[u/mrichter/AliRoot.git] / VZERO / VZEROSurveyToAlignment.C

#include "STEER/AliCDBManager.h"
#include "STEER/AliCDBStorage.h"
#include "STEER/AliCDBEntry.h"
#include "VZERO/AliVZEROSurveyData.h"

void VZEROSurveyToAlignment(){

  // Macro to convert survey data into alignment data. 
  // The position of four fiducial marks, sticked on the 
  // entrance face of the V0C box is converted into the 
  // global position of the box. Positions given by surveyers 
  // are extracted from Survey Data Base. 

  if(!gGeoManager) TGeoManager::Import("geometry.root");

  TClonesArray *array = new TClonesArray("AliAlignObjMatrix",10);
  TClonesArray &mobj = *array;
 
  Double_t l_vect[3]={0.,0.,0.}; // a local vector (the origin)
  Double_t g_vect[3];            // vector corresp. to it in global RS
  Double_t m_vect[3];            // vector corresp. to it in mother RS

  gGeoManager->cd("/ALIC_1/VZERO_1/V0RI_1");
  
  // ************* get global matrix *******************
  TGeoHMatrix* g3 = gGeoManager->GetCurrentMatrix();
  // this is used below as the ideal global matrix

  // ************* get local matrix *******************
  TGeoNode* n3 = gGeoManager->GetCurrentNode();
  TGeoHMatrix* l3 = n3->GetMatrix(); 

 // point coordinates in the global RS
  g3->LocalToMaster(l_vect,g_vect);
  cout<<endl<<"Point coordinates in the global RS: "<<
    g_vect[0]<<" "<<g_vect[1]<<" "<<g_vect[2];

 // point coordinates in the mother volume RS
  l3->LocalToMaster(l_vect,m_vect);
  cout<<endl<<"Point coordinates in the mother's volume RS: "<<
    m_vect[0]<<" "<<m_vect[1]<<" "<<m_vect[2]<<" "<<endl;

 // Hereafter are the four ideal fiducial marks on the V0C box, 
 // expressed in local coordinates and in cms - hard coded. 

  const Double_t xside   = 22.627;
  const Double_t yside   = 22.627;
  const Double_t zsize   = 2.35;
  const Double_t zoffset = 0.001;
  
  const Double_t zdepth  = zsize+zoffset;
  Double_t A[3]={-xside,-yside,zdepth};
  Double_t B[3]={xside,-yside,zdepth};
  Double_t C[3]={xside,yside,zdepth};
  Double_t D[3]={-xside,yside,zdepth};

  TGeoTranslation* Atr = new TGeoTranslation("Atr",-xside,-yside,zdepth);
  TGeoTranslation* Btr = new TGeoTranslation("Btr",xside,-yside,zdepth);
  TGeoTranslation* Ctr = new TGeoTranslation("Ctr",xside,yside,zdepth);
  TGeoTranslation* Dtr = new TGeoTranslation("Dtr",-xside,yside,zdepth);

  //                    ^ local y
  //                    |
  //      D-------------|-------------C
  //      |             |             |
  //      |             |             |
  //      |             |             |
  //      |             |             |
  //      |             |             |
  //      |             |             |
  //  ------------------|------------------> local x
  //      |             |             |
  //      |             |             |
  //      |             |             |
  //      |             |             |
  //      |             |             |
  //      |             |             |
  //      A-------------|-------------B
  //
  // local z exiting the plane of the screen
   
  Double_t gA[3], gB[3], gC[3], gD[3];
  g3->LocalToMaster(A,gA);
  g3->LocalToMaster(B,gB);
  g3->LocalToMaster(C,gC);
  g3->LocalToMaster(D,gD);
  cout<<endl<<"Ideal fiducial marks coordinates in the global RS:\n"<<
    "A "<<gA[0]<<" "<<gA[1]<<" "<<gA[2]<<" "<<endl<<
    "B "<<gB[0]<<" "<<gB[1]<<" "<<gB[2]<<" "<<endl<<
    "C "<<gC[0]<<" "<<gC[1]<<" "<<gC[2]<<" "<<endl<<
    "D "<<gD[0]<<" "<<gD[1]<<" "<<gD[2]<<" "<<endl;
    
// Retrieval of real survey data from CDB : 

   AliCDBManager *man = AliCDBManager::Instance();
   AliCDBStorage *storLoc;
   storLoc = man->GetStorage("local://$ALICE_ROOT");
 
   AliCDBEntry *entry=0;
   entry = storLoc->Get("VZERO/Survey/Data", 0);
   
   AliVZEROSurveyData * surveyda = 0;   
   if (entry) surveyda = (AliVZEROSurveyData*) entry->GetObject();
   if (!surveyda)  AliError("No survey data from survey database !");
   
   Double_t ngA[3], ngB[3], ngC[3], ngD[3];

     for(Int_t i=0; i<3; i++) 
     { ngA[i]  = surveyda->GetPointA(i) ; 
       ngB[i]  = surveyda->GetPointB(i) ;
       ngC[i]  = surveyda->GetPointC(i) ; 
       ngD[i]  = surveyda->GetPointD(i) ; }
          
   cout<<endl<<"Fiducial marks coordinates in the global RS given by survey:\n"<<
    "A "<<ngA[0]<<" "<<ngA[1]<<" "<<ngA[2]<<" "<<endl<<
    "B "<<ngB[0]<<" "<<ngB[1]<<" "<<ngB[2]<<" "<<endl<<
    "C "<<ngC[0]<<" "<<ngC[1]<<" "<<ngC[2]<<" "<<endl<<
    "D "<<ngD[0]<<" "<<ngD[1]<<" "<<ngD[2]<<" "<<endl;
    
   delete entry;

  // From the new fiducial marks coordinates derive back the new global position
  // of the surveyed volume
  //*** What follows is the actual survey-to-alignment procedure which assumes,
  //*** as is the case of the present example, 4 fiducial marks
  //*** at the corners of a square lying on a plane parallel to a surface
  //*** of the surveyed box at a certain offset and with
  //*** x and y sides parallel to the box's x and y axes.
  //*** If the code below is placed in a separate class or method, it needs
  //*** as input the four points and the offset from the origin (zdepth)
  //*** The algorithm can be easily modified for different placement
  //*** and/or cardinality of the fiducial marks.
  
  Double_t ab[3], bc[3], n[3];
  Double_t plane[4], s;

  // first vector on the plane of the fiducial marks
  for(i=0;i<3;i++){
    ab[i] = ngB[i] - ngA[i];
  }

  // second vector on the plane of the fiducial marks
  for(i=0;i<3;i++){
    bc[i] = ngC[i] - ngB[i];
  }

  // vector normal to the plane of the fiducial marks obtained
  // as cross product of the two vectors on the plane d0^d1
  n[0] = ab[1] * bc[2] - ab[2] * bc[1];
  n[1] = ab[2] * bc[0] - ab[0] * bc[2];
  n[2] = ab[0] * bc[1] - ab[1] * bc[0];

  Double_t sizen = TMath::Sqrt( n[0]*n[0] + n[1]*n[1] + n[2]*n[2] );
  if(sizen>1.e-8){
          s = Double_t(1.)/sizen ; //normalization factor
  }else{
          return 0;
  }

  // plane expressed in the hessian normal form, see:
  // http://mathworld.wolfram.com/HessianNormalForm.html
  // the first three are the coordinates of the orthonormal vector
  // the fourth coordinate is equal to the distance from the origin
  for(i=0;i<3;i++){
    plane[i] = n[i] * s;
  }
  plane[3] = -( plane[0] * ngA[0] + plane[1] * ngA[1] + plane[2] * ngA[2] );
  //  cout<<plane[0]<<"  "<<plane[1]<<"  "<<plane[2]<<"  "<<plane[3]<<"  "<<endl;

  // The center of the square with fiducial marks as corners
  // as the middle point of one diagonal - md
  // Used below to get the center - orig - of the surveyed box
  
  Double_t orig[3], md[3];
  for(i=0;i<3;i++){
    md[i] = (ngA[i] + ngC[i]) * 0.5;
  }

  //  center of the box
  for(i=0;i<3;i++){
    orig[i] = md[i] - plane[i]*zdepth;
  }
  orig[1] = md[1] - plane[1]*zdepth;
  orig[2] = md[2] - plane[2]*zdepth;
  cout<<endl<<"Center of the box: "<<orig[0]<<"  "<<orig[1]<<"  "<<orig[2]<<endl;

  // get x,y local directions needed to write the global rotation matrix
  // for the surveyed volume by normalising vectors ab and bc
  
  Double_t sx = TMath::Sqrt(ab[0]*ab[0] + ab[1]*ab[1] + ab[2]*ab[2]);
  if(sx>1.e-8){
     for(i=0;i<3;i++){
          ab[i] /= sx;
     }
     cout<<endl<<"x direction "<<ab[0]<<"  "<<ab[1]<<"  "<<ab[2]<<endl;
  }
  Double_t sy = TMath::Sqrt(bc[0]*bc[0] + bc[1]*bc[1] + bc[2]*bc[2]);
  if(sy>1.e-8){
    for(i=0;i<3;i++){
          bc[i] /= sy;
    }
    cout<<endl<<"y direction "<<bc[0]<<"  "<<bc[1]<<"  "<<bc[2]<<endl;
  }

  // the global matrix for the surveyed volume - ng
  Double_t rot[9] = {ab[0],bc[0],plane[0],ab[1],bc[1],plane[1],ab[2],bc[2],plane[2]};
  TGeoHMatrix ng;
  ng.SetTranslation(orig);
  ng.SetRotation(rot);

  cout<<"\n********* global matrix inferred from surveyed fiducial marks ***********\n";
  ng.Print();

 // To produce the alignment object for the given volume you would
 // then do something like this:
 // Calculate the global delta transformation as ng * g3^-1
 
 TGeoHMatrix gdelta = g3->Inverse(); //now equal to the inverse of g3
 gdelta.MultiplyLeft(&ng);
 Int_t index = 0;
 
 // if the volume is in the look-up table use something like this instead:
 // AliAlignObj::LayerToVolUID(AliAlignObj::kTOF,i); 
 
 //AliAlignObjMatrix* mobj[0] = new AliAlignObjMatrix("VZERO/V0C",index,gdelta,kTRUE);
 
  new(mobj[0]) AliAlignObjMatrix("VZERO/V0C",index,gdelta,kTRUE);
  
  if(!gSystem->Getenv("$TOCDB")){
    // save on file
    TFile f("V0Survey.root","RECREATE");
    if(!f) cerr<<"cannot open file for output\n";
    f.cd();
    f.WriteObject(array,"V0SurveyObjs ","kSingleKey");
    f.Close();
  }else{
    // save in CDB storage
    const char* Storage = gSystem->Getenv("$STORAGE");
    AliCDBManager* cdb = AliCDBManager::Instance();
    AliCDBStorage* storage = cdb->GetStorage(Storage);
    AliCDBMetaData* md = new AliCDBMetaData();
    md->SetResponsible("Brigitte Cheynis");
    md->SetComment("Alignment objects for V0 survey");
    md->SetAliRootVersion(gSystem->Getenv("$ARVERSION"));
    AliCDBId id("VZERO/Align/Data",0,9999999);
    storage->Put(array,id,md);
  }

  array->Delete();

}
Commit	Line	Data
d0c548dc	1	#include "STEER/AliCDBManager.h"
	2	#include "STEER/AliCDBStorage.h"
	3	#include "STEER/AliCDBEntry.h"
	4	#include "VZERO/AliVZEROSurveyData.h"
	5
	6	void VZEROSurveyToAlignment(){
	7
	8	// Macro to convert survey data into alignment data.
	9	// The position of four fiducial marks, sticked on the
	10	// entrance face of the V0C box is converted into the
	11	// global position of the box. Positions given by surveyers
	12	// are extracted from Survey Data Base.
	13
	14	if(!gGeoManager) TGeoManager::Import("geometry.root");
	15
	16	TClonesArray *array = new TClonesArray("AliAlignObjMatrix",10);
	17	TClonesArray &mobj = *array;
	18
	19	Double_t l_vect[3]={0.,0.,0.}; // a local vector (the origin)
	20	Double_t g_vect[3]; // vector corresp. to it in global RS
	21	Double_t m_vect[3]; // vector corresp. to it in mother RS
	22
	23	gGeoManager->cd("/ALIC_1/VZERO_1/V0RI_1");
	24
	25	// *********** get global matrix *****************
	26	TGeoHMatrix* g3 = gGeoManager->GetCurrentMatrix();
	27	// this is used below as the ideal global matrix
	28
	29	// *********** get local matrix *****************
	30	TGeoNode* n3 = gGeoManager->GetCurrentNode();
	31	TGeoHMatrix* l3 = n3->GetMatrix();
	32
	33	// point coordinates in the global RS
	34	g3->LocalToMaster(l_vect,g_vect);
	35	cout<<endl<<"Point coordinates in the global RS: "<<
	36	g_vect[0]<<" "<<g_vect[1]<<" "<<g_vect[2];
	37
	38	// point coordinates in the mother volume RS
	39	l3->LocalToMaster(l_vect,m_vect);
	40	cout<<endl<<"Point coordinates in the mother's volume RS: "<<
	41	m_vect[0]<<" "<<m_vect[1]<<" "<<m_vect[2]<<" "<<endl;
	42
	43	// Hereafter are the four ideal fiducial marks on the V0C box,
	44	// expressed in local coordinates and in cms - hard coded.
	45
	46	const Double_t xside = 22.627;
	47	const Double_t yside = 22.627;
	48	const Double_t zsize = 2.35;
	49	const Double_t zoffset = 0.001;
	50
	51	const Double_t zdepth = zsize+zoffset;
	52	Double_t A[3]={-xside,-yside,zdepth};
	53	Double_t B[3]={xside,-yside,zdepth};
	54	Double_t C[3]={xside,yside,zdepth};
	55	Double_t D[3]={-xside,yside,zdepth};
	56
	57	TGeoTranslation* Atr = new TGeoTranslation("Atr",-xside,-yside,zdepth);
	58	TGeoTranslation* Btr = new TGeoTranslation("Btr",xside,-yside,zdepth);
	59	TGeoTranslation* Ctr = new TGeoTranslation("Ctr",xside,yside,zdepth);
	60	TGeoTranslation* Dtr = new TGeoTranslation("Dtr",-xside,yside,zdepth);
	61
	62	// ^ local y
	63	// \|
	64	// D-------------\|-------------C
65	// \| \| \|
66	// \| \| \|
67	// \| \| \|
68	// \| \| \|
69	// \| \| \|
70	// \| \| \|
71	// ------------------\|------------------> local x
72	// \| \| \|
73	// \| \| \|
74	// \| \| \|
75	// \| \| \|
76	// \| \| \|
77	// \| \| \|
78	// A-------------\|-------------B
79	//
80	// local z exiting the plane of the screen
81
82	Double_t gA[3], gB[3], gC[3], gD[3];
83	g3->LocalToMaster(A,gA);
84	g3->LocalToMaster(B,gB);
85	g3->LocalToMaster(C,gC);
86	g3->LocalToMaster(D,gD);
87	cout<<endl<<"Ideal fiducial marks coordinates in the global RS:\n"<<
88	"A "<<gA[0]<<" "<<gA[1]<<" "<<gA[2]<<" "<<endl<<
89	"B "<<gB[0]<<" "<<gB[1]<<" "<<gB[2]<<" "<<endl<<
90	"C "<<gC[0]<<" "<<gC[1]<<" "<<gC[2]<<" "<<endl<<
91	"D "<<gD[0]<<" "<<gD[1]<<" "<<gD[2]<<" "<<endl;
92
93	// Retrieval of real survey data from CDB :
94
95	AliCDBManager *man = AliCDBManager::Instance();
96	AliCDBStorage *storLoc;
97	storLoc = man->GetStorage("local://$ALICE_ROOT");
98
99	AliCDBEntry *entry=0;
100	entry = storLoc->Get("VZERO/Survey/Data", 0);
101
102	AliVZEROSurveyData * surveyda = 0;
103	if (entry) surveyda = (AliVZEROSurveyData*) entry->GetObject();
104	if (!surveyda) AliError("No survey data from survey database !");
105
106	Double_t ngA[3], ngB[3], ngC[3], ngD[3];
107
108	for(Int_t i=0; i<3; i++)
109	{ ngA[i] = surveyda->GetPointA(i) ;
110	ngB[i] = surveyda->GetPointB(i) ;
111	ngC[i] = surveyda->GetPointC(i) ;
112	ngD[i] = surveyda->GetPointD(i) ; }
113
114	cout<<endl<<"Fiducial marks coordinates in the global RS given by survey:\n"<<
115	"A "<<ngA[0]<<" "<<ngA[1]<<" "<<ngA[2]<<" "<<endl<<
116	"B "<<ngB[0]<<" "<<ngB[1]<<" "<<ngB[2]<<" "<<endl<<
117	"C "<<ngC[0]<<" "<<ngC[1]<<" "<<ngC[2]<<" "<<endl<<
118	"D "<<ngD[0]<<" "<<ngD[1]<<" "<<ngD[2]<<" "<<endl;
119
120	delete entry;
121
122	// From the new fiducial marks coordinates derive back the new global position
123	// of the surveyed volume
124	//*** What follows is the actual survey-to-alignment procedure which assumes,
125	//*** as is the case of the present example, 4 fiducial marks
126	//*** at the corners of a square lying on a plane parallel to a surface
127	//*** of the surveyed box at a certain offset and with
128	//*** x and y sides parallel to the box's x and y axes.
129	//*** If the code below is placed in a separate class or method, it needs
130	//*** as input the four points and the offset from the origin (zdepth)
131	//*** The algorithm can be easily modified for different placement
132	//*** and/or cardinality of the fiducial marks.
133
134	Double_t ab[3], bc[3], n[3];
135	Double_t plane[4], s;
136
137	// first vector on the plane of the fiducial marks
138	for(i=0;i<3;i++){
139	ab[i] = ngB[i] - ngA[i];
140	}
141
142	// second vector on the plane of the fiducial marks
143	for(i=0;i<3;i++){
144	bc[i] = ngC[i] - ngB[i];
145	}
146
147	// vector normal to the plane of the fiducial marks obtained
148	// as cross product of the two vectors on the plane d0^d1
149	n[0] = ab[1] * bc[2] - ab[2] * bc[1];
150	n[1] = ab[2] * bc[0] - ab[0] * bc[2];
151	n[2] = ab[0] * bc[1] - ab[1] * bc[0];
152
153	Double_t sizen = TMath::Sqrt( n[0]n[0] + n[1]n[1] + n[2]*n[2] );
154	if(sizen>1.e-8){
155	s = Double_t(1.)/sizen ; //normalization factor
156	}else{
157	return 0;
158	}
159
160	// plane expressed in the hessian normal form, see:
161	// http://mathworld.wolfram.com/HessianNormalForm.html
162	// the first three are the coordinates of the orthonormal vector
163	// the fourth coordinate is equal to the distance from the origin
164	for(i=0;i<3;i++){
165	plane[i] = n[i] * s;
166	}
167	plane[3] = -( plane[0] * ngA[0] + plane[1] * ngA[1] + plane[2] * ngA[2] );
168	// cout<<plane[0]<<" "<<plane[1]<<" "<<plane[2]<<" "<<plane[3]<<" "<<endl;
169
170	// The center of the square with fiducial marks as corners
171	// as the middle point of one diagonal - md
172	// Used below to get the center - orig - of the surveyed box
173
174	Double_t orig[3], md[3];
175	for(i=0;i<3;i++){
176	md[i] = (ngA[i] + ngC[i]) * 0.5;
177	}
178
179	// center of the box
180	for(i=0;i<3;i++){
181	orig[i] = md[i] - plane[i]*zdepth;
182	}
183	orig[1] = md[1] - plane[1]*zdepth;
184	orig[2] = md[2] - plane[2]*zdepth;
185	cout<<endl<<"Center of the box: "<<orig[0]<<" "<<orig[1]<<" "<<orig[2]<<endl;
186
187	// get x,y local directions needed to write the global rotation matrix
188	// for the surveyed volume by normalising vectors ab and bc
189
190	Double_t sx = TMath::Sqrt(ab[0]ab[0] + ab[1]ab[1] + ab[2]*ab[2]);
191	if(sx>1.e-8){
192	for(i=0;i<3;i++){
193	ab[i] /= sx;
194	}
195	cout<<endl<<"x direction "<<ab[0]<<" "<<ab[1]<<" "<<ab[2]<<endl;
196	}
197	Double_t sy = TMath::Sqrt(bc[0]bc[0] + bc[1]bc[1] + bc[2]*bc[2]);
198	if(sy>1.e-8){
199	for(i=0;i<3;i++){
200	bc[i] /= sy;
201	}
202	cout<<endl<<"y direction "<<bc[0]<<" "<<bc[1]<<" "<<bc[2]<<endl;
203	}
204
205	// the global matrix for the surveyed volume - ng
206	Double_t rot[9] = {ab[0],bc[0],plane[0],ab[1],bc[1],plane[1],ab[2],bc[2],plane[2]};
207	TGeoHMatrix ng;
208	ng.SetTranslation(orig);
209	ng.SetRotation(rot);
210
211	cout<<"\n******* global matrix inferred from surveyed fiducial marks *********\n";
212	ng.Print();
213
214	// To produce the alignment object for the given volume you would
215	// then do something like this:
216	// Calculate the global delta transformation as ng * g3^-1
217
218	TGeoHMatrix gdelta = g3->Inverse(); //now equal to the inverse of g3
219	gdelta.MultiplyLeft(&ng);
220	Int_t index = 0;
221
222	// if the volume is in the look-up table use something like this instead:
223	// AliAlignObj::LayerToVolUID(AliAlignObj::kTOF,i);
224
225	//AliAlignObjMatrix* mobj[0] = new AliAlignObjMatrix("VZERO/V0C",index,gdelta,kTRUE);
226
227	new(mobj[0]) AliAlignObjMatrix("VZERO/V0C",index,gdelta,kTRUE);
228
229	if(!gSystem->Getenv("$TOCDB")){
230	// save on file
231	TFile f("V0Survey.root","RECREATE");
232	if(!f) cerr<<"cannot open file for output\n";
233	f.cd();
234	f.WriteObject(array,"V0SurveyObjs ","kSingleKey");
235	f.Close();
236	}else{
237	// save in CDB storage
238	const char* Storage = gSystem->Getenv("$STORAGE");
239	AliCDBManager* cdb = AliCDBManager::Instance();
240	AliCDBStorage* storage = cdb->GetStorage(Storage);
241	AliCDBMetaData* md = new AliCDBMetaData();
242	md->SetResponsible("Brigitte Cheynis");
243	md->SetComment("Alignment objects for V0 survey");
244	md->SetAliRootVersion(gSystem->Getenv("$ARVERSION"));
245	AliCDBId id("VZERO/Align/Data",0,9999999);
246	storage->Put(array,id,md);
247	}
248
249	array->Delete();
250
251	}