**************************************************************************/
/* $Id$ */
-
-//////////////////////////////////////////////////////////////////////////////////
-// //
-// An AliTRDalignment object contains the alignment data (3 shifts and 3 tilts) //
-// for all the alignable volumes of the TRD, i.e. for 18 supermodules and 540 //
-// chambers. The class provides simple tools for reading and writing these data //
-// in different formats, and for generating fake data that can be used to //
-// simulate misalignment. //
-// The six alignment variables have the following meaning: //
-// shift in rphi //
-// shift in z //
-// shift in r //
-// tilt around rphi //
-// tilt around z //
-// tilt around r //
-// The shifts are in cm and the tilts are in degrees. //
-// The currently supported formats are: //
-// - ascii //
-// - root file containing a TClonesArray of alignment objects //
-// - offline conditions database //
-// - OCDB-like root file //
-// - geometry file (like misaligned_geometry.root) //
-// //
-// D.Miskowiec, November 2006 //
-// //
-//////////////////////////////////////////////////////////////////////////////////
-
+///////////////////////////////////////////////////////////////////////////////
+// //
+// An AliTRDalignment object contains the alignment data (3 shifts and 3 //
+// tilts) for all the alignable volumes of the TRD, i.e. for 18 supermodules //
+// and 540 chambers. The class provides simple tools for reading and writing //
+// these data in different formats, and for generating fake data that can be //
+// used to simulate misalignment. //
+// The six alignment variables have the following meaning: //
+// shift in rphi //
+// shift in z //
+// shift in r //
+// tilt around rphi //
+// tilt around z //
+// tilt around r //
+// The shifts are in cm and the tilts are in degrees. //
+// The currently supported formats are: //
+// - ascii //
+// - root file containing a TClonesArray of alignment objects //
+// - offline conditions database //
+// - OCDB-like root file //
+// - geometry file (like misaligned_geometry.root) //
+// //
+// Some examples of usage (in an aliroot session): //
+// AliTRDalignment a,b,c,d,e; //
+// double xsm[]={0,0,0,-70,0,0}; //
+// double xch[]={0,0,-50,0,0,0}; //
+// a.SetSm(4,xsm); //
+// a.SetCh(120,xch); //
+// a.WriteAscii("kuku.dat"); //
+// TGeoManager::Import("geometry.root"); a.WriteRoot("kuku.root"); //
+// TGeoManager::Import("geometry.root"); a.WriteDB("kukudb.root",0,0); //
+// TGeoManager::Import("geometry.root"); //
+// a.WriteDB("local://$ALICE_ROOT/OCDB", "TRD/Align/Data", 0,0); //
+// TGeoManager::Import("geometry.root"); a.WriteGeo("kukugeometry.root"); //
+// //
+// b.ReadAscii("kuku.dat"); //
+// TGeoManager::Import("geometry.root"); c.ReadRoot("kuku.root"); //
+// TGeoManager::Import("geometry.root"); d.ReadDB("kukudb.root"); //
+// TGeoManager::Import("kukugeometry.root"); e.ReadCurrentGeo(); //
+// //
+// e.PrintSm(4); //
+// e.PrintCh(120); //
+// a.PrintRMS(); //
+// b.PrintRMS(); //
+// e.PrintRMS(); //
+// //
+// //
+// D.Miskowiec, November 2006 //
+// //
+///////////////////////////////////////////////////////////////////////////////
+
+#include <iostream>
#include <fstream>
-#include <string>
#include "TMath.h"
#include "TFile.h"
#include "TGeoManager.h"
#include "TGeoPhysicalNode.h"
#include "TClonesArray.h"
+#include "TString.h"
+#include "TFitter.h"
+#include "TMinuit.h"
#include "AliLog.h"
#include "AliAlignObj.h"
-#include "AliAlignObjAngles.h"
+#include "AliAlignObjParams.h"
#include "AliCDBManager.h"
#include "AliCDBStorage.h"
#include "AliCDBMetaData.h"
#include "AliCDBEntry.h"
-#include "AliCDBId.h"
+#include "AliSurveyObj.h"
+#include "AliSurveyPoint.h"
#include "AliTRDalignment.h"
+void trdAlignmentFcn(Int_t &npar, Double_t *gin, Double_t &f, Double_t *x, Int_t iflag);
+
ClassImp(AliTRDalignment)
//_____________________________________________________________________________
AliTRDalignment::AliTRDalignment()
:TObject()
+ ,fComment()
,fRan(0)
{
//
SetZero();
+ for (int i=0; i<18; i++) for (int j=0; j<2; j++) for (int k=0; k<2; k++) for (int l=0; l<2; l++) {
+ fSurveyX[i][j][k][l] = 0.0;
+ fSurveyY[i][j][k][l] = 0.0;
+ fSurveyZ[i][j][k][l] = 0.0;
+ fSurveyEX[i][j][k][l] = 0.0;
+ fSurveyEY[i][j][k][l] = 0.0;
+ fSurveyEZ[i][j][k][l] = 0.0;
+ }
+
+ // Initialize the nominal positions of the survey points
+ // in the local frame of supermodule (where y is the long side,
+ // z corresponds to the radius in lab, and x to the phi in lab).
+ // Four survey marks are on each z-side of the supermodule.
+ // A B
+ // ----o-----------o---- x |
+ // \ / |
+ // \ / |
+ // \ / |
+ // \ / |
+ // ---o-----o--- -------------->
+ // C D y
+ //
+ // For the purpose of this explanation lets define the origin such that
+ // the supermodule occupies 0 < x < 77.9 cm. Then the coordinates (x,y)
+ // are (in cm)
+ // A (76.2,-30.25)
+ // B (76.2,+30.25)
+ // C ( 2.2,-22.5 )
+ // D ( 2.2,+22.5 )
+ //
+
+ double x[2] = {22.5,30.25}; // lab phi, or tracking-y
+ double y[2] = {353.0, -353.0}; // lab z; inc. 2 cm survey target offset
+ double z[2] = {-(77.9/2.0-2.0),77.9/2.0-1.5}; // lab r, or better tracking-x
+
+ for (int j=0; j<2; j++) for (int k=0; k<2; k++) for (int l=0; l<2; l++) {
+ fSurveyX0[j][k][l] = -TMath::Power(-1,l) * x[k];
+ fSurveyY0[j][k][l] = y[j];
+ fSurveyZ0[j][k][l] = z[k];
+ }
+
}
//_____________________________________________________________________________
AliTRDalignment::AliTRDalignment(const AliTRDalignment& source)
:TObject(source)
- ,fRan(source.fRan)
+ ,fComment(source.fComment)
+ ,fRan(source.fRan)
{
//
// copy constructor
//
- for (int i = 0; i < 18; i++) {
- SetSm(i,source.fSm[i]);
+ for (int i=0; i<18; i++) SetSm(i,source.fSm[i]);
+ for (int i=0; i<540; i++) SetCh(i,source.fCh[i]);
+ for (int i=0; i<18; i++) for (int j=0; j<2; j++) for (int k=0; k<2; k++) for (int l=0; l<2; l++) {
+ fSurveyX[i][j][k][l] = source.fSurveyX[i][j][k][l];
+ fSurveyY[i][j][k][l] = source.fSurveyY[i][j][k][l];
+ fSurveyZ[i][j][k][l] = source.fSurveyZ[i][j][k][l];
+ fSurveyEX[i][j][k][l] = source.fSurveyEX[i][j][k][l];
+ fSurveyEY[i][j][k][l] = source.fSurveyEY[i][j][k][l];
+ fSurveyEZ[i][j][k][l] = source.fSurveyEZ[i][j][k][l];
}
- for (int i = 0; i < 540; i++) {
- SetCh(i,source.fCh[i]);
+ for (int j=0; j<2; j++) for (int k=0; k<2; k++) for (int l=0; l<2; l++) {
+ fSurveyX0[j][k][l] = source.fSurveyX0[j][k][l];
+ fSurveyY0[j][k][l] = source.fSurveyY0[j][k][l];
+ fSurveyZ0[j][k][l] = source.fSurveyZ0[j][k][l];
}
}
if (this != &source) {
for (int i = 0; i < 18; i++) SetSm(i,source.fSm[i]);
for (int i = 0; i < 540; i++) SetCh(i,source.fCh[i]);
+ for (int i=0; i<18; i++) for (int j=0; j<2; j++) for (int k=0; k<2; k++) for (int l=0; l<2; l++) {
+ fSurveyX[i][j][k][l] = source.fSurveyX[i][j][k][l];
+ fSurveyY[i][j][k][l] = source.fSurveyY[i][j][k][l];
+ fSurveyZ[i][j][k][l] = source.fSurveyZ[i][j][k][l];
+ fSurveyEX[i][j][k][l] = source.fSurveyEX[i][j][k][l];
+ fSurveyEY[i][j][k][l] = source.fSurveyEY[i][j][k][l];
+ fSurveyEZ[i][j][k][l] = source.fSurveyEZ[i][j][k][l];
+ }
+ for (int j=0; j<2; j++) for (int k=0; k<2; k++) for (int l=0; l<2; l++) {
+ fSurveyX0[j][k][l] = source.fSurveyX0[j][k][l];
+ fSurveyY0[j][k][l] = source.fSurveyY0[j][k][l];
+ fSurveyZ0[j][k][l] = source.fSurveyZ0[j][k][l];
+ }
+ fComment = source.fComment;
}
return *this;
}
+//_____________________________________________________________________________
+AliTRDalignment& AliTRDalignment::operator*=(double fac)
+{
+ //
+ // multiplication operator
+ //
+
+ for (int i = 0; i < 18; i++) for (int j = 0; j < 6; j++) this->fSm[i][j] *= fac;
+ for (int i = 0; i < 540; i++) for (int j = 0; j < 6; j++) this->fCh[i][j] *= fac;
+
+ return *this;
+
+}
+
//_____________________________________________________________________________
AliTRDalignment& AliTRDalignment::operator+=(const AliTRDalignment &source)
{
// addition operator
//
- for (int i = 0; i < 18; i++) {
- for (int j = 0; j < 6; j++) {
- this->fSm[i][j] =+ source.fSm[i][j];
- }
- }
- for (int i = 0; i < 540; i++) {
- for (int j = 0; j < 6; j++) {
- this->fCh[i][j] =+ source.fCh[i][j];
- }
- }
+ for (int i = 0; i < 18; i++) for (int j = 0; j < 6; j++) this->fSm[i][j] += source.fSm[i][j];
+ for (int i = 0; i < 540; i++) for (int j = 0; j < 6; j++) this->fCh[i][j] += source.fCh[i][j];
return *this;
// subtraction operator
//
- for (int i = 0; i < 18; i++) {
- for (int j = 0; j < 6; j++) {
- fSm[i][j] -= source.fSm[i][j];
- }
- }
- for (int i = 0; i < 540; i++) {
- for (int j = 0; j < 6; j++) {
- fCh[i][j] -= source.fCh[i][j];
- }
- }
+ for (int i = 0; i < 18; i++) for (int j = 0; j < 6; j++) fSm[i][j] -= source.fSm[i][j];
+ for (int i = 0; i < 540; i++) for (int j = 0; j < 6; j++) fCh[i][j] -= source.fCh[i][j];
return *this;
Bool_t areEqual = 1;
- for (int i = 0; i < 18; i++) {
- for (int j = 0; j < 6; j++) {
- areEqual &= (fSm[i][j] == source.fSm[i][j]);
- }
- }
- for (int i = 0; i < 540; i++) {
- for (int j = 0; j < 6; j++) {
- areEqual &= (fCh[i][j] == source.fCh[i][j]);
- }
- }
+ for (int i = 0; i < 18; i++) for (int j = 0; j < 6; j++) areEqual &= (fSm[i][j] == source.fSm[i][j]);
+ for (int i = 0; i < 540; i++) for (int j = 0; j < 6; j++) areEqual &= (fCh[i][j] == source.fCh[i][j]);
return areEqual;
}
//_____________________________________________________________________________
-void AliTRDalignment::SetSmRandom(Double_t a[6])
+void AliTRDalignment::SetSmRandom(double a[6])
{
//
// generate random gaussian supermodule data with sigmas a
//
double x[6];
+ double xmax[6]={999, 0.6, 999, 999, 999, 999};
- for (Int_t i = 0; i < 18; i++) {
- fRan.Rannor(x[0],x[1]);
- fRan.Rannor(x[2],x[3]);
- fRan.Rannor(x[4],x[5]);
- for (Int_t j = 0; j < 6; j++) {
- x[j] *= a[j];
+ for (int i = 0; i < 18; i++) {
+ for (int j = 0; j < 6; j++) {
+ do {x[j] = fRan.Gaus(0,a[j]);} while (TMath::Abs(x[j]) > xmax[j]);
}
SetSm(i,x);
//PrintSm(i);
}
//_____________________________________________________________________________
-void AliTRDalignment::SetChRandom(Double_t a[6])
+void AliTRDalignment::SetChRandom(double a[6])
{
//
// generate random gaussian chamber data with sigmas a
double x[6];
- for (Int_t i = 0; i < 540; i++) {
+ for (int i = 0; i < 540; i++) {
fRan.Rannor(x[0],x[1]);
fRan.Rannor(x[2],x[3]);
fRan.Rannor(x[4],x[5]);
- for (Int_t j = 0; j < 6; j++) {
- x[j] *= a[j];
- }
+ for (int j = 0; j < 6; j++) x[j] *= a[j];
SetCh(i,x);
//PrintCh(i);
}
// expected from the mechanical precision
//
- Double_t a[6];
+ double a[6];
a[0] = 0.3; // phi
a[1] = 0.3; // z
// expected from the mechanical precision
//
- Double_t a[6];
+ double a[6];
a[0] = 0.1; // phi
a[1] = 0.1; // z
// remaining after full calibration
//
- Double_t a[6];
+ double a[6];
a[0] = 0.002; // phi
a[1] = 0.003; // z
}
//_____________________________________________________________________________
-void AliTRDalignment::PrintSm(Int_t i, FILE *fp) const
+void AliTRDalignment::PrintSm(int i, FILE * const fp) const
{
//
// print the supermodule data
}
//_____________________________________________________________________________
-void AliTRDalignment::PrintCh(Int_t i, FILE *fp) const
+void AliTRDalignment::PrintCh(int i, FILE * const fp) const
{
//
// print the chamber data
}
//_____________________________________________________________________________
-void AliTRDalignment::ReadAscii(char *filename)
+void AliTRDalignment::ReadAscii(const char * const filename)
{
//
// read the alignment data from ascii file
fstream fi(filename,fstream::in);
if (!fi) {
- AliFatal(Form("cannot open input file %s",filename));
+ AliError(Form("cannot open input file %s",filename));
+ return;
}
// supermodules
for (int i = 0; i < 18; i++) {
fi>>j>>x[0]>>x[1]>>x[2]>>x[3]>>x[4]>>x[5]>>volid>>syna;
- if (j != i) {
- AliError(Form("sm %d expected, %d found",i,j));
- }
- if (volid != 0) {
- AliError(Form("sm %d volume id %d expected, %d found",i,0,volid));
- }
+ if (j != i) AliError(Form("sm %d expected, %d found",i,j));
+ if (volid != 0) AliError(Form("sm %d volume id %d expected, %d found",i,0,volid));
std::string symnam = GetSmName(i);
- if (syna != symnam) {
- AliError(Form("sm %d name %s expected, %s found",i,symnam.data(),syna.data()));
- }
+ if (syna != symnam) AliError(Form("sm %d name %s expected, %s found",i,symnam.data(),syna.data()));
SetSm(i,x);
}
for (int i = 0; i < 540; i++) {
fi>>j>>x[0]>>x[1]>>x[2]>>x[3]>>x[4]>>x[5]>>volid>>syna;
- if (j != i) {
- AliError(Form("ch %d expected, %d found",i,j));
- }
- if (volid != GetVoi(i)) {
- AliError(Form("ch %d volume id %d expected, %d found",i,GetVoi(i),volid));
- }
+ if (j != i) AliError(Form("ch %d expected, %d found",i,j));
+ if (volid != GetVoi(i)) AliError(Form("ch %d volume id %d expected, %d found",i,GetVoi(i),volid));
std::string symnam = GetChName(i);
- if (syna != symnam) {
- AliError(Form("ch %d name %s expected, %s found",i,symnam.data(),syna.data()));
- }
+ if (syna != symnam) AliError(Form("ch %d name %s expected, %s found",i,symnam.data(),syna.data()));
SetCh(i,x);
}
}
//_____________________________________________________________________________
-void AliTRDalignment::ReadRoot(char *filename)
+void AliTRDalignment::ReadCurrentGeo()
+{
+ //
+ // use currently loaded geometry to determine misalignment by comparing
+ // original and misaligned matrix of the last node
+ // Now, original, does not mean "ideal". It is the matrix before the alignment.
+ // So, if alignment was applied more than once, the numbers extracted will
+ // represent just the last alignment. -- check this!
+ //
+
+ TGeoPNEntry *pne;
+ TGeoHMatrix *ideSm[18]; // ideal
+ TGeoHMatrix *misSm[18]; // misaligned
+ for (int i = 0; i < 18; i++) if ((pne = gGeoManager->GetAlignableEntry(GetSmName(i)))) {
+
+ // read misaligned and original matrices
+
+ TGeoPhysicalNode *node = pne->GetPhysicalNode();
+ if (!node) AliError(Form("physical node entry %s has no physical node",GetSmName(i)));
+ if (!node) continue;
+ misSm[i] = new TGeoHMatrix(*node->GetNode(node->GetLevel())->GetMatrix());
+ ideSm[i] = new TGeoHMatrix(*node->GetOriginalMatrix());
+
+ // calculate the local misalignment matrices as inverse misaligned times ideal
+
+ TGeoHMatrix mat(ideSm[i]->Inverse());
+ mat.Multiply(misSm[i]);
+ double *tra = mat.GetTranslation();
+ double *rot = mat.GetRotationMatrix();
+ double pars[6];
+ pars[0] = tra[0];
+ pars[1] = tra[1];
+ pars[2] = tra[2];
+ if (TMath::Abs(rot[0])<1e-7 || TMath::Abs(rot[8])<1e-7) AliError("Failed to extract roll-pitch-yall angles!");
+ double raddeg = TMath::RadToDeg();
+ pars[3] = raddeg * TMath::ATan2(-rot[5],rot[8]);
+ pars[4] = raddeg * TMath::ASin(rot[2]);
+ pars[5] = raddeg * TMath::ATan2(-rot[1],rot[0]);
+ SetSm(i,pars);
+
+ // cleanup
+
+ delete ideSm[i];
+ delete misSm[i];
+ }
+
+ TGeoHMatrix *ideCh[540]; // ideal
+ TGeoHMatrix *misCh[540]; // misaligned
+ for (int i = 0; i < 540; i++) if ((pne = gGeoManager->GetAlignableEntry(GetChName(i)))) {
+
+ // read misaligned and original matrices
+
+ TGeoPhysicalNode *node = pne->GetPhysicalNode();
+ if (!node) AliError(Form("physical node entry %s has no physical node",GetChName(i)));
+ if (!node) continue;
+ misCh[i] = new TGeoHMatrix(*node->GetNode(node->GetLevel())->GetMatrix());
+ ideCh[i] = new TGeoHMatrix(*node->GetOriginalMatrix());
+
+ // calculate the local misalignment matrices as inverse misaligned times ideal
+
+ TGeoHMatrix mat(ideCh[i]->Inverse());
+ mat.Multiply(misCh[i]);
+ double *tra = mat.GetTranslation();
+ double *rot = mat.GetRotationMatrix();
+ double pars[6];
+ pars[0] = tra[0];
+ pars[1] = tra[1];
+ pars[2] = tra[2];
+ if(TMath::Abs(rot[0])<1e-7 || TMath::Abs(rot[8])<1e-7) {
+ AliError("Failed to extract roll-pitch-yall angles!");
+ return;
+ }
+ double raddeg = TMath::RadToDeg();
+ pars[3] = raddeg * TMath::ATan2(-rot[5],rot[8]);
+ pars[4] = raddeg * TMath::ASin(rot[2]);
+ pars[5] = raddeg * TMath::ATan2(-rot[1],rot[0]);
+ SetCh(i,pars);
+
+ // cleanup
+ delete ideCh[i];
+ delete misCh[i];
+ }
+
+ return;
+
+}
+
+//_____________________________________________________________________________
+void AliTRDalignment::ReadRoot(const char * const filename)
{
//
// read the alignment data from root file
- // here I expect a fixed order and number of elements
- // it would be much better to identify the alignment objects
- // one by one and set the parameters of the corresponding sm or ch
//
TFile fi(filename,"READ");
ArToNumbers(ar);
fi.Close();
}
- else {
- AliError(Form("cannot open input file %s",filename));
- }
+ else AliError(Form("cannot open input file %s",filename));
return;
}
//_____________________________________________________________________________
-void AliTRDalignment::ReadDB(char *filename)
+void AliTRDalignment::ReadDB(const char * const filename)
{
//
// read the alignment data from database file
if (fi.IsOpen()) {
AliCDBEntry *e = (AliCDBEntry *) fi.Get("AliCDBEntry");
e->PrintMetaData();
+ fComment.SetString(e->GetMetaData()->GetComment());
TClonesArray *ar = (TClonesArray *) e->GetObject();
ArToNumbers(ar);
fi.Close();
}
- else {
- AliError(Form("cannot open input file %s",filename));
- }
+ else AliError(Form("cannot open input file %s",filename));
return;
}
//_____________________________________________________________________________
-void AliTRDalignment::ReadDB(char *db, char *path, Int_t run
- , Int_t version, Int_t subversion)
+void AliTRDalignment::ReadDB(const char * const db, const char * const path,
+ int run, int version, int subversion)
{
//
// read the alignment data from database
AliCDBManager *cdb = AliCDBManager::Instance();
AliCDBStorage *storLoc = cdb->GetStorage(db);
AliCDBEntry *e = storLoc->Get(path,run,version,subversion);
- e->PrintMetaData();
- TClonesArray *ar = (TClonesArray *) e->GetObject();
- ArToNumbers(ar);
+ if (e) {
+ e->PrintMetaData();
+ fComment.SetString(e->GetMetaData()->GetComment());
+ TClonesArray *ar = (TClonesArray *) e->GetObject();
+ ArToNumbers(ar);
+ }
+}
+
+//_____________________________________________________________________________
+Bool_t AliTRDalignment::DecodeSurveyPointName(TString pna, Int_t &sm, Int_t &iz,
+ Int_t &ir, Int_t &iphi) {
+ // decode the survey point name and extract the sm, z, r and phi indices
+
+ if (pna(0,6)!="TRD_sm") {
+ AliError(Form("unexpected point name: %s",pna.Data()));
+ return kFALSE;
+ }
+ sm = atoi(pna(6,2).Data()); // supermodule number
+ iz = -1;
+ if (pna(8) == 'a') iz=0; // anticlockwise, positive z
+ if (pna(8) == 'c') iz=1; // clockwise, negative z
+ ir = -1;
+ if (pna(9) == 'l') ir=0; // low radius
+ if (pna(9) == 'h') ir=1; // high radius
+ iphi = -1;
+ if (pna(10) == '0') iphi = 0; // low phi within supermodule
+ if (pna(10) == '1') iphi = 1; // high phi within supermodule
+ if (sm>=0 && sm<18 && iz>=0 && iz<2 && ir>=0 && ir<2 && iphi>=0 && iphi<2) return kTRUE;
+ AliError(Form("cannot decode point name: %s",pna.Data()));
+ return kFALSE;
+}
+
+//_____________________________________________________________________________
+void AliTRDalignment::ReadSurveyReport(const char * const filename)
+{
+ //
+ // Read survey report and store the numbers in fSurveyX, fSurveyY, fSurveyZ,
+ // and fSurveyE. Store the survey info in the fComment.
+ // Each supermodule has 8 survey points. The point names look like
+ // TRD_sm08ah0 and have the following meaning.
+ //
+ // sm00..17 mean supermodule 0 through 17, following the phi.
+ // Supermodule 00 is between phi=0 and phi=20 degrees.
+ //
+ // a or c denotes the anticlockwise and clockwise end of the supermodule
+ // in z. Clockwise end is where z is negative and where the muon arm sits.
+ //
+ // l or h denote low radius and high radius holes
+ //
+ // 0 or 1 denote the hole at smaller and at larger phi, respectively.
+ //
+
+ // read the survey file
+
+ fstream in(filename,fstream::in);
+ if (!in) {
+ AliError(Form("cannot open input file %s",filename));
+ return;
+ }
+
+ // loop through the lines of the file until the beginning of data
+
+ TString title,date,subdetector,url,version,observations,system,units;
+ while (1) {
+ char pee=in.peek();
+ if (pee==EOF) break;
+ TString line;
+ line.ReadLine(in);
+ if (line.Contains("Title:")) title.ReadLine(in);
+ if (line.Contains("Date:")) date.ReadLine(in);
+ if (line.Contains("Subdetector:")) subdetector.ReadLine(in);
+ if (line.Contains("URL:")) url.ReadLine(in);
+ if (line.Contains("Version:")) version.ReadLine(in);
+ if (line.Contains("Observations:")) observations.ReadLine(in);
+ if (line.Contains("System:")) system.ReadLine(in);
+ if (line.Contains("Units:")) units.ReadLine(in);
+ if (line.Contains("Data:")) break;
+ }
+
+ // check what we found so far (watch out, they have \r at the end)
+
+ std::cout<<"title .........."<<title<<std::endl;
+ std::cout<<"date ..........."<<date<<std::endl;
+ std::cout<<"subdetector ...."<<subdetector<<std::endl;
+ std::cout<<"url ............"<<url<<std::endl;
+ std::cout<<"version ........"<<version<<std::endl;
+ std::cout<<"observations ..."<<observations<<std::endl;
+ std::cout<<"system ........."<<system<<std::endl;
+ std::cout<<"units .........."<<units<<std::endl;
+
+ if (!subdetector.Contains("TRD")) {
+ AliWarning(Form("Not a TRD survey file, subdetector = %s",subdetector.Data()));
+ return;
+ }
+ double tocm = 0; // we want to have it in cm
+ if (units.Contains("mm")) tocm = 0.1;
+ else if (units.Contains("cm")) tocm = 1.0;
+ else if (units.Contains("m")) tocm = 100.0;
+ else if (units.Contains("pc")) tocm = 3.24078e-15;
+ else {
+ AliError(Form("unexpected units: %s",units.Data()));
+ return;
+ }
+ if (!system.Contains("ALICEPH")) {
+ AliError(Form("wrong system: %s, should be ALICEPH",system.Data()));
+ return;
+ }
+ // scan the rest of the file which should contain list of surveyed points
+ // for every point, decode the point name and store the numbers in the right
+ // place in the arrays fSurveyX etc.
+
+ while (1) {
+ TString pna; // point name
+ char type, target;
+ double x,y,z,precision;
+
+ in >> pna >> x >> y >> z >> type >> target >> precision;
+ if (in.fail()) break;
+ Int_t i,j,k,l;
+ if (DecodeSurveyPointName(pna,i,j,k,l)) {
+ fSurveyX[i][j][k][l] = tocm*x;
+ fSurveyY[i][j][k][l] = tocm*y;
+ fSurveyZ[i][j][k][l] = tocm*z;
+ fSurveyEX[i][j][k][l] = precision/10; // "precision" is supposed to be in mm
+ fSurveyEY[i][j][k][l] = precision/10; // "precision" is supposed to be in mm
+ fSurveyEZ[i][j][k][l] = precision/10; // "precision" is supposed to be in mm
+ // if, at some point, separate precision numbers for x,y,z show up in the
+ // survey reports the function will fail here
+ printf("decoded %s %02d %d %d %d %8.2f %8.2f %8.2f %6.2f %6.2f %6.2f\n",
+ pna.Data(), i, j, k, l,
+ fSurveyX[i][j][k][l], fSurveyY[i][j][k][l], fSurveyZ[i][j][k][l],
+ fSurveyEX[i][j][k][l], fSurveyEY[i][j][k][l], fSurveyEZ[i][j][k][l]);
+ } else AliError(Form("cannot decode point name: %s",pna.Data()));
+ }
+ in.close();
+ TString info = "Survey "+title+" "+date+" "+url+" "+version+" "+observations;
+ info.ReplaceAll("\r","");
+ fComment.SetString(info.Data());
+
}
//_____________________________________________________________________________
-void AliTRDalignment::ReadGeo(char *misaligned)
+void AliTRDalignment::ReadSurveyReport(const AliSurveyObj * const so)
{
//
- // determine misalignment by comparing original and misaligned matrix
- // of the last node on the misaligned_geometry file
- // an alternative longer way is in attic.C
+ // Read survey report and store the numbers in fSurveyX, fSurveyY, fSurveyZ,
+ // and fSurveyE. Store the survey info in the fComment.
+ // Each supermodule has 8 survey points. The point names look like
+ // TRD_sm08ah0 and have the following meaning.
+ //
+ // sm00..17 mean supermodule 0 through 17, following the phi.
+ // Supermodule 00 is between phi=0 and phi=20 degrees.
+ //
+ // a or c denotes the anticlockwise and clockwise end of the supermodule
+ // in z. Clockwise end is where z is negative and where the muon arm sits.
+ //
+ // l or h denote low radius and high radius holes
+ //
+ // 0 or 1 denote the hole at smaller and at larger phi, respectively.
//
- TGeoHMatrix *ideSm[18]; // ideal
- TGeoHMatrix *ideCh[540];
- TGeoHMatrix *misSm[18]; // misaligned
- TGeoHMatrix *misCh[540];
+ // read and process the data from the survey object
- // read misaligned and original matrices
+ Int_t size = so->GetEntries();
+ printf("-> %d\n", size);
- TGeoManager::Import(misaligned);
- for (int i = 0; i < 18; i++) {
- TGeoPNEntry *pne = gGeoManager->GetAlignableEntry(GetSmName(i));
- if (!pne) {
- AliError(Form("no such physical node entry: %s",GetSmName(i)));
- return;
- }
- TGeoPhysicalNode *node = pne->GetPhysicalNode();
- if (!node) {
- AliError(Form("physical node entry %s has no physical node",GetSmName(i)));
- return;
- }
- misSm[i] = new TGeoHMatrix(*node->GetNode(node->GetLevel())->GetMatrix());
- ideSm[i] = new TGeoHMatrix(*node->GetOriginalMatrix());
+ TString title = so->GetReportTitle();
+ TString date = so->GetReportDate();
+ TString subdetector = so->GetDetector();
+ TString url = so->GetURL();
+ TString report = so->GetReportNumber();
+ TString version = so->GetReportVersion();
+ TString observations = so->GetObservations();
+ TString system = so->GetCoordSys();
+ TString units = so->GetUnits();
+
+ // check what we found so far (watch out, they have \r at the end)
+
+ std::cout<<"title .........."<<title<<std::endl;
+ std::cout<<"date ..........."<<date<<std::endl;
+ std::cout<<"subdetector ...."<<subdetector<<std::endl;
+ std::cout<<"url ............"<<url<<std::endl;
+ std::cout<<"version ........"<<version<<std::endl;
+ std::cout<<"observations ..."<<observations<<std::endl;
+ std::cout<<"system ........."<<system<<std::endl;
+ std::cout<<"units .........."<<units<<std::endl;
+
+ if (!subdetector.Contains("TRD")) {
+ AliWarning(Form("Not a TRD survey file, subdetector = %s",subdetector.Data()));
+ return;
}
- for (int i = 0; i < 540; i++) {
- TGeoPNEntry *pne = gGeoManager->GetAlignableEntry(GetChName(i));
- if (!pne) {
- AliError(Form("no such physical node entry: %s",GetChName(i)));
- return;
- }
- TGeoPhysicalNode *node = pne->GetPhysicalNode();
- if (!node) {
- AliError(Form("physical node entry %s has no physical node",GetChName(i)));
- return;
- }
- misCh[i] = new TGeoHMatrix(*node->GetNode(node->GetLevel())->GetMatrix());
- ideCh[i] = new TGeoHMatrix(*node->GetOriginalMatrix());
+ double tocm = 0; // we want to have it in cm
+ if (units.Contains("mm")) tocm = 0.1;
+ else if (units.Contains("cm")) tocm = 1.0;
+ else if (units.Contains("m")) tocm = 100.0;
+ else if (units.Contains("pc")) tocm = 3.24078e-15;
+ else {
+ AliError(Form("unexpected units: %s",units.Data()));
+ return;
+ }
+ if (!system.Contains("ALICEPH")) {
+ AliError(Form("wrong system: %s, should be ALICEPH",system.Data()));
+ return;
}
- // calculate the local misalignment matrices as inverse misaligned times ideal
+ // for every survey point, decode the point name and store the numbers in
+ // the right place in the arrays fSurveyX etc.
+
+ TObjArray *points = so->GetData();
+ for (int ip = 0; ip<points->GetEntries(); ++ip) {
+ AliSurveyPoint *po = (AliSurveyPoint *) points->At(ip);
+ TString pna = po->GetPointName();
+ Int_t i,j,k,l;
+ if (DecodeSurveyPointName(pna,i,j,k,l)) {
+ fSurveyX[i][j][k][l] = tocm*po->GetX();
+ fSurveyY[i][j][k][l] = tocm*po->GetY();
+ fSurveyZ[i][j][k][l] = tocm*po->GetZ();
+ fSurveyEX[i][j][k][l] = po->GetPrecisionX()/10; // "precision" is supposed to be in mm
+ fSurveyEY[i][j][k][l] = po->GetPrecisionY()/10;
+ fSurveyEZ[i][j][k][l] = po->GetPrecisionZ()/10;
+ printf("decoded %s %02d %d %d %d %8.2f %8.2f %8.2f %6.2f %6.2f %6.2f\n",
+ pna.Data(), i, j, k, l,
+ fSurveyX[i][j][k][l], fSurveyY[i][j][k][l], fSurveyZ[i][j][k][l],
+ fSurveyEX[i][j][k][l], fSurveyEY[i][j][k][l], fSurveyEZ[i][j][k][l]);
+ } else AliError(Form("cannot decode point name: %s",pna.Data()));
+ }
- for (int i = 0; i < 18; i++) {
- TGeoHMatrix mat(ideSm[i]->Inverse());
- mat.Multiply(misSm[i]);
- double *tra = mat.GetTranslation();
- double *rot = mat.GetRotationMatrix();
- double pars[6];
- pars[0] = tra[0];
- pars[1] = tra[1];
- pars[2] = tra[2];
- if (TMath::Abs(rot[0])<1e-7 || TMath::Abs(rot[8])<1e-7) {
- AliError("Failed to extract roll-pitch-yall angles!");
- return;
- }
- double raddeg = TMath::RadToDeg();
- pars[3] = raddeg * TMath::ATan2(-rot[5],rot[8]);
- pars[4] = raddeg * TMath::ASin(rot[2]);
- pars[5] = raddeg * TMath::ATan2(-rot[1],rot[0]);
- SetSm(i,pars);
+ TString info = "Survey "+title+" "+date+" "+url+" "+report+" "+version+" "+observations;
+ info.ReplaceAll("\r","");
+ fComment.SetString(info.Data());
+}
+
+//_____________________________________________________________________________
+double AliTRDalignment::SurveyChi2(int i, const double * const a) {
+
+ //
+ // Compare the survey results to the ideal positions of the survey marks
+ // in the local frame of supermodule. When transforming, use the alignment
+ // parameters a[6]. Return chi-squared.
+ //
+
+ if (!IsGeoLoaded()) return 0;
+ printf("Survey of supermodule %d\n",i);
+ AliAlignObjParams al(GetSmName(i),0,a[0],a[1],a[2],a[3],a[4],a[5],0);
+
+ TGeoPNEntry *pne = gGeoManager->GetAlignableEntry(GetSmName(i));
+ if (!pne) AliError(Form("no such physical node entry: %s",GetSmName(i)));
+ TGeoPhysicalNode *node = pne->GetPhysicalNode();
+ if (!node) {
+ AliWarning(Form("physical node entry %s has no physical node; making a new one",GetSmName(i)));
+ node = gGeoManager->MakeAlignablePN(pne);
}
- for (int i = 0; i < 540; i++) {
- TGeoHMatrix mat(ideCh[i]->Inverse());
- mat.Multiply(misCh[i]);
- double *tra = mat.GetTranslation();
- double *rot = mat.GetRotationMatrix();
- double pars[6];
- pars[0] = tra[0];
- pars[1] = tra[1];
- pars[2] = tra[2];
- if(TMath::Abs(rot[0])<1e-7 || TMath::Abs(rot[8])<1e-7) {
- AliError("Failed to extract roll-pitch-yall angles!");
- return;
- }
- double raddeg = TMath::RadToDeg();
- pars[3] = raddeg * TMath::ATan2(-rot[5],rot[8]);
- pars[4] = raddeg * TMath::ASin(rot[2]);
- pars[5] = raddeg * TMath::ATan2(-rot[1],rot[0]);
- SetCh(i,pars);
+ // al.ApplyToGeometry();
+ // node = pne->GetPhysicalNode(); // changed in the meantime
+ // TGeoHMatrix *ma = node->GetMatrix();
+
+ // a less destructive method (it does not modify geometry), gives the same result:
+
+ TGeoHMatrix *ma = new TGeoHMatrix();
+ al.GetLocalMatrix(*ma);
+ ma->MultiplyLeft(node->GetMatrix()); // global trafo, modified by a[]
+
+ double chi2=0;
+ printf(" sm z r phi x (lab phi) y (lab z) z (lab r) all in cm\n");
+ for (int j=0; j<2; j++) for (int k=0; k<2; k++) for (int l=0; l<2; l++) {
+ if (fSurveyEX[i][j][k][l] == 0.0
+ && fSurveyEY[i][j][k][l] == 0.0
+ && fSurveyEZ[i][j][k][l] == 0.0) continue; // no data for this survey point
+ double master[3] = {fSurveyX[i][j][k][l],fSurveyY[i][j][k][l],fSurveyZ[i][j][k][l]};
+ double local[3];
+ ma->MasterToLocal(master,local);
+ double dx = local[0]-fSurveyX0[j][k][l];
+ double dy = local[1]-fSurveyY0[j][k][l];
+ double dz = local[2]-fSurveyZ0[j][k][l];
+ chi2 += dx*dx/fSurveyEX[i][j][k][l]/fSurveyEX[i][j][k][l];
+ chi2 += dy*dy/fSurveyEY[i][j][k][l]/fSurveyEY[i][j][k][l];
+ chi2 += dz*dz/fSurveyEZ[i][j][k][l]/fSurveyEZ[i][j][k][l];
+ printf("local survey %3d %3d %3d %3d %12.3f %12.3f %12.3f\n",i,j,k,l,local[0],local[1],local[2]);
+ printf("local ideal %12.3f %12.3f %12.3f\n",fSurveyX0[j][k][l],
+ fSurveyY0[j][k][l],fSurveyZ0[j][k][l]);
+ printf("difference %12.3f %12.3f %12.3f\n",dx,dy,dz);
}
+ printf("chi2 = %.2f\n",chi2);
+ return chi2;
+}
- // cleanup
- for (int i = 0; i < 18; i++) delete ideSm[i];
- for (int i = 0; i < 18; i++) delete misSm[i];
- for (int i = 0; i < 540; i++) delete ideCh[i];
- for (int i = 0; i < 540; i++) delete misCh[i];
+//_____________________________________________________________________________
+void trdAlignmentFcn(int &npar, double *g, double &f, double *par, int iflag) {
- return;
+ //
+ // Standard function as needed by Minuit-like minimization procedures.
+ // For the set of parameters par calculates and returns chi-squared.
+ //
+
+ // smuggle a C++ object into a C function
+ AliTRDalignment *alignment = (AliTRDalignment*) gMinuit->GetObjectFit();
+
+ f = alignment->SurveyChi2(par);
+ if (iflag==3) {}
+ if (npar) {}
+ if (g) {} // no warnings about unused stuff...
}
//_____________________________________________________________________________
-void AliTRDalignment::ReadSurveyReport(char *filename)
-{
- // read survey report and set the supermodule parameters correspondingly
+void AliTRDalignment::SurveyToAlignment(int i, const char * const flag) {
- fstream fi(filename,fstream::in);
- if (!fi) {
- AliFatal(Form("cannot open input file %s",filename));
+ //
+ // Find the supermodule alignment parameters needed to make the survey
+ // results coincide with the ideal positions of the survey marks.
+ // The string flag should look like "101000"; the six characters corresponds
+ // to the six alignment parameters and 0/1 mean that the parameter should
+ // be fixed/released in the fit.
+
+ if (strlen(flag)!=6) {
+ AliError(Form("unexpected flag: %s",flag));
+ return;
}
- // to be continued...
+ printf("Finding alignment matrix for supermodule %d\n",i);
+ fIbuffer[0] = i; // store the sm number in the buffer so minuit can see it
+
+ TFitter fitter(100);
+ gMinuit->SetObjectFit(this);
+ fitter.SetFCN(trdAlignmentFcn);
+ fitter.SetParameter(0,"dx",0,0.5,0,0);
+ fitter.SetParameter(1,"dy",0,0.5,0,0);
+ fitter.SetParameter(2,"dz",0,0.5,0,0);
+ fitter.SetParameter(3,"rx",0,0.1,0,0);
+ fitter.SetParameter(4,"ry",0,0.1,0,0);
+ fitter.SetParameter(5,"rz",0,0.1,0,0);
+
+ for (int j=0; j<6; j++) if (flag[j]=='0') fitter.FixParameter(j);
+
+ double arglist[100];
+ arglist[0] = 2;
+ fitter.ExecuteCommand("SET PRINT", arglist, 1);
+ fitter.ExecuteCommand("SET ERR", arglist, 1);
+ arglist[0]=50;
+ //fitter.ExecuteCommand("SIMPLEX", arglist, 1);
+ fitter.ExecuteCommand("MINIMIZE", arglist, 1);
+ fitter.ExecuteCommand("CALL 3", arglist,0);
+ double a[6];
+ for (int j=0; j<6; j++) a[j] = fitter.GetParameter(j);
+ SetSm(i,a);
+ for (int j=0; j<6; j++) printf("%10.3f ",fitter.GetParameter(j));
+ printf("\n");
+ for (int j=0; j<6; j++) printf("%10.3f ",fitter.GetParError(j));
+ printf("\n");
}
//_____________________________________________________________________________
-void AliTRDalignment::ReadAny(char *filename)
+void AliTRDalignment::ReadAny(const char * const filename)
{
//
// read the alignment data from any kind of file
//
TString fist(filename);
- if (fist.EndsWith(".txt")) {
- ReadAscii(filename);
- }
- if (fist.EndsWith(".dat")) {
- ReadAscii(filename);
- }
+ if (fist.EndsWith(".txt")) ReadAscii(filename);
+ if (fist.EndsWith(".dat")) ReadAscii(filename);
if (fist.EndsWith(".root")) {
- if (fist.Contains("Run")) {
- ReadDB(filename);
- }
- else {
- ReadRoot(filename);
- }
+ if (fist.Contains("Run")) ReadDB(filename);
+ else ReadRoot(filename);
}
}
//_____________________________________________________________________________
-void AliTRDalignment::WriteAscii(char *filename) const
+void AliTRDalignment::WriteAscii(const char * const filename) const
{
//
// store the alignment data on ascii file
}
//_____________________________________________________________________________
-void AliTRDalignment::WriteRoot(char *filename)
+void AliTRDalignment::WriteRoot(const char * const filename)
{
//
// store the alignment data on root file
//
- TClonesArray *ar = new TClonesArray("AliAlignObjAngles",10000);
+ TClonesArray *ar = new TClonesArray("AliAlignObjParams",10000);
NumbersToAr(ar);
TFile fo(filename,"RECREATE");
if (fo.IsOpen()) {
fo.WriteObject(ar,"TRDAlignObjs","kSingleKey");
fo.Close();
}
- else {
- AliError(Form("cannot open output file %s",filename));
- }
+ else AliError(Form("cannot open output file %s",filename));
delete ar;
}
//_____________________________________________________________________________
-void AliTRDalignment::WriteDB(char *filename, char *comment, Int_t run0, Int_t run1)
+void AliTRDalignment::WriteDB(const char * const filename, int run0, int run1)
{
//
// dumping on a DB-like file
//
- TClonesArray *ar = new TClonesArray("AliAlignObjAngles",10000);
+ TClonesArray *ar = new TClonesArray("AliAlignObjParams",10000);
NumbersToAr(ar);
- char *path = "di1/di2/di3";
+ const Char_t *path = "TRD/Align/Data";
AliCDBId id(path,run0,run1);
AliCDBMetaData *md = new AliCDBMetaData();
md->SetResponsible("Dariusz Miskowiec");
- md->SetComment(comment);
+ md->SetComment(fComment.GetString().Data());
AliCDBEntry *e = new AliCDBEntry(ar, id, md);
TFile fi(filename,"RECREATE");
if (fi.IsOpen()) {
e->Write();
fi.Close();
}
- else {
- AliError(Form("cannot open input file %s",filename));
- }
+ else AliError(Form("cannot open input file %s",filename));
delete e;
delete md;
}
//_____________________________________________________________________________
-void AliTRDalignment::WriteDB(char *db, char *path, char *comment, Int_t run0, Int_t run1)
+void AliTRDalignment::WriteDB(char * const db, const char * const path, int run0, int run1)
{
//
// store the alignment data in database
//
- TClonesArray *ar = new TClonesArray("AliAlignObjAngles",10000);
+ TClonesArray *ar = new TClonesArray("AliAlignObjParams",10000);
NumbersToAr(ar);
AliCDBManager *cdb = AliCDBManager::Instance();
AliCDBStorage *storLoc = cdb->GetStorage(db);
AliCDBMetaData *md = new AliCDBMetaData();
md->SetResponsible("Dariusz Miskowiec");
- md->SetComment(comment);
+ md->SetComment(fComment.GetString().Data());
AliCDBId id(path,run0,run1);
storLoc->Put(ar,id,md);
md->Delete();
void AliTRDalignment::WriteGeo(char *filename)
{
//
- // apply misalignment to (currently loaded ideal) geometry and store the
+ // apply misalignment to current geometry and store the
// resulting geometry on a root file
//
- TClonesArray *ar = new TClonesArray("AliAlignObjAngles",10000);
+ TClonesArray *ar = new TClonesArray("AliAlignObjParams",10000);
NumbersToAr(ar);
- for (int i = 0; i < ar->GetEntriesFast(); i++) {
- AliAlignObj *alobj = (AliAlignObj *) ar->UncheckedAt(i);
- alobj->ApplyToGeometry();
- }
delete ar;
gGeoManager->Export(filename);
}
//_____________________________________________________________________________
-Double_t AliTRDalignment::GetSmRMS(Int_t xyz) const
+double AliTRDalignment::GetSmRMS(int xyz) const
{
//
// rms fSm[][xyz]
//
- Double_t s1 = 0.0;
- Double_t s2 = 0.0;
+ double s1 = 0.0;
+ double s2 = 0.0;
for (int i = 0; i < 18; i++) {
s1 += fSm[i][xyz];
s2 += fSm[i][xyz]*fSm[i][xyz];
}
- Double_t rms2 = s2/18.0 - s1*s1/18.0/18.0;
+ double rms2 = s2/18.0 - s1*s1/18.0/18.0;
return rms2>0 ? sqrt(rms2) : 0.0;
}
//_____________________________________________________________________________
-Double_t AliTRDalignment::GetChRMS(Int_t xyz) const
+double AliTRDalignment::GetChRMS(int xyz) const
{
//
// rms fCh[][xyz]
//
- Double_t s1 =0.0;
- Double_t s2 =0.0;
+ double s1 =0.0;
+ double s2 =0.0;
for (int i = 0; i < 540; i++) {
s1 += fCh[i][xyz];
s2 += fCh[i][xyz]*fCh[i][xyz];
}
- Double_t rms2 = s2/540.0 - s1*s1/540.0/540.0;
+ double rms2 = s2/540.0 - s1*s1/540.0/540.0;
return rms2>0 ? sqrt(rms2) : 0.0;
}
//_____________________________________________________________________________
-void AliTRDalignment::ArToNumbers(TClonesArray *ar)
+void AliTRDalignment::ArToNumbers(TClonesArray * const ar)
{
//
- // read numbers from the array of AliAlignObj objects and fill fSm and fCh
+ // for each of the alignment objects in array ar extract the six local
+ // alignment parameters; recognize by name to which supermodule or chamber
+ // the alignment object pertains; set the respective fSm or fCh
//
- LoadIdealGeometry();
- SetZero();
- double pa[6];
- for (int i = 0; i < 18; i++) {
+ ar->Sort();
+ if (!IsGeoLoaded()) return;
+ for (int i = 0; i < ar->GetEntries(); i++) {
AliAlignObj *aao = (AliAlignObj *) ar->At(i);
- aao->GetLocalPars(pa,pa+3);
- SetSm(i,pa);
- }
- for (int i = 0; i < 540; i++) {
- AliAlignObj *aao = (AliAlignObj *) ar->At(18+i);
- aao->GetLocalPars(pa,pa+3);
- SetCh(i,pa);
+ aao->ApplyToGeometry();
}
+ SetZero();
+ ReadCurrentGeo();
}
//_____________________________________________________________________________
-void AliTRDalignment::NumbersToAr(TClonesArray *ar)
+void AliTRDalignment::NumbersToAr(TClonesArray * const ar)
{
//
// build array of AliAlignObj objects based on fSm and fCh data
+ // at the same time, apply misalignment to the currently loaded geometry
+ // it is important to apply misalignment of supermodules before creating
+ // alignment objects for chambers
//
- LoadIdealGeometry();
+ if (!IsGeoLoaded()) return;
TClonesArray &alobj = *ar;
int nobj = 0;
for (int i = 0; i < 18; i++) {
- new(alobj[nobj]) AliAlignObjAngles(GetSmName(i)
+ new(alobj[nobj]) AliAlignObjParams(GetSmName(i)
,0
,fSm[i][0],fSm[i][1],fSm[i][2]
,fSm[i][3],fSm[i][4],fSm[i][5]
,0);
+ ((AliAlignObj *) alobj[nobj])->ApplyToGeometry();
nobj++;
}
for (int i = 0; i < 540; i++) {
- new(alobj[nobj]) AliAlignObjAngles(GetChName(i)
- ,GetVoi(i)
- ,fCh[i][0],fCh[i][1],fCh[i][2]
- ,fCh[i][3],fCh[i][4],fCh[i][5]
- ,0);
- nobj++;
+ if (gGeoManager->GetAlignableEntry(GetChName(i))) {
+ new(alobj[nobj]) AliAlignObjParams(GetChName(i)
+ ,GetVoi(i)
+ ,fCh[i][0],fCh[i][1],fCh[i][2]
+ ,fCh[i][3],fCh[i][4],fCh[i][5]
+ ,0);
+ ((AliAlignObj *) alobj[nobj])->ApplyToGeometry();
+ nobj++;
+ }
}
+ AliInfo("current geometry modified");
}
//_____________________________________________________________________________
-void AliTRDalignment::LoadIdealGeometry(char *filename)
+int AliTRDalignment::IsGeoLoaded()
{
//
- // load ideal geometry from filename
- // it is needed for operations on AliAlignObj objects
- // this needs to be straightened out
- // particularly, sequences LoadIdealGeometry("file1"); LoadIdealGeometry("file2");
- // do not work as one would naturally expect
+ // check whether a geometry is loaded
+ // issue a warning if geometry is not ideal
//
- static int attempt = 0; // which reload attempt is it? just to avoid endless loops
-
- if (!gGeoManager) {
- TGeoManager::Import(filename);
- }
- if (!gGeoManager) {
- AliFatal(Form("cannot open geometry file %s",filename));
- }
- if (gGeoManager->GetListOfPhysicalNodes()->GetEntries()) {
- if (attempt) {
- AliFatal(Form("geometry on file %s is not ideal",filename));
- }
- AliWarning("current geometry is not ideal - it contains physical nodes");
- AliWarning(Form("reloading geometry from %s - attempt nr %d",filename,attempt));
- gGeoManager = 0;
- attempt++;
- LoadIdealGeometry(filename);
+ if (gGeoManager) {
+ if (gGeoManager->GetListOfPhysicalNodes()->GetEntries()) AliWarning("current geometry is not ideal");
+ return 1;
+ } else {
+ AliError("first load geometry by calling TGeoManager::Import(filename)");
+ return 0;
}
- attempt = 0;
-
}
+
+//_____________________________________________________________________________