/**************************************************************************
- * Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. *
- * *
- * Author: The ALICE Off-line Project. *
- * Contributors are mentioned in the code where appropriate. *
- * *
- * Permission to use, copy, modify and distribute this software and its *
- * documentation strictly for non-commercial purposes is hereby granted *
- * without fee, provided that the above copyright notice appears in all *
- * copies and that both the copyright notice and this permission notice *
- * appear in the supporting documentation. The authors make no claims *
- * about the suitability of this software for any purpose. It is *
- * provided "as is" without express or implied warranty. *
- **************************************************************************/
-
-/* $Id$ */
-
-///////////////////////////////////////////////////////////
-//
-// Segment for reconstruction
-// in
-// ALICE
-// dimuon
-// spectrometer:
-// two hits for reconstruction in the two chambers of one station
-//
-///////////////////////////////////////////////////////////
-
-#include "AliMUONSegment.h"
-#include "AliMUON.h"
-#include "AliMUONHitForRec.h"
-#include "AliMUONTrackParam.h"
-#include "AliRun.h" // for gAlice
-#include "AliLog.h"
-
+* Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. *
+* *
+* Author: The ALICE Off-line Project. *
+* Contributors are mentioned in the code where appropriate. *
+* *
+* Permission to use, copy, modify and distribute this software and its *
+* documentation strictly for non-commercial purposes is hereby granted *
+* without fee, provided that the above copyright notice appears in all *
+* copies and that both the copyright notice and this permission notice *
+* appear in the supporting documentation. The authors make no claims *
+* about the suitability of this software for any purpose. It is *
+* provided "as is" without express or implied warranty. *
+**************************************************************************/
+
+// $Id$
+
+/// \class AliMUONSegment
+///
+/// A basic line segment, to be used in contour making algorithms.
+///
+/// In particular, this class defines what a left or right edge is.
+///
+/// Also, please note that, due to the way Root collections are sorted (relying
+/// on TObject::Compare method), the way the AliMUONSegment::Compare method
+/// is implemented below is really important when it comes to understand
+/// contour making algorithm. Keep that in mind.
+///
+/// \author Laurent Aphecetche, Subatech
+///
+
+#include "AliMUONSegment.h"
+
+#include "TMath.h"
+#include "Riostream.h"
+#include "AliMpConstants.h"
+
+using std::cout;
+using std::endl;
/// \cond CLASSIMP
-ClassImp(AliMUONSegment) // Class implementation in ROOT context
+ClassImp(AliMUONSegment)
/// \endcond
- //__________________________________________________________________________
-AliMUONSegment::AliMUONSegment()
- : TObject(),
- fHitForRecPtr1(0x0),
- fHitForRecPtr2(0x0),
- fBendingCoor(0.),
- fBendingSlope(0.),
- fBendingCoorReso2(0.),
- fBendingSlopeReso2(0.),
- fBendingCoorSlopeReso2(0.),
- fBendingImpact(0.),
- fNonBendingCoor(0.),
- fNonBendingSlope(0.),
- fNonBendingCoorReso2(0.),
- fNonBendingSlopeReso2(0.),
- fNonBendingCoorSlopeReso2(0.),
- fNonBendingImpact(0.),
- fZ(0.),
- fInTrack(kFALSE)
+const Double_t AliMUONSegment::fgkPrecision(AliMpConstants::LengthTolerance());
+
+//_____________________________________________________________________________
+AliMUONSegment::AliMUONSegment() :
+TObject(),
+fStartX(), fStartY(), fEndX(), fEndY(), fSmallerY(), fIsHorizontal(), fIsVertical(),
+fIsLeftEdge(), fIsRightEdge(), fIsAPoint(kTRUE)
{
- /// Default constructor
-
+ /// Ctor
+ Set(fStartX,fStartY,fEndX,fEndY);
}
- //__________________________________________________________________________
-AliMUONSegment::AliMUONSegment(AliMUONHitForRec* Hit1, AliMUONHitForRec* Hit2)
- : TObject(),
- fHitForRecPtr1(Hit1),
- fHitForRecPtr2(Hit2),
- fBendingCoor(Hit1->GetBendingCoor()),
- fBendingSlope(0.),
- fBendingCoorReso2(Hit1->GetBendingReso2()),
- fBendingSlopeReso2(0.),
- fBendingCoorSlopeReso2(0.),
- fBendingImpact(0.),
- fNonBendingCoor(Hit1->GetNonBendingCoor()),
- fNonBendingSlope(0.),
- fNonBendingCoorReso2(Hit1->GetNonBendingReso2()),
- fNonBendingSlopeReso2(0.),
- fNonBendingCoorSlopeReso2(0.),
- fNonBendingImpact(0.),
- fZ(Hit1->GetZ()),
- fInTrack(kFALSE)
+//_____________________________________________________________________________
+AliMUONSegment::AliMUONSegment(Double_t xstart, Double_t ystart, Double_t xend, Double_t yend)
+: TObject(),
+fStartX(xstart), fStartY(ystart), fEndX(xend), fEndY(yend), fSmallerY(), fIsHorizontal(), fIsVertical(),
+fIsLeftEdge(), fIsRightEdge(), fIsAPoint(kTRUE)
{
- /// Constructor for AliMUONSegment from two HitForRec's,
- /// one, in the first chamber of the station, pointed to by "Hit1",
- /// the other one, in the second chamber of the station, pointed to by "Hit1".
- /// Fills the pointers to both hits,
- /// the slope, the covariance for (coordinate in first chamber, slope),
- /// and the impact parameter at vertex (Z=0),
- /// in bending and non bending planes.
- /// Puts the "fInTrack" flag to "kFALSE".
-
- Double_t dz;
- dz = Hit1->GetZ() - Hit2->GetZ();
-
- // bending plane
- fBendingSlope = (fBendingCoor - Hit2->GetBendingCoor()) / dz;
- fBendingImpact = fBendingCoor - Hit1->GetZ() * fBendingSlope;
- fBendingSlopeReso2 = ( Hit1->GetBendingReso2() +
- Hit2->GetBendingReso2() ) / dz / dz;
- fBendingCoorSlopeReso2 = Hit1->GetBendingReso2() / dz;
- // non bending plane
- fNonBendingSlope = (fNonBendingCoor - Hit2->GetNonBendingCoor()) / dz;
- fNonBendingImpact = fNonBendingCoor - Hit1->GetZ() * fNonBendingSlope;
- fNonBendingSlopeReso2 = ( Hit1->GetNonBendingReso2() +
- Hit2->GetNonBendingReso2() ) / dz / dz;
- fNonBendingCoorSlopeReso2 = Hit1->GetNonBendingReso2() / dz;
- return;
+ /// Ctor
+ Set(xstart,ystart,xend,yend);
}
- //__________________________________________________________________________
-Int_t AliMUONSegment::Compare(const TObject* Segment) const
+//_____________________________________________________________________________
+Bool_t
+AliMUONSegment::AreEqual(double a, double b)
{
- /// "Compare" function to sort with increasing absolute value
- /// of the "impact parameter" in bending plane.
- /// Returns -1 (0, +1) if |impact parameter| of current Segment
- /// is smaller than (equal to, larger than) |impact parameter| of Segment
-
- if (TMath::Abs(((AliMUONSegment*)this)->fBendingImpact)
- < TMath::Abs(((AliMUONSegment*)Segment)->fBendingImpact))
- return(-1);
- // continuous parameter, hence no need for testing equal case
- else return(+1);
+ /// Whether the two floats are equal within the given precision
+ return (TMath::Abs(b-a) < fgkPrecision);
}
- //__________________________________________________________________________
-Double_t AliMUONSegment::NormalizedChi2WithSegment(AliMUONSegment* Segment, Double_t Sigma2Cut) const
+//_____________________________________________________________________________
+Int_t
+AliMUONSegment::Compare(const TObject* obj) const
{
- /// Calculate the normalized Chi2 between the current Segment (this)
- /// and the Segment pointed to by "Segment",
- /// i.e. the square deviations between the coordinates and the slopes,
- /// in both the bending and the non bending plane,
- /// divided by the variance of the same quantities and by "Sigma2Cut".
- /// Returns 5 if none of the 4 quantities is OK,
- /// something smaller than or equal to 4 otherwise.
- /// Would it be more correct to use a real chi square
- /// including the non diagonal term ????
-
- Double_t chi2, chi2Max, diff, normDiff;
- chi2 = 0.0;
- chi2Max = 5.0;
- // coordinate in bending plane
- diff = this->fBendingCoor - Segment->fBendingCoor;
- normDiff = diff * diff /
- (this->fBendingCoorReso2 + Segment->fBendingCoorReso2) / Sigma2Cut;
- if (normDiff > 1.0) return chi2Max;
- chi2 = chi2 + normDiff;
- // slope in bending plane
- diff = this->fBendingSlope - Segment->fBendingSlope;
- normDiff = diff * diff /
- (this->fBendingSlopeReso2 + Segment->fBendingSlopeReso2) / Sigma2Cut;
- if (normDiff > 1.0) return chi2Max;
- chi2 = chi2 + normDiff;
- // coordinate in non bending plane
- diff = this->fNonBendingCoor - Segment->fNonBendingCoor;
- normDiff = diff * diff /
- (this->fNonBendingCoorReso2 + Segment->fNonBendingCoorReso2) / Sigma2Cut;
- if (normDiff > 1.0) return chi2Max;
- chi2 = chi2 + normDiff;
- // slope in non bending plane
- diff = this->fNonBendingSlope - Segment->fNonBendingSlope;
- normDiff = diff * diff /
- (this->fNonBendingSlopeReso2 + Segment->fNonBendingSlopeReso2) / Sigma2Cut;
- if (normDiff > 1.0) return chi2Max;
- chi2 = chi2 + normDiff;
- return chi2;
+ /// Compare method, which sort segments in ascending x order
+ /// if same x, insure that left edges are before right edges
+ /// within same x, order by increasing bottommost y
+ /// Mind your steps ! This method is critical to the contour merging algorithm !
+
+ const AliMUONSegment* rhs = static_cast<const AliMUONSegment*>(obj);
+
+ if ( AreEqual(StartX(),rhs->StartX()) )
+ {
+ if ( IsLeftEdge() && rhs->IsRightEdge() ) return -1;
+ if ( IsRightEdge() && rhs->IsLeftEdge() ) return 1;
+ if ( SmallerY() < rhs->SmallerY() ) return -1;
+ if ( SmallerY() > rhs->SmallerY() ) return 1;
+ return 0;
+ }
+ else if ( StartX() < rhs->StartX() )
+ {
+ return -1;
+ }
+ else //if ( StartX() > rhs->StartX() )
+ {
+ return 1;
+ }
}
- //__________________________________________________________________________
-AliMUONSegment* AliMUONSegment::CreateSegmentFromLinearExtrapToStation ( Double_t z, Double_t MCSfactor) const
+//_____________________________________________________________________________
+double AliMUONSegment::Top() const
{
- /// Extrapolates linearly the current Segment (this) to station (0..) "Station".
- /// Multiple Coulomb scattering calculated from "MCSfactor"
- /// corresponding to one chamber,
- /// with one chamber for the coordinate, two chambers for the angle,
- /// due to the arrangement in stations.
- /// Valid from station(1..) 4 to 5 or vice versa.
- /// Returns the pointer to the created AliMUONSegment object
- /// corresponding to this extrapolation.
- /// The caller has the responsibility to delete this object.
-
- AliMUONSegment* extrapSegment = new AliMUONSegment(); // creates empty new segment
- // dZ from first hit of current Segment to first chamber of station "Station"
- Double_t dZ = z - this->GetZ();
- // Data in bending plane
- extrapSegment->fZ = z;
- // coordinate
- extrapSegment->fBendingCoor = this->fBendingCoor + this->fBendingSlope * dZ;
- // slope
- extrapSegment->fBendingSlope = this->fBendingSlope;
- // covariance, including multiple Coulomb scattering over dZ due to one chamber
- extrapSegment->fBendingCoorReso2 = this->fBendingCoorReso2 +
- (this->fBendingSlopeReso2 + MCSfactor) * dZ * dZ; // missing non diagonal term: "2.0 * this->fBendingCoorSlopeReso2 * dZ" !!!!
- extrapSegment->fBendingSlopeReso2 = this->fBendingSlopeReso2 + 2.0 * MCSfactor;
- extrapSegment->fBendingCoorSlopeReso2 =
- this->fBendingCoorSlopeReso2 + this->fBendingSlopeReso2 * dZ; // missing: contribution from multiple Coulomb scattering !!!!
- // Data in non bending plane
- // coordinate
- extrapSegment->fNonBendingCoor =
- this->fNonBendingCoor + this->fNonBendingSlope * dZ;
- // slope
- extrapSegment->fNonBendingSlope = this->fNonBendingSlope;
- // covariance, including multiple Coulomb scattering over dZ due to one chamber
- extrapSegment->fNonBendingCoorReso2 = this->fNonBendingCoorReso2 +
- (this->fNonBendingSlopeReso2 + MCSfactor) *dZ * dZ; // missing non diagonal term: "2.0 * this->fNonBendingCoorSlopeReso2 * dZ" !!!!
- extrapSegment->fNonBendingSlopeReso2 =
- this->fNonBendingSlopeReso2 + 2.0 * MCSfactor;
- extrapSegment->fNonBendingCoorSlopeReso2 =
- this->fNonBendingCoorSlopeReso2 + this->fNonBendingSlopeReso2 * dZ; // missing: contribution from multiple Coulomb scattering !!!!
- return extrapSegment;
+ /// Max Y of the segment
+ return TMath::Max(fStartY,fEndY);
}
- //__________________________________________________________________________
-AliMUONHitForRec* AliMUONSegment::CreateHitForRecFromLinearExtrapToChamber ( Double_t z, Double_t MCSfactor) const
+//_____________________________________________________________________________
+double AliMUONSegment::Distance() const
{
- /// Extrapolates linearly the current Segment (this) to chamber(0..) "Chamber".
- /// Multiple Coulomb scattering calculated from "MCSfactor"
- /// corresponding to one chamber.
- /// Valid from station(1..) 4 to 5 or vice versa.
- /// Returns the pointer to the created AliMUONHitForRec object
- /// corresponding to this extrapolation.
- /// The caller has the responsibility to delete this object.
-
- AliMUONHitForRec* extrapHitForRec = new AliMUONHitForRec(); // creates empty new HitForRec
- // dZ from first hit of current Segment to chamber
- Double_t dZ = z - this->GetZ();
- // Data in bending plane
- extrapHitForRec->SetZ(z);
- // coordinate
- extrapHitForRec->SetBendingCoor(this->fBendingCoor + this->fBendingSlope * dZ);
- // covariance, including multiple Coulomb scattering over dZ due to one chamber
- extrapHitForRec->SetBendingReso2(this->fBendingCoorReso2 +
- (this->fBendingSlopeReso2 + MCSfactor) * dZ * dZ); // missing non diagonal term: "2.0 * this->fBendingCoorSlopeReso2 * dZ" !!!!
- // Data in non bending plane
- // coordinate
- extrapHitForRec ->SetNonBendingCoor(this->fNonBendingCoor +
- this->fNonBendingSlope * dZ);
- // covariance, including multiple Coulomb scattering over dZ due to one chamber
- extrapHitForRec->
- SetNonBendingReso2(this->fNonBendingCoorReso2 +
- (this->fNonBendingSlopeReso2 + MCSfactor) * dZ * dZ); // missing non diagonal term: "2.0 * this->fNonBendingCoorSlopeReso2 * dZ" !!!!
- return extrapHitForRec;
+ /// Length of the segment
+ return TMath::Sqrt((fStartX-fEndX)*(fStartX-fEndX) +
+ (fStartY-fEndY)*(fStartY-fEndY));
}
- //__________________________________________________________________________
-void AliMUONSegment::UpdateFromStationTrackParam(AliMUONTrackParam *TrackParam, Double_t /*MCSfactor*/, Double_t /*Dz1*/, Double_t /*Dz2*/, Double_t /*Dz3*/, Int_t Station, Double_t InverseMomentum)
+//_____________________________________________________________________________
+void AliMUONSegment::Print(Option_t*) const
{
- /// Fill data members with values calculated from the array of track parameters
- /// pointed to by "TrackParam" (index = 0 and 1 for first and second chambers
- /// of the station, respectively).
- /// Multiple Coulomb scattering is taking into account with "MCSfactor"
- /// corresponding to one chamber,
- /// with one chamber for the coordinate, two chambers for the angle,
- /// due to the arrangement in stations.
- /// Resolution coming from:
- /// coordinate in closest station at "Dz1" from current "Station",
- /// slope between closest stations, with "Dz2" interval between them,
- /// interval "Dz3" between chambers of closest station,
- /// extrapolation over "Dz1" from closest station,
- /// "InverseMomentum".
- /// When called, "fBendingCoorReso2" and "fNonBendingCoorReso2"
- /// are assumed to be filled
- /// with the variance on bending and non bending coordinates.
- /// The "road" is parametrized from the old reco_muon.F
- /// with 8 cm between stations.
-
- AliMUONTrackParam *param0;
-// Double_t cReso2, sReso2;
- // parameters to define the widths of the searching roads in station 0,1,2
- // width = p0 + p1/ (momentum)^2
- // station number: 0 1 2
-// static Double_t p0BendingCoor[3] = { 6.43e-2, 1.64e-2, 0.034 };
-// static Double_t p1BendingCoor[3] = { 986., 821., 446. };
-// static Double_t p0BendingSlope[3] = { 3.54e-6, 3.63e-6, 3.6e-6 };
-// static Double_t p1BendingSlope[3] = { 4.49e-3, 4.8e-3, 0.011 };
-// static Double_t p0NonBendingCoor[3] = { 4.66e-2, 4.83e-2, 0.049 };
-// static Double_t p1NonBendingCoor[3] = { 1444., 866., 354. };
-// static Double_t p0NonBendingSlope[3] = { 6.14e-4, 6.49e-4, 6.85e-4 };
-// static Double_t p1NonBendingSlope[3] = { 0., 0., 0. };
-
- static Double_t p0BendingCoor[3] = { 6.43e-2, 6.43e-2, 6.43e-2 };
- static Double_t p1BendingCoor[3] = { 986., 986., 986. };
- static Double_t p0BendingSlope[3] = { 3.6e-6, 3.6e-6, 3.6e-6 };
- static Double_t p1BendingSlope[3] = { 1.1e-2, 1.1e-2, 1.1e-2 };
- static Double_t p0NonBendingCoor[3] = { 0.049, 0.049, 0.049 };
- static Double_t p1NonBendingCoor[3] = { 1444., 1444., 1444. };
- static Double_t p0NonBendingSlope[3] = { 6.8e-4, 6.8e-4, 6.8e-4 };
- static Double_t p1NonBendingSlope[3] = { 0., 0., 0. };
- param0 = &(TrackParam[0]);
-
-// OLD version
-// // Bending plane
-// fBendingCoor = param0->GetBendingCoor(); // coordinate
-// fBendingSlope = param0->GetBendingSlope(); // slope
-// cReso2 = fBendingCoorReso2;
-// sReso2 = 2.0 * cReso2 / Dz2 / Dz2;
-// fBendingCoorReso2 = cReso2 + (sReso2 + MCSfactor) * Dz1 * Dz1;
-// fBendingSlopeReso2 = sReso2 + 2.0 * MCSfactor;
-// // Non bending plane
-// fNonBendingCoor = param0->GetNonBendingCoor(); // coordinate
-// fNonBendingSlope = param0->GetNonBendingSlope(); // slope
-// cReso2 = fNonBendingCoorReso2;
-// sReso2 = 2.0 * cReso2 / Dz2 / Dz2;
-// fNonBendingCoorReso2 = cReso2 + (sReso2 + MCSfactor) * Dz1 * Dz1;
-// fNonBendingSlopeReso2 = sReso2 + 2.0 * MCSfactor;
-
- // Coordinate and slope
- // Bending plane
- fBendingCoor = param0->GetBendingCoor(); // coordinate
- fBendingSlope = param0->GetBendingSlope(); // slope
- // Non bending plane
- fNonBendingCoor = param0->GetNonBendingCoor(); // coordinate
- fNonBendingSlope = param0->GetNonBendingSlope(); // slope
-
- fZ = param0->GetZ(); // z
-
- // Resolutions
- // cReso2 and sReso2 have to be subtracted here from the parametrization
- // because they are added in the functions "NormalizedChi2WithSegment"
- // and "NormalizedChi2WithHitForRec"
- // Bending plane
-// cReso2 = fBendingCoorReso2;
-// sReso2 = (2. * cReso2 )/ (Dz3*Dz3) ;
- fBendingCoorReso2 = p0BendingCoor[Station] + p1BendingCoor[Station]*InverseMomentum*InverseMomentum ; // - cReso2
- fBendingSlopeReso2 = p0BendingSlope[Station] + p1BendingSlope[Station]*InverseMomentum*InverseMomentum; // - sReso2;
- // Non bending plane
-// cReso2 = fNonBendingCoorReso2;
-// sReso2 = (2. * cReso2 )/ (Dz3*Dz3) ;
- fNonBendingCoorReso2 = p0NonBendingCoor[Station] + p1NonBendingCoor[Station]*InverseMomentum*InverseMomentum; // - cReso2;
- fNonBendingSlopeReso2 = p0NonBendingSlope[Station] + p1NonBendingSlope[Station]*InverseMomentum*InverseMomentum; // - sReso2;
- return;
+ /// Printout
+ cout << AsString() << endl;
}
-// OLD function, with roads automatically calculated instead from being parametrized
-// kept because it would be a better solution,
-// if one can really find the right values.
-// //__________________________________________________________________________
-// void AliMUONSegment::UpdateFromStationTrackParam(AliMUONTrackParam *TrackParam, Double_t MCSfactor, Double_t Dz1, Double_t Dz2)
-// {
-// // Fill data members with values calculated from the array of track parameters
-// // pointed to by "TrackParam" (index = 0 and 1 for first and second chambers
-// // of the station, respectively).
-// // Multiple Coulomb scattering is taking into account with "MCSfactor"
-// // corresponding to one chamber,
-// // with one chamber for the coordinate, two chambers for the angle,
-// // due to the arrangement in stations.
-// // Resolution coming from:
-// // coordinate in closest station at "Dz1",
-// // slope between closest stations, with "Dz2" interval between them,
-// // extrapolation over "Dz" from closest station.
-// // When called, "fBendingCoorReso2" and "fNonBendingCoorReso2"
-// // are assumed to be filled
-// // with the variance on bending and non bending coordinates.
-// AliMUONTrackParam *param0;
-// Double_t cReso2, sReso2;
-// param0 = &(TrackParam[0]);
-// // Bending plane
-// fBendingCoor = param0->GetBendingCoor(); // coordinate
-// fBendingSlope = param0->GetBendingSlope(); // slope
-// cReso2 = fBendingCoorReso2;
-// sReso2 = 2.0 * cReso2 / Dz2 / Dz2;
-// fBendingCoorReso2 = cReso2 + (sReso2 + MCSfactor) * Dz1 * Dz1;
-// fBendingSlopeReso2 = sReso2 + 2.0 * MCSfactor;
-// // Non bending plane
-// fNonBendingCoor = param0->GetNonBendingCoor(); // coordinate
-// fNonBendingSlope = param0->GetNonBendingSlope(); // slope
-// cReso2 = fNonBendingCoorReso2;
-// sReso2 = 2.0 * cReso2 / Dz2 / Dz2;
-// fNonBendingCoorReso2 = cReso2 + (sReso2 + MCSfactor) * Dz1 * Dz1;
-// fNonBendingSlopeReso2 = sReso2 + 2.0 * MCSfactor;
-// return;
-// }
-
//_____________________________________________________________________________
-void
-AliMUONSegment::Print(Option_t*) const
+const char* AliMUONSegment::AsString() const
{
- /// Printing
+ /// Return a string representation of this object
+ return Form("[ (%10.5f,%10.5f) -> (%10.5f,%10.5f) %s ] (d=%e)",fStartX,fStartY,fEndX,fEndY,
+ IsLeftEdge() ? "L" : ( IsRightEdge() ? "R" : ( IsHorizontal() ? "H" : "" )),
+ Distance() );
+}
- cout.precision(5);
- cout.width(5);
-
- cout << "<AliMUONSegment>"
- << "(Coor,Slope,Impact)Bending=("
- << fBendingCoor << "," << fBendingSlope << "," << fBendingImpact
- << ")" << endl
- << "(Coor,Slope,Impact)NonBending=("
- << fNonBendingCoor << "," << fNonBendingSlope << "," << fNonBendingImpact
- << ")" << endl
- << "Cov (coor,slope,coor & slope)Bending=("
- << fBendingCoorReso2 << "," << fBendingSlopeReso2 << "," << fBendingCoorSlopeReso2 << endl
- << "Cov (coor,slope,coor & slope)NonBending=("
- << fNonBendingCoorReso2 << "," << fNonBendingSlopeReso2 << "," << fNonBendingCoorSlopeReso2 << endl;
- if ( fHitForRecPtr1 )
- {
- cout << "HitForRec1=";
- fHitForRecPtr1->Print();
- }
- if ( fHitForRecPtr2 )
- {
- cout << "HitForRec2=";
- fHitForRecPtr2->Print();
- }
+//_____________________________________________________________________________
+void
+AliMUONSegment::Set(Double_t xstart, Double_t ystart, Double_t xend, Double_t yend)
+{
+ /// Set start and end point, and (re)compute internal values
+ fStartX = xstart;
+ fEndX = xend;
+ fStartY = ystart;
+ fEndY = yend;
+ fSmallerY = TMath::Min(fStartY,fEndY);
+ fIsHorizontal = AreEqual(fStartY,fEndY);
+ fIsVertical = AreEqual(fStartX,fEndX);
+ fIsLeftEdge = fIsVertical && ( fStartY > fEndY );
+ fIsRightEdge = fIsVertical && ( fStartY < fEndY );
+ fIsAPoint = ( Distance() < fgkPrecision );
}
+