// @(#)root/geom:$Id: TGeoShape.cxx 20882 2007-11-19 11:31:26Z rdm $ // Author: Andrei Gheata 31/01/02 /************************************************************************* * Copyright (C) 1995-2000, Rene Brun and Fons Rademakers. * * All rights reserved. * * * * For the licensing terms see $ROOTSYS/LICENSE. * * For the list of contributors see $ROOTSYS/README/CREDITS. * *************************************************************************/ //____________________________________________________________________________ // TGeoShape - Base abstract class for all shapes. //____________________________________________________________________________ // // // Shapes are geometrical objects that provide the basic modelling // functionality. They provide the definition of the LOCAL frame of coordinates, // with respect to which they are defined. Any implementation of a shape deriving // from the base TGeoShape class has to provide methods for : // - finding out if a point defined in their local frame is or not contained // inside; // - computing the distance from a local point to getting outside/entering the // shape, given a known direction; // - computing the maximum distance in any direction from a local point that // does NOT result in a boundary crossing of the shape (safe distance); // - computing the cosines of the normal vector to the crossed shape surface, // given a starting local point and an ongoing direction. // All the features above are globally managed by the modeller in order to // provide navigation functionality. In addition to those, shapes have also to // implement additional specific abstract methods : // - computation of the minimal box bounding the shape, given that this box have // to be aligned with the local coordinates; // - algorithms for dividing the shape along a given axis and producing resulting // divisions volumes. // // The modeler currently provides a set of 16 basic shapes, which we will call // primitives. It also provides a special class allowing the creation of shapes // made as a result of boolean operations between primitives. These are called // composite shapes and the composition operation can be recursive (composition // of composites). This allows the creation of a quite large number of different // shape topologies and combinations. // // Shapes are named objects and register themselves to the manager class at // creation time. This is responsible for their final deletion. Shapes // can be created without name if their retreival by name is no needed. Generally // shapes are objects that are usefull only at geometry creation stage. The pointer // to a shape is in fact needed only when referring to a given volume and it is // always accessible at that level. A shape may be referenced by several volumes, // therefore its deletion is not possible once volumes were defined based on it. // // // // Creating shapes //================ // Shape objects embeed only the minimum set of parameters that are fully // describing a valid physical shape. For instance, a tube is represented by // its half length, the minimum radius and the maximum radius. Shapes are used // togeather with media in order to create volumes, which in their turn // are the main components of the geometrical tree. A specific shape can be created // stand-alone : // // TGeoBBox *box = new TGeoBBox("s_box", halfX, halfY, halfZ); // named // TGeoTube *tub = new TGeoTube(rmin, rmax, halfZ); // no name // ... (see each specific shape constructors) // // Sometimes it is much easier to create a volume having a given shape in one // step, since shapes are not direcly linked in the geometrical tree but volumes // are : // // TGeoVolume *vol_box = gGeoManager->MakeBox("BOX_VOL", "mat1", halfX, halfY, halfZ); // TGeoVolume *vol_tub = gGeoManager->MakeTube("TUB_VOL", "mat2", rmin, rmax, halfZ); // ... (see MakeXXX() utilities in TGeoManager class) // // // Shape queries //=============== // Note that global queries related to a geometry are handled by the manager class. // However, shape-related queries might be sometimes usefull. // // A) Bool_t TGeoShape::Contains(Double_t *point[3]) // - this method returns true if POINT is actually inside the shape. The point // has to be defined in the local shape reference. For instance, for a box having // DX, DY and DZ half-lengths a point will be considered inside if : // | -DX <= point[0] <= DX // | -DY <= point[1] <= DY // | -DZ <= point[2] <= DZ // // B) Double_t TGeoShape::DistFromInside(Double_t *point[3], Double_t *dir[3], // Int_t iact, Double_t step, Double_t *safe) // - computes the distance to exiting a shape from a given point INSIDE, along // a given direction. The direction is given by its director cosines with respect // to the local shape coordinate system. This method provides additional // information according the value of IACT input parameter : // IACT = 0 => compute only safe distance and fill it at the location // given by SAFE // IACT = 1 => a proposed STEP is supplied. The safe distance is computed // first. If this is bigger than STEP than the proposed step // is approved and returned by the method since it does not // cross the shape boundaries. Otherwise, the distance to // exiting the shape is computed and returned. // IACT = 2 => compute both safe distance and distance to exiting, ignoring // the proposed step. // IACT > 2 => compute only the distance to exiting, ignoring anything else. // // C) Double_t TGeoShape::DistFromOutside(Double_t *point[3], Double_t *dir[3], // Int_t iact, Double_t step, Double_t *safe) // - computes the distance to entering a shape from a given point OUTSIDE. Acts // in the same way as B). // // D) Double_t Safety(Double_t *point[3], Bool_t inside) // // - compute maximum shift of a point in any direction that does not change its // INSIDE/OUTSIDE state (does not cross shape boundaries). The state of the point // have to be properly supplied. // // E) Double_t *Normal(Double_t *point[3], Double_t *dir[3], Bool_t inside) // // - returns director cosines of normal to the crossed shape surface from a // given point towards a direction. One has to specify if the point is inside // or outside shape. According to this, the normal will be outwards or inwards // shape respectively. Normal components are statically stored by shape class, // so it has to be copied after retreival in a different array. // // Dividing shapes //================= // Shapes can generally be divided along a given axis. Supported axis are // X, Y, Z, Rxy, Phi, Rxyz. A given shape cannot be divided however on any axis. // The general rule is that that divisions are possible on whatever axis that // produces still known shapes as slices. The division of shapes should not be // performed by TGeoShape::Divide() calls, but rather by TGeoVolume::Divide(). // The algorithm for dividing a specific shape is known by the shape object, but // is always invoked in a generic way from the volume level. Details on how to // do that can be found in TGeoVolume class. One can see how all division options // are interpreted and which is their result inside specific shape classes. //_____________________________________________________________________________ // //Begin_Html /* <img src="gif/t_shape.jpg"> */ //End_Html #include "TObjArray.h" #include "TEnv.h" #include "TError.h" #include "TGeoMatrix.h" #include "TGeoManager.h" #include "TGeoVolume.h" #include "TGeoShape.h" #include "TVirtualGeoPainter.h" #include "TBuffer3D.h" #include "TBuffer3DTypes.h" #include "TMath.h" ClassImp(TGeoShape) TGeoMatrix *TGeoShape::fgTransform = NULL; //_____________________________________________________________________________ TGeoShape::TGeoShape() { // Default constructor fShapeBits = 0; fShapeId = 0; if (!gGeoManager) { gGeoManager = new TGeoManager("Geometry", "default geometry"); // gROOT->AddGeoManager(gGeoManager); } // fShapeId = gGeoManager->GetListOfShapes()->GetSize(); // gGeoManager->AddShape(this); } //_____________________________________________________________________________ TGeoShape::TGeoShape(const char *name) :TNamed(name, "") { // Default constructor fShapeBits = 0; fShapeId = 0; if (!gGeoManager) { gGeoManager = new TGeoManager("Geometry", "default geometry"); // gROOT->AddGeoManager(gGeoManager); } fShapeId = gGeoManager->GetListOfShapes()->GetSize(); gGeoManager->AddShape(this); } //_____________________________________________________________________________ TGeoShape::~TGeoShape() { // Destructor if (gGeoManager) gGeoManager->GetListOfShapes()->Remove(this); } //_____________________________________________________________________________ const char *TGeoShape::GetName() const { // Get the shape name. if (!strlen(fName)) { return ((TObject *)this)->ClassName(); } return TNamed::GetName(); } //_____________________________________________________________________________ Int_t TGeoShape::ShapeDistancetoPrimitive(Int_t numpoints, Int_t px, Int_t py) const { // Returns distance to shape primitive mesh. TVirtualGeoPainter *painter = gGeoManager->GetGeomPainter(); if (!painter) return 9999; return painter->ShapeDistancetoPrimitive(this, numpoints, px, py); } //_____________________________________________________________________________ Bool_t TGeoShape::IsCloseToPhi(Double_t epsil, Double_t *point, Double_t c1, Double_t s1, Double_t c2, Double_t s2) { // True if point is closer than epsil to one of the phi planes defined by c1,s1 or c2,s2 Double_t saf1 = TGeoShape::Big(); Double_t saf2 = TGeoShape::Big(); if (point[0]*c1+point[1]*s1 >= 0) saf1 = TMath::Abs(-point[0]*s1 + point[1]*c1); if (point[0]*c2+point[1]*s2 >= 0) saf2 = TMath::Abs(point[0]*s2 - point[1]*c2); Double_t saf = TMath::Min(saf1,saf2); if (saf<epsil) return kTRUE; return kFALSE; } //_____________________________________________________________________________ Bool_t TGeoShape::IsInPhiRange(Double_t *point, Double_t phi1, Double_t phi2) { // Static method to check if a point is in the phi range (phi1, phi2) [degrees] Double_t phi = TMath::ATan2(point[1], point[0]) * TMath::RadToDeg(); while (phi<phi1) phi+=360.; Double_t ddp = phi-phi1; if (ddp>phi2-phi1) return kFALSE; return kTRUE; } //_____________________________________________________________________________ Bool_t TGeoShape::IsCrossingSemiplane(Double_t *point, Double_t *dir, Double_t cphi, Double_t sphi, Double_t &snext, Double_t &rxy) { // Compute distance from POINT to semiplane defined by PHI angle along DIR. Computes // also radius at crossing point. This might be negative in case the crossing is // on the other side of the semiplane. snext = rxy = TGeoShape::Big(); Double_t nx = -sphi; Double_t ny = cphi; Double_t rxy0 = point[0]*cphi+point[1]*sphi; Double_t rdotn = point[0]*nx + point[1]*ny; if (TMath::Abs(rdotn)<TGeoShape::Tolerance()) { snext = 0.0; rxy = rxy0; return kTRUE; } if (rdotn<0) { rdotn = -rdotn; } else { nx = -nx; ny = -ny; } Double_t ddotn = dir[0]*nx + dir[1]*ny; if (ddotn<=0) return kFALSE; snext = rdotn/ddotn; rxy = rxy0+snext*(dir[0]*cphi+dir[1]*sphi); if (rxy<0) return kFALSE; return kTRUE; } //_____________________________________________________________________________ Double_t TGeoShape::DistToPhiMin(Double_t *point, Double_t *dir, Double_t s1, Double_t c1, Double_t s2, Double_t c2, Double_t sm, Double_t cm, Bool_t in) { // compute distance from point (inside phi) to both phi planes. Return minimum. Double_t sfi1=TGeoShape::Big(); Double_t sfi2=TGeoShape::Big(); Double_t s=0; Double_t un = dir[0]*s1-dir[1]*c1; if (!in) un=-un; if (un>0) { s=-point[0]*s1+point[1]*c1; if (!in) s=-s; if (s>=0) { s /= un; if (((point[0]+s*dir[0])*sm-(point[1]+s*dir[1])*cm)>=0) sfi1=s; } } un = -dir[0]*s2+dir[1]*c2; if (!in) un=-un; if (un>0) { s=point[0]*s2-point[1]*c2; if (!in) s=-s; if (s>=0) { s /= un; if ((-(point[0]+s*dir[0])*sm+(point[1]+s*dir[1])*cm)>=0) sfi2=s; } } return TMath::Min(sfi1, sfi2); } //_____________________________________________________________________________ void TGeoShape::NormalPhi(Double_t *point, Double_t *dir, Double_t *norm, Double_t c1, Double_t s1, Double_t c2, Double_t s2) { // Static method to compute normal to phi planes. Double_t saf1 = TGeoShape::Big(); Double_t saf2 = TGeoShape::Big(); if (point[0]*c1+point[1]*s1 >= 0) saf1 = TMath::Abs(-point[0]*s1 + point[1]*c1); if (point[0]*c2+point[1]*s2 >= 0) saf2 = TMath::Abs(point[0]*s2 - point[1]*c2); Double_t c,s; if (saf1<saf2) { c=c1; s=s1; } else { c=c2; s=s2; } norm[2] = 0; norm[0] = -s; norm[1] = c; if (dir[0]*norm[0]+dir[1]*norm[1] < 0) { norm[0] = s; norm[1] = -c; } } //_____________________________________________________________________________ Double_t TGeoShape::SafetyPhi(Double_t *point, Bool_t in, Double_t phi1, Double_t phi2) { // Static method to compute safety w.r.t a phi corner defined by cosines/sines // of the angles phi1, phi2. Bool_t inphi = TGeoShape::IsInPhiRange(point, phi1, phi2); if (inphi && !in) return -TGeoShape::Big(); phi1 *= TMath::DegToRad(); phi2 *= TMath::DegToRad(); Double_t c1 = TMath::Cos(phi1); Double_t s1 = TMath::Sin(phi1); Double_t c2 = TMath::Cos(phi2); Double_t s2 = TMath::Sin(phi2); Double_t rsq = point[0]*point[0]+point[1]*point[1]; Double_t rproj = point[0]*c1+point[1]*s1; Double_t safsq = rsq-rproj*rproj; if (safsq<0) return 0.; Double_t saf1 = (rproj<0)?TGeoShape::Big():TMath::Sqrt(safsq); rproj = point[0]*c2+point[1]*s2; safsq = rsq-rproj*rproj; if (safsq<0) return 0.; Double_t saf2 = (rproj<0)?TGeoShape::Big():TMath::Sqrt(safsq); Double_t safe = TMath::Min(saf1, saf2); // >0 if (safe>1E10) { if (in) return TGeoShape::Big(); return -TGeoShape::Big(); } return safe; } //_____________________________________________________________________________ void TGeoShape::SetShapeBit(UInt_t f, Bool_t set) { // Equivalent of TObject::SetBit. if (set) { SetShapeBit(f); } else { ResetShapeBit(f); } } //_____________________________________________________________________________ TGeoMatrix *TGeoShape::GetTransform() { // Returns current transformation matrix that applies to shape. return fgTransform; } //_____________________________________________________________________________ void TGeoShape::SetTransform(TGeoMatrix *matrix) { // Set current transformation matrix that applies to shape. fgTransform = matrix; } //_____________________________________________________________________________ void TGeoShape::TransformPoints(Double_t *points, UInt_t NbPnts) const { // Tranform a set of points (LocalToMaster) UInt_t i,j; Double_t dlocal[3]; Double_t dmaster[3]; if (fgTransform) { for (j = 0; j < NbPnts; j++) { i = 3*j; fgTransform->LocalToMaster(&points[i], dmaster); points[i] = dmaster[0]; points[i+1] = dmaster[1]; points[i+2] = dmaster[2]; } return; } if (!gGeoManager) return; Bool_t bomb = (gGeoManager->GetBombMode()==0)?kFALSE:kTRUE; for (j = 0; j < NbPnts; j++) { i = 3*j; dlocal[0] = points[3*j]; dlocal[1] = points[3*j+1]; dlocal[2] = points[3*j+2]; if (gGeoManager->IsMatrixTransform()) { TGeoHMatrix *glmat = gGeoManager->GetGLMatrix(); if (bomb) glmat->LocalToMasterBomb(&points[i], dmaster); else glmat->LocalToMaster(&points[i], dmaster); } else { if (bomb) gGeoManager->LocalToMasterBomb(&points[i], dmaster); else gGeoManager->LocalToMaster(&points[i],dmaster); } points[i] = dmaster[0]; points[i+1] = dmaster[1]; points[i+2] = dmaster[2]; } } //_____________________________________________________________________________ void TGeoShape::FillBuffer3D(TBuffer3D & buffer, Int_t reqSections, Bool_t localFrame) const { // Fill the supplied buffer, with sections in desired frame // See TBuffer3D.h for explanation of sections, frame etc. // Catch this common potential error here // We have to set kRawSize (unless already done) to allocate buffer space // before kRaw can be filled if (reqSections & TBuffer3D::kRaw) { if (!(reqSections & TBuffer3D::kRawSizes) && !buffer.SectionsValid(TBuffer3D::kRawSizes)) { R__ASSERT(kFALSE); } } if (reqSections & TBuffer3D::kCore) { // If writing core section all others will be invalid buffer.ClearSectionsValid(); // Check/grab some objects we need if (!gGeoManager) { R__ASSERT(kFALSE); return; } const TGeoVolume * paintVolume = gGeoManager->GetPaintVolume(); if (!paintVolume) paintVolume = gGeoManager->GetTopVolume(); if (!paintVolume) { buffer.fID = const_cast<TGeoShape *>(this); buffer.fColor = 0; buffer.fTransparency = 0; // R__ASSERT(kFALSE); // return; } else { buffer.fID = const_cast<TGeoVolume *>(paintVolume); buffer.fColor = paintVolume->GetLineColor(); buffer.fTransparency = paintVolume->GetTransparency(); Double_t visdensity = gGeoManager->GetVisDensity(); if (visdensity>0 && paintVolume->GetMedium()) { if (paintVolume->GetMaterial()->GetDensity() < visdensity) { buffer.fTransparency = 90; } } } buffer.fLocalFrame = localFrame; Bool_t r1,r2=kFALSE; r1 = gGeoManager->IsMatrixReflection(); if (paintVolume && paintVolume->GetShape()) { if (paintVolume->GetShape()->IsReflected()) { // Temporary trick to deal with reflected shapes. // Still lighting gets wrong... if (buffer.Type() < TBuffer3DTypes::kTube) r2 = kTRUE; } } buffer.fReflection = ((r1&(!r2))|(r2&!(r1))); // Set up local -> master translation matrix if (localFrame) { TGeoMatrix * localMasterMat = 0; if (TGeoShape::GetTransform()) { localMasterMat = TGeoShape::GetTransform(); } else { localMasterMat = gGeoManager->GetCurrentMatrix(); // For overlap drawing the correct matrix needs to obtained in // from GetGLMatrix() - this should not be applied in the case // of composite shapes if (gGeoManager->IsMatrixTransform() && !IsComposite()) { localMasterMat = gGeoManager->GetGLMatrix(); } } if (!localMasterMat) { R__ASSERT(kFALSE); return; } localMasterMat->GetHomogenousMatrix(buffer.fLocalMaster); } else { buffer.SetLocalMasterIdentity(); } buffer.SetSectionsValid(TBuffer3D::kCore); } } //_____________________________________________________________________________ Int_t TGeoShape::GetBasicColor() const { // Get the basic color (0-7). Int_t basicColor = 0; // TODO: Check on sensible fallback if (gGeoManager) { const TGeoVolume * volume = gGeoManager->GetPaintVolume(); if (volume) { basicColor = ((volume->GetLineColor() %8) -1) * 4; if (basicColor < 0) basicColor = 0; } } return basicColor; } //_____________________________________________________________________________ const TBuffer3D &TGeoShape::GetBuffer3D(Int_t /*reqSections*/, Bool_t /*localFrame*/) const { // Stub implementation to avoid forcing implementation at this stage static TBuffer3D buffer(TBuffer3DTypes::kGeneric); Warning("GetBuffer3D", "this must be implemented for shapes in a TGeoPainter hierarchy. This will be come a pure virtual fn eventually."); return buffer; } //_____________________________________________________________________________ char *TGeoShape::GetPointerName() const { // Provide a pointer name containing uid. static char name[20]; Int_t uid = GetUniqueID(); if (uid) sprintf(name,"p%s_%i", GetName(),uid); else sprintf(name,"p%s", GetName()); return name; } //_____________________________________________________________________________ void TGeoShape::ExecuteEvent(Int_t event, Int_t px, Int_t py) { // Execute mouse actions on this shape. if (!gGeoManager) return; TVirtualGeoPainter *painter = gGeoManager->GetPainter(); painter->ExecuteShapeEvent(this, event, px, py); } //_____________________________________________________________________________ void TGeoShape::Draw(Option_t *option) { // Draw this shape. TVirtualGeoPainter *painter = gGeoManager->GetGeomPainter(); if (option && strlen(option) > 0) { painter->DrawShape(this, option); } else { painter->DrawShape(this, gEnv->GetValue("Viewer3D.DefaultDrawOption","")); } } //_____________________________________________________________________________ void TGeoShape::Paint(Option_t *option) { // Paint this shape. TVirtualGeoPainter *painter = gGeoManager->GetGeomPainter(); if (option && strlen(option) > 0) { painter->PaintShape(this, option); } else { painter->PaintShape(this, gEnv->GetValue("Viewer3D.DefaultDrawOption","")); } }