx]; 454 pix.SetPixelCore(pix.IsPixelUsed()); 455 } 456 457 return n; 458 } 459 460 void MImgCleanStd::CleanStep3b(Int_t idx) 461 { 462 MSignalPix &pix = (*fEvt)[idx]; 463 464 // 465 // check if the pixel's next neighbor is a core pixel. 466 // if it is a core pixel set pixel state to: used. 467 // 468 MGeomPix &gpix = (*fCam)[idx]; 469 const Int_t nnmax = gpix.GetNumNeighbors(); 470 471 for (Int_t j=0; j<nnmax; j++) 472 { 473 const Int_t idx2 = gpix.GetNeighbor(j); 474 475 // Check if the neighbor pixel is a core pixel. (Rem: Unampped 476 // pixels are never assigned the core-pixel status) 477 if (!(*fEvt)[idx2].IsPixelCore()) 478 continue; 479 480 pix.SetPixelUsed(); 481 break; 482 } 483 } 484 485 // -------------------------------------------------------------------------- 486 // 487 // NT: Add option "rings": default value = 1. 488 // Look n (n>1) times for the boundary pixels around the used pixels. 489 // If a pixel has more than 2.5 (clean level 2.5) sigma, 490 // it is declared as used. 491 // 492 // If a value<2 for fCleanRings is used, no CleanStep4 is done. 493 // 494 void MImgCleanStd::CleanStep4(UShort_t r, Int_t idx) 495 { 496 MSignalPix &pix = (*fEvt)[idx]; 497 498 // 499 // Skip events that have already a defined status; 500 // 501 if (pix.GetRing() != 0) 701 // If we found at least n neighbors which are 702 // with a time difference of lvl keep the pixel 703 if (cnt>=n) 704 continue; 705 706 indices.Set(indices.GetSize()+1); 707 indices[indices.GetSize()-1] = idx; 708 } 709 710 // Now remove the pixels which didn't fullfill the requirement 711 for (UInt_t i=0; i<indices.GetSize(); i++) 712 { 713 (*fEvt)[indices[i]].SetPixelUnused(); 714 (*fEvt)[indices[i]].SetPixelCore(kFALSE); 715 } 716 } 717 718 void MImgCleanStd::CleanStepTime() const 719 { 720 if (fPostCleanType<=0) 502 721 return; 503 722 504 // 505 // check if the pixel's next neighbor is a used pixel. 506 // if it is a used pixel set pixel state to: used, 507 // and tell to which ring it belongs to. 508 // 509 MGeomPix &gpix = (*fCam)[idx]; 510 511 const Int_t nnmax = gpix.GetNumNeighbors(); 512 513 for (Int_t j=0; j<nnmax; j++) 514 { 515 const Int_t idx2 = gpix.GetNeighbor(j); 516 517 const MSignalPix &npix = (*fEvt)[idx2]; 518 if (!npix.IsPixelUsed() || npix.GetRing()>r-1 ) 519 continue; 520 521 pix.SetRing(r); 522 break; 523 } 524 } 525 526 // -------------------------------------------------------------------------- 527 // 528 // Look for the boundary pixels around the core pixels 529 // if a pixel has more than 2.5 (clean level 2.5) sigma, and 530 // a core neighbor, it is declared as used. 531 // 532 void MImgCleanStd::CleanStep3() 533 { 534 const TArrayD &data = fData->GetData(); 535 536 for (UShort_t r=1; r<fCleanRings+1; r++) 537 { 538 // Loop over all pixels 539 const UInt_t npixevt = fEvt->GetNumPixels(); 540 for (UInt_t idx=0; idx<npixevt; idx++) 541 { 542 MSignalPix &pix = (*fEvt)[idx]; 543 544 // 545 // if pixel is a core pixel or unmapped, go to the next pixel 546 // 547 if (pix.IsPixelCore() || pix.IsPixelUnmapped()) 548 continue; 549 550 if (data[idx] <= fCleanLvl2) 551 continue; 552 553 if (r==1) 554 CleanStep3b(idx); 555 else 556 CleanStep4(r, idx); 557 } 558 } 723 if (fPostCleanType&2) 724 CleanTime(2, fTimeLvl2); 725 726 if (fPostCleanType&1) 727 CleanTime(1, fTimeLvl1); 559 728 } 560 729 … … 572 741 return kFALSE; 573 742 } 574 575 743 fEvt = (MSignalCam*)pList->FindObject(AddSerialNumber(fNameSignalCam), "MSignalCam"); 576 744 if (!fEvt) … … 595 763 return kFALSE; 596 764 765 if (fCleanLvl2>fCleanLvl1) 766 { 767 *fLog << warn << "WARNING - fCleanLvl2 (" << fCleanLvl2 << ") > fCleanLvl1 (" << fCleanLvl1 << ")... resetting fCleanLvl2." << endl; 768 fCleanLvl2 = fCleanLvl1; 769 } 770 771 if (fCleanLvl2==fCleanLvl1 && fCleanRings>0) 772 { 773 *fLog << warn << "WARNING - fCleanLvl2 == fCleanLvl1 (" << fCleanLvl1 << ") but fCleanRings>0... resetting fCleanRings to 0." << endl; 774 fCleanRings=0; 775 } 776 777 if (fKeepIsolatedPixels && fTimeLvl2<fCleanLvl1) 778 { 779 *fLog << warn << "WARNING - fKeepIsolatedPixels set but CleanLvl0 (" << fTimeLvl2 << ") < fCleanLvl1 (" << fCleanLvl1 << ")... resetting fTimeLvl2." << endl; 780 fTimeLvl2 = fCleanLvl1; 781 } 782 if (!fKeepIsolatedPixels && fTimeLvl2>fCleanLvl1) 783 { 784 *fLog << warn << "WARNING - fKeepIsolatedPixels not set but CleanLvl0 (" << fTimeLvl2 << ") > fCleanLvl1 (" << fCleanLvl1 << ")... setting fKeepIsolatedCorePixels." << endl; 785 fKeepIsolatedPixels=kTRUE; 786 } 787 788 if (fKeepIsolatedPixels && fTimeLvl2==fCleanLvl1 && fRecoverIsolatedPixels!=0) 789 { 790 *fLog << warn << "WARNING - fTimeLvl2 == fCleanLvl1 (" << fTimeLvl2 << ") and fKeepSinglePixels and fRecoverIsolatedPixels!=0... setting fRecoverIsolatedPixels=0." << endl; 791 fRecoverIsolatedPixels = 0; 792 } 793 597 794 Print(); 598 795 … … 631 828 632 829 #ifdef DEBUG 633 *fLog << all << " CleanStep 1" << endl;830 *fLog << all << "ResetCleaning" << endl; 634 831 #endif 635 CleanStep1(); 636 832 ResetCleaning(); 637 833 638 834 #ifdef DEBUG 639 *fLog << all << " CleanStep 2" << endl;835 *fLog << all << "DoCleaning" << endl; 640 836 #endif 641 837 Float_t size; 642 const Short_t n = CleanStep2(size); 838 Short_t n = DoCleaning(size); 839 840 #ifdef DEBUG 841 *fLog << all << "RecoverIsolatedPixels" << endl; 842 #endif 843 for (UInt_t i=0; i<(UInt_t)fRecoverIsolatedPixels; i++) 844 { 845 const Int_t rc=RecoverIsolatedPixels(size); 846 if (rc==0) 847 break; 848 849 n -= rc; 850 } 851 852 #ifdef DEBUG 853 *fLog << all << "Time Cleaning" << endl; 854 #endif 855 // FIXME: Remove removed core piselx? 856 CleanStepTime(); 857 643 858 fEvt->SetSinglePixels(n, size); 644 859 645 // For speed reasons skip the rest of the cleaning if no646 // action will be taken!647 if (fCleanLvl1>fCleanLvl2)648 {649 860 #ifdef DEBUG 650 *fLog << all << "CleanStep 3" << endl; 651 #endif 652 CleanStep3(); 653 } 654 655 #ifdef DEBUG 656 *fLog << all << "Calc Islands" << endl; 861 *fLog << all << "CalcIslands" << endl; 657 862 #endif 658 863 // Takes roughly 10% of the time … … 698 903 *fLog << "initialized with level " << fCleanLvl1 << " and " << fCleanLvl2; 699 904 *fLog << " (CleanRings=" << fCleanRings << ")" << endl; 905 906 if (fPostCleanType) 907 { 908 *fLog << "Time post cleaning is switched on with:" << endl; 909 if (fPostCleanType&2) 910 *fLog << " - Two pixel coincidence window: " << fTimeLvl2 << "ns" << endl; 911 if (fPostCleanType&1) 912 *fLog << " - One pixel coincidence window: " << fTimeLvl1 << "ns" << endl; 913 } 914 915 if (fKeepIsolatedPixels) 916 *fLog << "isolated core pixels will be kept above " << fCleanLvl0 << endl; 917 918 if (fRecoverIsolatedPixels) 919 { 920 if (fRecoverIsolatedPixels<0) 921 *fLog << "all "; 922 *fLog << "isolated core pixels with used pixels as neighbors will be recovered"; 923 if (fRecoverIsolatedPixels>0) 924 *fLog << " " << fRecoverIsolatedPixels << " times"; 925 *fLog << "." << endl;; 926 } 700 927 701 928 if (fCleaningMethod!=kAbsolute && fCleaningMethod!=kTime) … … 848 1075 if (gsNameSignalCam!=fNameSignalCam) 849 1076 out << " " << GetUniqueName() << ".SetNameSignalCam(\"" << fNameSignalCam << "\");" << endl; 850 if (fKeepSinglePixels) 851 out << " " << GetUniqueName() << ".SetKeepSinglePixels();" << endl; 1077 if (fKeepIsolatedPixels) 1078 out << " " << GetUniqueName() << ".SetKeepIsolatedPixels();" << endl; 1079 if (fRecoverIsolatedPixels) 1080 out << " " << GetUniqueName() << ".SetRecoverIsolatedPixels(" << fRecoverIsolatedPixels << ");" << endl; 852 1081 853 1082 } … … 860 1089 // MImgCleanStd.CleanMethod: Standard, Scaled, Democratic, Probability, Absolute 861 1090 // MImgCleanStd.CleanRings: 1 862 // MImgCleanStd.Keep SinglePixels: yes, no1091 // MImgCleanStd.KeepIsolatedPixels: yes, no 863 1092 // 864 1093 Int_t MImgCleanStd::ReadEnv(const TEnv &env, TString prefix, Bool_t print) … … 870 1099 SetCleanRings(GetEnvValue(env, prefix, "CleanRings", fCleanRings)); 871 1100 } 1101 if (IsEnvDefined(env, prefix, "CleanLevel0", print)) 1102 { 1103 rc = kTRUE; 1104 fCleanLvl0 = GetEnvValue(env, prefix, "CleanLevel0", fCleanLvl0); 1105 } 872 1106 if (IsEnvDefined(env, prefix, "CleanLevel1", print)) 873 1107 { … … 880 1114 fCleanLvl2 = GetEnvValue(env, prefix, "CleanLevel2", fCleanLvl2); 881 1115 } 882 if (IsEnvDefined(env, prefix, " KeepSinglePixels", print))1116 if (IsEnvDefined(env, prefix, "TimeLevel1", print)) 883 1117 { 884 1118 rc = kTRUE; 885 fKeepSinglePixels = GetEnvValue(env, prefix, "KeepSinglePixels", fKeepSinglePixels); 1119 fTimeLvl1 = GetEnvValue(env, prefix, "TimeLevel1", fTimeLvl1); 1120 } 1121 if (IsEnvDefined(env, prefix, "TimeLevel2", print)) 1122 { 1123 rc = kTRUE; 1124 fTimeLvl2 = GetEnvValue(env, prefix, "TimeLevel2", fTimeLvl2); 1125 } 1126 if (IsEnvDefined(env, prefix, "KeepIsolatedPixels", print)) 1127 { 1128 rc = kTRUE; 1129 fKeepIsolatedPixels = GetEnvValue(env, prefix, "KeepIsolatedPixels", fKeepIsolatedPixels); 1130 } 1131 if (IsEnvDefined(env, prefix, "RecoverIsolatedPixels", print)) 1132 { 1133 rc = kTRUE; 1134 fRecoverIsolatedPixels = GetEnvValue(env, prefix, "RecoverIsolatedPixels", fKeepIsolatedPixels); 1135 } 1136 if (IsEnvDefined(env, prefix, "PostCleanType", print)) 1137 { 1138 rc = kTRUE; 1139 fPostCleanType = GetEnvValue(env, prefix, "PostCleanType", fPostCleanType); 886 1140 } 887 1141 -
trunk/MagicSoft/Mars/mimage/MImgCleanStd.h
r7804 r8646 7 7 8 8 class MGeomCam; 9 class M Sigmabar;9 class MGeomPix; 10 10 class MSignalCam; 11 11 class MPedPhotCam; 12 12 class MArrivalTime; 13 13 class MCameraData; 14 //class MRawRunHeader; 14 15 15 16 class MGGroupFrame; … … 32 33 static const TString gsNameSignalCam; // default name of the 'MSignalCam' container 33 34 34 const MGeomCam *fCam; //! 35 MSignalCam *fEvt; //! 36 MPedPhotCam *fPed; //! 37 MCameraData *fData; //! 35 const MGeomCam *fCam; //! 36 MSignalCam *fEvt; //! 37 MPedPhotCam *fPed; //! 38 MCameraData *fData; //! 39 // MRawRunHeader *fHeader; //! 38 40 39 41 CleaningMethod_t fCleaningMethod; 40 42 43 Float_t fCleanLvl0; 41 44 Float_t fCleanLvl1; 42 45 Float_t fCleanLvl2; 43 46 47 Float_t fTimeLvl1; 48 Float_t fTimeLvl2; 49 44 50 UShort_t fCleanRings; 45 Bool_t fKeepSinglePixels; 51 Bool_t fKeepIsolatedPixels; 52 Int_t fRecoverIsolatedPixels; 53 Int_t fPostCleanType; 46 54 47 55 TString fNamePedPhotCam; // name of the 'MPedPhotCam' container … … 50 58 51 59 // MImgCleanStd 52 void CleanStep1(); 53 Short_t CleanStep2(Float_t &size); 54 void CleanStep3(); 55 void CleanStep3b(Int_t idx); 56 void CleanStep4(UShort_t r, Int_t idx); 60 Bool_t HasCoreNeighbors(const MGeomPix &gpix) const; 61 Bool_t HasUsedNeighbors(const MGeomPix &gpix) const; 62 void SetUsedNeighbors(const MGeomPix &gpix, Int_t r=1) const; 63 Int_t DoCleaning(Float_t &size) const; 64 void ResetCleaning() const; 65 Int_t RecoverIsolatedPixels(Float_t &size) const; 66 void CleanTime(Int_t n, Double_t lvl) const; 67 68 void CleanStepTime() const; 57 69 58 70 // MGTask, MTask, MParContainer … … 70 82 void Print(Option_t *o="") const; 71 83 72 Float_t GetCleanLvl1() const { return fCleanLvl1; } 73 Float_t GetCleanLvl2() const { return fCleanLvl2; } 84 Float_t GetCleanLvl0() const { return fCleanLvl0; } 85 Float_t GetCleanLvl1() const { return fCleanLvl1; } 86 Float_t GetCleanLvl2() const { return fCleanLvl2; } 87 88 Float_t GetTimeLvl1() const { return fTimeLvl1; } 89 Float_t GetTimeLvl2() const { return fTimeLvl2; } 90 91 void SetCleanLvl0(Float_t lvl) { fCleanLvl0=lvl; } 92 void SetCleanLvl1(Float_t lvl) { fCleanLvl1=lvl; } 93 void SetCleanLvl2(Float_t lvl) { fCleanLvl2=lvl; } 94 95 void SetTimeLvl1(Float_t lvl) { fTimeLvl1=lvl; } 96 void SetTimeLvl2(Float_t lvl) { fTimeLvl2=lvl; } 97 98 void SetCleanRings(UShort_t r) { fCleanRings=r; } 74 99 UShort_t GetCleanRings() const { return fCleanRings;} 75 100 76 void SetCleanRings(UShort_t r) { if(r==0) r=1; fCleanRings=r; }77 101 void SetMethod(CleaningMethod_t m) { fCleaningMethod = m; } 78 void SetKeepSinglePixels(Bool_t b=kTRUE) { fKeepSinglePixels=b; } 102 void SetKeepIsolatedPixels(Bool_t b=kTRUE) { fKeepIsolatedPixels=b; } 103 void SetRecoverIsolatedPixels(Int_t n=-1) { fRecoverIsolatedPixels=n; } 79 104 80 105 Bool_t ProcessMessage(Int_t msg, Int_t submsg, Long_t param1, Long_t param2); … … 84 109 void SetNameGeomCam(const char *name) { fNameGeomCam = name; } 85 110 86 ClassDef(MImgCleanStd, 3) // task doing the image cleaning111 ClassDef(MImgCleanStd, 4) // task doing the image cleaning 87 112 }; 88 113 -
trunk/MagicSoft/Mars/mjobs/MJCut.cc
r8644 r8646 388 388 write->AddContainer("OpticalAxis", "Events", kFALSE); 389 389 write->AddContainer("Disp", "Events", kFALSE); 390 write->AddContainer("Ghostbuster", "Events", kFALSE); 390 391 write->AddContainer("MEnergyEst", "Events", kFALSE); 391 392 write->AddContainer("MTime", "Events", kFALSE); -
trunk/MagicSoft/Mars/mjtrain/MJTrainEnergy.cc
r8644 r8646 145 145 146 146 // ------------------------ Train RF -------------------------- 147 MRanForestCalc rf( fTitle);147 MRanForestCalc rf("TrainEnergy", fTitle); 148 148 rf.SetNumTrees(fNumTrees); 149 149 rf.SetNdSize(fNdSize); -
trunk/MagicSoft/Mars/mjtrain/MJTrainSeparation.cc
r8644 r8646 802 802 // ------------------------ Train RF -------------------------- 803 803 804 MRanForestCalc rf ;804 MRanForestCalc rf("TrainSeparation", fTitle); 805 805 rf.SetNumTrees(fNumTrees); 806 806 rf.SetNdSize(fNdSize); -
trunk/MagicSoft/Mars/mranforest/MRanForestCalc.cc
r8644 r8646 1 1 /* ======================================================================== *\ 2 ! $Name: not supported by cvs2svn $:$Id: MRanForestCalc.cc,v 1.2 6 2007-07-24 13:35:39tbretz Exp $2 ! $Name: not supported by cvs2svn $:$Id: MRanForestCalc.cc,v 1.27 2007-07-26 11:13:00 tbretz Exp $ 3 3 ! -------------------------------------------------------------------------- 4 4 ! … … 229 229 tlist.AddToList(&fillh); 230 230 231 MEvtLoop evtloop(f Name);231 MEvtLoop evtloop(fTitle); 232 232 evtloop.SetParList(&plist); 233 233 evtloop.SetDisplay(fDisplay);
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