// @(#)root/gl:$Id$ // Author: Richard Maunder 25/05/2005 /************************************************************************* * Copyright (C) 1995-2004, Rene Brun and Fons Rademakers. * * All rights reserved. * * * * For the licensing terms see $ROOTSYS/LICENSE. * * For the list of contributors see $ROOTSYS/README/CREDITS. * *************************************************************************/ #ifndef ROOT_TGLBoundingBox #define ROOT_TGLBoundingBox #ifndef ROOT_TGLUtil #include "TGLUtil.h" #endif ////////////////////////////////////////////////////////////////////////// // // // TGLBoundingBox // // // // Concrete class describing an orientated (free) or axis aligned box // // of 8 verticies. Supports methods for setting aligned or orientated // // boxes, find volume, axes, extents, centers, face planes etc. // // Also tests for overlap testing of planes and other bounding boxes, // // with fast sphere approximation. // ////////////////////////////////////////////////////////////////////////// // TODO: Create more compact version + axis aligned version, both with lazy // sphere testing. class TGLBoundingBox { private: // Fields // Box vertices are indexed thus (OpenGL is left handed by default) // y // | // | // |________x // / 3-------2 // / /| /| // z 7-------6 | // | 0-----|-1 // |/ |/ // 4-------5 // // 0123 'far' face // 4567 'near' face // // This could be more compact: // For orientated box 3 vertices which form plane cutting box // diagonally (e.g. 0,5,6 or 1,3,6 etc) would fix in space. // For axis aligned 2 verticies would suffice. // Rest could be calculated on demand - however speed more important // than memory considerations TGLVertex3 fVertex[8]; //! the 8 bounding box vertices Double_t fVolume; //! box volume - cached for speed Double_t fDiagonal; //! max box diagonal - cached for speed TGLVector3 fAxes[3]; //! box axes in global frame - cached for speed TGLVector3 fAxesNorm[3];//! normalised box axes in global frame - cached for speed // Methods void UpdateCache(); Bool_t ValidIndex(UInt_t index) const { return (index < 8); } Double_t Min(UInt_t index) const; Double_t Max(UInt_t index) const; public: TGLBoundingBox(); TGLBoundingBox(const TGLVertex3 vertex[8]); TGLBoundingBox(const Double_t vertex[8][3]); TGLBoundingBox(const TGLVertex3 & lowVertex, const TGLVertex3 & highVertex); TGLBoundingBox(const TGLBoundingBox & other); virtual ~TGLBoundingBox(); // ClassDef introduces virtual fns // Set orientated box TGLBoundingBox & operator =(const TGLBoundingBox & other); void Set(const TGLVertex3 vertex[8]); void Set(const Double_t vertex[8][3]); void Set(const TGLBoundingBox & other); void SetEmpty(); // Set axis aligned box void SetAligned(const TGLVertex3 & lowVertex, const TGLVertex3 & highVertex); // axis aligned void SetAligned(UInt_t nbPnts, const Double_t * pnts); // axis aligned void MergeAligned(const TGLBoundingBox & other); void ExpandAligned(const TGLVertex3 & point); // Manipulation void Transform(const TGLMatrix & matrix); void Scale(Double_t factor); void Scale(Double_t xFactor, Double_t yFactor, Double_t zFactor); void Translate(const TGLVector3 & offset); // Single vertex accessors const TGLVertex3 & operator [] (UInt_t index) const; const TGLVertex3 & Vertex(UInt_t index) const; Double_t XMin() const { return Min(0); } Double_t XMax() const { return Max(0); } Double_t YMin() const { return Min(1); } Double_t YMax() const { return Max(1); } Double_t ZMin() const { return Min(2); } Double_t ZMax() const { return Max(2); } TGLVertex3 MinAAVertex() const; TGLVertex3 MaxAAVertex() const; // Multiple vertices accessors const TGLVertex3* Vertices() const; // All 8 box vertices Int_t NumVertices() const { return 8; } enum EFace { kFaceLowX, kFaceHighX, kFaceLowY, kFaceHighY, kFaceLowZ, kFaceHighZ, kFaceCount }; const std::vector & FaceVertices(EFace face) const; // 4 box face vertices // Other properties TGLVertex3 Center() const; TGLVector3 Extents() const; const TGLVector3 & Axis(UInt_t i, Bool_t normalised = kTRUE) const; Bool_t IsEmpty() const; Double_t Volume() const { return fVolume; } Double_t Diagonal() const { return fDiagonal; } void PlaneSet(TGLPlaneSet_t & planeSet) const; TGLPlane GetNearPlane() const; // Overlap testing Rgl::EOverlap Overlap(const TGLPlane & plane) const; Rgl::EOverlap Overlap(const TGLBoundingBox & box) const; void Draw(Bool_t solid = kFALSE) const; void Dump() const; ClassDef(TGLBoundingBox,0); // a 3D orientated bounding box }; //______________________________________________________________________________ inline TGLBoundingBox & TGLBoundingBox::operator =(const TGLBoundingBox & other) { // Check for self-assignment if (this != &other) { Set(other); } return *this; } //______________________________________________________________________________ inline const TGLVertex3 & TGLBoundingBox::operator [] (UInt_t index) const { return fVertex[index]; } //______________________________________________________________________________ inline const TGLVertex3 & TGLBoundingBox::Vertex(UInt_t index) const { return fVertex[index]; } //______________________________________________________________________________ inline const TGLVertex3* TGLBoundingBox::Vertices() const { return fVertex; } //______________________________________________________________________________ inline TGLVector3 TGLBoundingBox::Extents() const { // Return the local axis entents of the box return TGLVector3(Axis(0,kFALSE).Mag(), Axis(1,kFALSE).Mag(), Axis(2,kFALSE).Mag()); } //______________________________________________________________________________ inline TGLVertex3 TGLBoundingBox::Center() const { // Return the center vertex of the box return TGLVertex3((fVertex[0].X() + fVertex[6].X())/2.0, (fVertex[0].Y() + fVertex[6].Y())/2.0, (fVertex[0].Z() + fVertex[6].Z())/2.0); } //______________________________________________________________________________ inline const TGLVector3 & TGLBoundingBox::Axis(UInt_t i, Bool_t normalised) const { // Return a vector representing axis of index i (0:X, 1:Y, 2:Z). // Vector can be as-is (edge, magnitude == extent) or normalised (default) // y // | // | // |________x // / 3-------2 // / /| /| // z 7-------6 | // | 0-----|-1 // |/ |/ // 4-------5 // if (normalised) { return fAxesNorm[i]; } else { return fAxes[i]; } } //______________________________________________________________________________ inline Bool_t TGLBoundingBox::IsEmpty() const { // Return kTRUE if box has zero diagonal - kFALSE otherwise // TODO: Round errors - should have epsilon test return (Diagonal() == 0.0); } #endif // ROOT_TGLBoundingBox