//_____________________________________________________________________________
Int_t AliTRDdisplayDigits3D(Int_t event = 0, Int_t thresh = 4
, Bool_t sdigits = kFALSE)
{
//
// TRD digits display
//
// Input parameter:
// <event> : Event number
// <thresh> : Threshold to suppress the noise
// <sdigits> : If kTRUE it will display summable digits, normal digits otherwise.
// The signal event is displayed in yellow.
//
Char_t *inputFile = "galice.root";
// Define the objects
AliTRDv1 *trd;
AliTRDgeometry *geo;
TString evfoldname = AliConfig::GetDefaultEventFolderName();
AliRunLoader *runLoader = AliRunLoader::GetRunLoader(evfoldname);
if (!runLoader) {
runLoader = AliRunLoader::Open(inputFile
,AliConfig::GetDefaultEventFolderName()
,"UPDATE");
}
if (!runLoader) {
printf("Can not open session for file %s.",inputFile);
return kFALSE;
}
if (!runLoader->GetAliRun()) {
runLoader->LoadgAlice();
}
gAlice = runLoader->GetAliRun();
if (!gAlice) {
printf("Could not find AliRun object.\n");
return kFALSE;
}
runLoader->GetEvent(event);
AliLoader *loader = runLoader->GetLoader("TRDLoader");
if (!loader) {
printf("Can not get TRD loader from Run Loader");
}
loader->LoadDigits();
// Get the pointer to the detector object
trd = (AliTRDv1*) gAlice->GetDetector("TRD");
// Get the pointer to the geometry object
if (trd) {
geo = trd->GetGeometry();
}
else {
printf("Cannot find the geometry\n");
return 1;
}
AliCDBManager *cdbManager = AliCDBManager::Instance();
cdbManager->SetDefaultStorage("local://$ALICE_ROOT/OCDB");
AliTRDcalibDB *calibration = AliTRDcalibDB::Instance();
calibration->SetRun(0);
TCanvas *c1 = new TCanvas("digits","TRD digits display",0,0,700,730);
TView *v = new TView(1);
v->SetRange(-430,-560,-430,430,560,1710);
v->SetParallel();
c1->Clear();
c1->SetFillColor(1);
c1->SetTheta(90.0);
c1->SetPhi(0.0);
Int_t markerColorSignal = 2;
Int_t markerColorBgnd = 7;
Int_t markerColorMerged = 5;
Int_t mask = 10000000;
// Create the digits manager
AliTRDdigitsManager *digitsManager = new AliTRDdigitsManager();
digitsManager->SetSDigits(sdigits);
// Read the digits from the file
if (sdigits) {
digitsManager->ReadDigits(loader->TreeS());
}
else {
if (!loader->TreeD()) {
printf("mist\n");
return kFALSE;
}
digitsManager->ReadDigits(loader->TreeD());
}
Int_t totalsignal = 0;
Int_t totalbgnd = 0;
Int_t totalmerged = 0;
Int_t timeMax = calibration->GetNumberOfTimeBins();
// Loop through all detectors
for (Int_t idet = 0; idet < geo->Ndet(); idet++) {
printf("<AliTRDdisplayDigits3D> Loading detector %d\n",idet);
AliTRDdataArrayI *digits = digitsManager->GetDigits(idet);
digits->Expand();
Int_t isec = geo->GetSector(idet);
Int_t icha = geo->GetChamber(idet);
Int_t ipla = geo->GetPlane(idet);
AliTRDpadPlane *padPlane = new AliTRDpadPlane(ipla,icha);
Int_t rowMax = padPlane->GetNrows();
Int_t colMax = padPlane->GetNcols();
Int_t ndigits = digits->GetOverThreshold(thresh);
if (ndigits > 0) {
TPolyMarker3D *pmSignal = new TPolyMarker3D(ndigits);
Int_t isignal = 0;
for (Int_t time = 0; time < timeMax; time++) {
for (Int_t col = 0; col < colMax; col++) {
for (Int_t row = 0; row < rowMax; row++) {
Int_t amp = digits->GetDataUnchecked(row,col,time);
if (amp > thresh) {
Double_t glb[3];
Double_t loc[3];
loc[0] = row;
loc[1] = col;
loc[2] = time;
geo->Local2Global(idet,loc,glb);
Double_t x = glb[0];
Double_t y = glb[1];
Double_t z = glb[2];
pmSignal->SetPoint(isignal,x,y,z);
isignal++;
totalsignal++;
}
}
}
}
digits->Compress(1,0);
pmSignal->SetMarkerSize(1);
pmSignal->SetMarkerColor(markerColorSignal);
pmSignal->SetMarkerStyle(1);
pmSignal->Draw();
}
}
delete padPlane;
TGeometry *geoAlice = gAlice->GetGeometry();
TNode *main = (TNode *) ((geoAlice->GetListOfNodes())->First());
TIter next(main->GetListOfNodes());
TNode *module = 0;
while ((module = (TNode *) next())) {
Char_t ch[100];
sprintf(ch,"%s\n",module->GetTitle());
if ((ch[0] == 'T') && ((ch[1] == 'R') || (ch[1] == 'P'))) {
module->SetVisibility( 3);
}
else {
module->SetVisibility(-1);
}
}
geoAlice->Draw("same");
c1->Modified();
c1->Update();
return 0;
}
void xtruSamples()
{
// Draw a sample of TXTRU shapes some convex, concave (and possibly malformed)
// Change Bool_t's to test alternative specifications
// Author: Robert Hatcher ([email protected]) 2000.09.06
// One normally specifies the x-y points in counter-clockwise order;
// flip this to TRUE to test that it doesn't matter.
Bool_t makecw = kFALSE;
// One normally specifies the z points in increasing z order;
// flip this to TRUE to test that it doesn't matter.
Bool_t reversez = kFALSE;
// One shouldn't be creating malformed polygons
// but to test what happens when one does here's a flag.
// The effect will be only apparent in solid rendering mode
Bool_t domalformed = kFALSE;
// domalformed = kTRUE;
c1 = new TCanvas("c1","sample TXTRU Shapes",200,10,640,640);
// Create a new geometry
TGeometry* geom = new TGeometry("sample","sample");
geom->cd();
// Define the complexity of the drawing
Float_t zseg = 6; // either 2 or 6
Int_t extravis = 0; // make extra z "arrow" visible
Float_t unit = 1;
// Create a large BRIK to embed things into
Float_t bigdim = 12.5*unit;
TBRIK* world = new TBRIK("world","world","void",bigdim,bigdim,bigdim);
// Create the main node, make it invisible
TNode* worldnode = new TNode("worldnode","world node",world);
worldnode->SetVisibility(0);
worldnode->cd();
// Canonical shape ... gets further modified by scale factors
// to create convex (and malformed) versions
Float_t x[] = { -0.50, -1.20, 1.20, 0.50, 0.50, 1.20, -1.20, -0.50 };
Float_t y[] = { -0.75, -2.00, -2.00, -0.75, 0.75, 2.00, 2.00, 0.75 };
Float_t z[] = { -0.50, -1.50, -1.50, 1.50, 1.50, 0.50 };
Float_t s[] = { 0.50, 1.00, 1.50, 1.50, 1.00, 0.50 };
Int_t nxy = sizeof(x)/sizeof(Float_t);
Float_t convexscale[] = { 7.0, -1.0, 1.5 };
Int_t icolor[] = { 1, 2, 3, 2, 2, 2, 4, 2, 6 };
// xycase and zcase: 0=convex, 1=malformed, 2=concave
// this will either create a 2x2 matrix of shapes
// or a 3x3 array (if displaying malformed versions)
for (Int_t zcase = 0; zcase<3; zcase++) {
if (zcase == 1 && !domalformed) continue;
for (Int_t xycase = 0; xycase<3; xycase++) {
if (xycase == 1 && !domalformed) continue;
Char_t *name = "txtruXYZ";
sprintf(name,"txtru%1d%1d%1d",xycase,zcase,zseg);
TXTRU* mytxtru = new TXTRU(name,name,"void",8,2);
Int_t i, j;
Float_t xsign = (makecw) ? -1 : 1;
Float_t zsign = (reversez) ? -1 : 1;
// set the vertex points
for (i=0; i<nxy; i++) {
Float_t xtmp = x[i]*xsign;
Float_t ytmp = y[i];
if (i==0||i==3||i==4||i==7) xtmp *= convexscale[xycase];
if (xycase==2) xtmp *=2;
mytxtru->DefineVertex(i,xtmp,ytmp);
}
// set the z segment positions and scales
for (i=0, j=0; i<zseg; i++) {
Float_t ztmp = z[i]*zsign;
if (i==0||i==5) ztmp *= convexscale[zcase];
if (zcase==2) ztmp *= 2.5;
if (zseg>2 && zcase!=2 && (i==1||i==4)) continue;
mytxtru->DefineSection(j,ztmp,s[i]);
j++;
}
TNode* txtrunode = new TNode(name,name,mytxtru);
txtrunode->SetLineColor(icolor[3*zcase+xycase]);
Float_t pos_scale = (domalformed) ? 10 : 6;
Float_t xpos = (xycase-1)*pos_scale*unit;
Float_t ypos = (zcase-1)*pos_scale*unit;
txtrunode->SetPosition(xpos,ypos,0.);
}
}
// Some extra shapes to show the direction of "z"
Float_t zhalf = 0.5*bigdim;
Float_t rmax = 0.03*bigdim;
TCONE* zcone = new TCONE("zcone","zcone","void",zhalf,0.,rmax,0.,0.);
zcone->SetVisibility(extravis);
TNode* zconenode = new TNode("zconenode","zconenode",zcone);
zconenode->SetLineColor(3);
Float_t dzstub = 2*rmax;
TBRIK* zbrik = new TBRIK("zbrik","zbrik","void",rmax,rmax,dzstub);
zbrik->SetVisibility(extravis);
TNode* zbriknode = new TNode("zbriknode","zbriknode",zbrik);
zbriknode->SetPosition(0.,0.,zhalf+dzstub);
zbriknode->SetLineColor(3);
// geom->ls();
geom->Draw();
// Tweak the pad so that it displays the entire geometry undistorted
TVirtualPad *thisPad = gPad;
if (thisPad) {
TView *view = thisPad->GetView();
if (!view) return;
Double_t min[3],max[3],center[3];
view->GetRange(min,max);
int i;
// Find the boxed center
for (i=0;i<3; i++) center[i] = 0.5*(max[i]+min[i]);
Double_t maxSide = 0;
// Find the largest side
for (i=0;i<3; i++) maxSide = TMath::Max(maxSide,max[i]-center[i]);
file://Adjust scales:
for (i=0;i<3; i++) {
max[i] = center[i] + maxSide;
min[i] = center[i] - maxSide;
}
view->SetRange(min,max);
thisPad->Modified();
thisPad->Update();
}
}