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class TPainter3dAlgorithms: public TObject, public TAttLine, public TAttFill


Legos and Surfaces package

This package was originally written by Evgueni Tcherniaev from IHEP/Protvino.

The original Fortran implementation was adapted to HIGZ/PAW by Olivier Couet and Evgueni Tcherniaev.

This class is a subset of the original system. It has been converted to a C++ class by Rene Brun.

 

Function Members (Methods)

public:
TPainter3dAlgorithms()
TPainter3dAlgorithms(const TPainter3dAlgorithms&)
TPainter3dAlgorithms(Double_t* rmin, Double_t* rmax, Int_t system = 1)
virtual~TPainter3dAlgorithms()
voidTObject::AbstractMethod(const char* method) const
virtual voidTObject::AppendPad(Option_t* option = "")
voidBackBox(Double_t ang)
virtual voidTObject::Browse(TBrowser* b)
static TClass*Class()
static TClass*TAttFill::Class()
static TClass*TAttLine::Class()
static TClass*TObject::Class()
virtual const char*TObject::ClassName() const
virtual voidTObject::Clear(Option_t* = "")
voidClearRaster()
virtual TObject*TObject::Clone(const char* newname = "") const
voidColorFunction(Int_t nl, Double_t* fl, Int_t* icl, Int_t& irep)
virtual Int_tTObject::Compare(const TObject* obj) const
voidTAttFill::Copy(TAttFill& attfill) const
voidTAttLine::Copy(TAttLine& attline) const
virtual voidTObject::Copy(TObject& object) const
voidDefineGridLevels(Int_t ndivz)
virtual voidTObject::Delete(Option_t* option = "")MENU
Int_tTAttLine::DistancetoLine(Int_t px, Int_t py, Double_t xp1, Double_t yp1, Double_t xp2, Double_t yp2)
virtual Int_tTObject::DistancetoPrimitive(Int_t px, Int_t py)
virtual voidTObject::Draw(Option_t* option = "")
virtual voidTObject::DrawClass() constMENU
virtual TObject*TObject::DrawClone(Option_t* option = "") constMENU
voidDrawFaceGouraudShaded(Int_t* icodes, Double_t** xyz, Int_t np, Int_t* iface, Double_t* t)
voidDrawFaceMode1(Int_t* icodes, Double_t* xyz, Int_t np, Int_t* iface, Double_t* t)
voidDrawFaceMode2(Int_t* icodes, Double_t* xyz, Int_t np, Int_t* iface, Double_t* t)
voidDrawFaceMode3(Int_t* icodes, Double_t* xyz, Int_t np, Int_t* iface, Double_t* t)
voidDrawFaceMove1(Int_t* icodes, Double_t* xyz, Int_t np, Int_t* iface, Double_t* tt)
voidDrawFaceMove2(Int_t* icodes, Double_t* xyz, Int_t np, Int_t* iface, Double_t* tt)
voidDrawFaceMove3(Int_t* icodes, Double_t* xyz, Int_t np, Int_t* iface, Double_t* tt)
voidDrawFaceRaster1(Int_t* icodes, Double_t* xyz, Int_t np, Int_t* iface, Double_t* tt)
voidDrawFaceRaster2(Int_t* icodes, Double_t* xyz, Int_t np, Int_t* iface, Double_t* tt)
virtual voidTObject::Dump() constMENU
virtual voidTObject::Error(const char* method, const char* msgfmt) const
virtual voidTObject::Execute(const char* method, const char* params, Int_t* error = 0)
virtual voidTObject::Execute(TMethod* method, TObjArray* params, Int_t* error = 0)
virtual voidTObject::ExecuteEvent(Int_t event, Int_t px, Int_t py)
virtual voidTObject::Fatal(const char* method, const char* msgfmt) const
voidFillPolygon(Int_t n, Double_t* p, Double_t* f)
voidFillPolygonBorder(Int_t nn, Double_t* xy)
voidFindLevelLines(Int_t np, Double_t* f, Double_t* t)
virtual TObject*TObject::FindObject(const char* name) const
virtual TObject*TObject::FindObject(const TObject* obj) const
voidFindPartEdge(Double_t* p1, Double_t* p2, Double_t f1, Double_t f2, Double_t fmin, Double_t fmax, Int_t& kpp, Double_t* pp)
voidFindVisibleDraw(Double_t* r1, Double_t* r2)
voidFindVisibleLine(Double_t* p1, Double_t* p2, Int_t ntmax, Int_t& nt, Double_t* t)
voidFrontBox(Double_t ang)
virtual Option_t*TObject::GetDrawOption() const
static Long_tTObject::GetDtorOnly()
virtual Color_tTAttFill::GetFillColor() const
virtual Style_tTAttFill::GetFillStyle() const
virtual const char*TObject::GetIconName() const
virtual Color_tTAttLine::GetLineColor() const
virtual Style_tTAttLine::GetLineStyle() const
virtual Width_tTAttLine::GetLineWidth() const
virtual const char*TObject::GetName() const
virtual char*TObject::GetObjectInfo(Int_t px, Int_t py) const
static Bool_tTObject::GetObjectStat()
virtual Option_t*TObject::GetOption() const
virtual const char*TObject::GetTitle() const
virtual UInt_tTObject::GetUniqueID() const
voidGouraudFunction(Int_t ia, Int_t ib, Double_t* f, Double_t* t)
virtual Bool_tTObject::HandleTimer(TTimer* timer)
virtual ULong_tTObject::Hash() const
voidImplicitFunction(Double_t* rmin, Double_t* rmax, Int_t nx, Int_t ny, Int_t nz, const char* chopt)
virtual voidTObject::Info(const char* method, const char* msgfmt) const
virtual Bool_tTObject::InheritsFrom(const char* classname) const
virtual Bool_tTObject::InheritsFrom(const TClass* cl) const
voidInitMoveScreen(Double_t xmin, Double_t xmax)
voidInitRaster(Double_t xmin, Double_t ymin, Double_t xmax, Double_t ymax, Int_t nx, Int_t ny)
virtual voidTObject::Inspect() constMENU
voidTObject::InvertBit(UInt_t f)
virtual TClass*IsA() const
virtual TClass*TAttFill::IsA() const
virtual TClass*TAttLine::IsA() const
virtual TClass*TObject::IsA() const
virtual Bool_tTObject::IsEqual(const TObject* obj) const
virtual Bool_tTObject::IsFolder() const
Bool_tTObject::IsOnHeap() const
voidIsoSurface(Int_t ns, Double_t* s, Int_t nx, Int_t ny, Int_t nz, Double_t* x, Double_t* y, Double_t* z, const char* chopt)
virtual Bool_tTObject::IsSortable() const
virtual Bool_tTAttFill::IsTransparent() const
Bool_tTObject::IsZombie() const
voidLegoCartesian(Double_t ang, Int_t nx, Int_t ny, const char* chopt)
voidLegoCylindrical(Int_t iordr, Int_t na, Int_t nb, const char* chopt)
voidLegoFunction(Int_t ia, Int_t ib, Int_t& nv, Double_t* ab, Double_t* vv, Double_t* t)
voidLegoPolar(Int_t iordr, Int_t na, Int_t nb, const char* chopt)
voidLegoSpherical(Int_t ipsdr, Int_t iordr, Int_t na, Int_t nb, const char* chopt)
voidLightSource(Int_t nl, Double_t yl, Double_t xscr, Double_t yscr, Double_t zscr, Int_t& irep)
virtual voidTObject::ls(Option_t* option = "") const
voidLuminosity(Double_t* anorm, Double_t& flum)
voidMarchingCube(Double_t fiso, Double_t** p, Double_t* f, Double_t** g, Int_t& nnod, Int_t& ntria, Double_t** xyz, Double_t** grad, Int_t** itria)
voidMarchingCubeCase00(Int_t k1, Int_t k2, Int_t k3, Int_t k4, Int_t k5, Int_t k6, Int_t& nnod, Int_t& ntria, Double_t** xyz, Double_t** grad, Int_t** itria)
voidMarchingCubeCase03(Int_t& nnod, Int_t& ntria, Double_t** xyz, Double_t** grad, Int_t** itria)
voidMarchingCubeCase04(Int_t& nnod, Int_t& ntria, Double_t** xyz, Double_t** grad, Int_t** itria)
voidMarchingCubeCase06(Int_t& nnod, Int_t& ntria, Double_t** xyz, Double_t** grad, Int_t** itria)
voidMarchingCubeCase07(Int_t& nnod, Int_t& ntria, Double_t** xyz, Double_t** grad, Int_t** itria)
voidMarchingCubeCase10(Int_t& nnod, Int_t& ntria, Double_t** xyz, Double_t** grad, Int_t** itria)
voidMarchingCubeCase12(Int_t& nnod, Int_t& ntria, Double_t** xyz, Double_t** grad, Int_t** itria)
voidMarchingCubeCase13(Int_t& nnod, Int_t& ntria, Double_t** xyz, Double_t** grad, Int_t** itria)
voidMarchingCubeFindNodes(Int_t nnod, Int_t* ie, Double_t** xyz, Double_t** grad)
voidMarchingCubeMiddlePoint(Int_t nnod, Double_t** xyz, Double_t** grad, Int_t** it, Double_t* pxyz, Double_t* pgrad)
voidMarchingCubeSetTriangles(Int_t ntria, Int_t** it, Int_t** itria)
voidMarchingCubeSurfacePenetration(Double_t a00, Double_t a10, Double_t a11, Double_t a01, Double_t b00, Double_t b10, Double_t b11, Double_t b01, Int_t& irep)
voidTObject::MayNotUse(const char* method) const
virtual voidTAttFill::Modify()
virtual voidTAttLine::Modify()
voidModifyScreen(Double_t* r1, Double_t* r2)
virtual Bool_tTObject::Notify()
static voidTObject::operator delete(void* ptr)
static voidTObject::operator delete(void* ptr, void* vp)
static voidTObject::operator delete[](void* ptr)
static voidTObject::operator delete[](void* ptr, void* vp)
void*TObject::operator new(size_t sz)
void*TObject::operator new(size_t sz, void* vp)
void*TObject::operator new[](size_t sz)
void*TObject::operator new[](size_t sz, void* vp)
TPainter3dAlgorithms&operator=(const TPainter3dAlgorithms&)
TAttFill&TAttFill::operator=(const TAttFill&)
TAttLine&TAttLine::operator=(const TAttLine&)
TObject&TObject::operator=(const TObject& rhs)
virtual voidTObject::Paint(Option_t* option = "")
virtual voidTObject::Pop()
virtual voidTObject::Print(Option_t* option = "") const
virtual Int_tTObject::Read(const char* name)
virtual voidTObject::RecursiveRemove(TObject* obj)
virtual voidTAttFill::ResetAttFill(Option_t* option = "")
virtual voidTAttLine::ResetAttLine(Option_t* option = "")
voidTObject::ResetBit(UInt_t f)
virtual voidTObject::SaveAs(const char* filename = "", Option_t* option = "") constMENU
virtual voidTAttFill::SaveFillAttributes(ostream& out, const char* name, Int_t coldef = 1, Int_t stydef = 1001)
virtual voidTAttLine::SaveLineAttributes(ostream& out, const char* name, Int_t coldef = 1, Int_t stydef = 1, Int_t widdef = 1)
virtual voidTObject::SavePrimitive(basic_ostream<char,char_traits<char> >& out, Option_t* option = "")
voidTObject::SetBit(UInt_t f)
voidTObject::SetBit(UInt_t f, Bool_t set)
voidSetColorDark(Color_t color, Int_t n = 0)
voidSetColorMain(Color_t color, Int_t n = 0)
voidSetDrawFace(TPainter3dAlgorithms::DrawFaceFunc_t pointer)
virtual voidTObject::SetDrawOption(Option_t* option = "")MENU
static voidTObject::SetDtorOnly(void* obj)
static voidSetF3(TF3* f3)
static voidSetF3ClippingBoxOff()
static voidSetF3ClippingBoxOn(Double_t xclip, Double_t yclip, Double_t zclip)
virtual voidTAttFill::SetFillAttributes()MENU
virtual voidTAttFill::SetFillColor(Color_t fcolor)
virtual voidTAttFill::SetFillStyle(Style_t fstyle)
voidSetIsoSurfaceParameters(Double_t fmin, Double_t fmax, Int_t ncolor, Int_t ic1, Int_t ic2, Int_t ic3)
voidSetLegoFunction(TPainter3dAlgorithms::LegoFunc_t pointer)
virtual voidTAttLine::SetLineAttributes()MENU
virtual voidTAttLine::SetLineColor(Color_t lcolor)
virtual voidTAttLine::SetLineStyle(Style_t lstyle)
virtual voidTAttLine::SetLineWidth(Width_t lwidth)
voidSetMesh(Int_t mesh = 1)
static voidTObject::SetObjectStat(Bool_t stat)
voidSetSurfaceFunction(TPainter3dAlgorithms::SurfaceFunc_t pointer)
virtual voidTObject::SetUniqueID(UInt_t uid)
virtual voidShowMembers(TMemberInspector& insp, char* parent)
virtual voidTObject::ShowMembers(TMemberInspector& insp, char* parent)
voidSideVisibilityDecode(Double_t val, Int_t& iv1, Int_t& iv2, Int_t& iv3, Int_t& iv4, Int_t& iv5, Int_t& iv6, Int_t& ir)
voidSideVisibilityEncode(Int_t iopt, Double_t phi1, Double_t phi2, Double_t& val)
voidSpectrum(Int_t nl, Double_t fmin, Double_t fmax, Int_t ic, Int_t idc, Int_t& irep)
virtual voidStreamer(TBuffer& b)
virtual voidTAttLine::Streamer(TBuffer& b)
virtual voidTObject::Streamer(TBuffer& b)
voidStreamerNVirtual(TBuffer& b)
voidTAttFill::StreamerNVirtual(TBuffer& b)
voidTAttLine::StreamerNVirtual(TBuffer& b)
voidTObject::StreamerNVirtual(TBuffer& b)
voidSurfaceCartesian(Double_t ang, Int_t nx, Int_t ny, const char* chopt)
voidSurfaceCylindrical(Int_t iordr, Int_t na, Int_t nb, const char* chopt)
voidSurfaceFunction(Int_t ia, Int_t ib, Double_t* f, Double_t* t)
voidSurfacePolar(Int_t iordr, Int_t na, Int_t nb, const char* chopt)
voidSurfaceProperty(Double_t qqa, Double_t qqd, Double_t qqs, Int_t nnqs, Int_t& irep)
voidSurfaceSpherical(Int_t ipsdr, Int_t iordr, Int_t na, Int_t nb, const char* chopt)
virtual voidTObject::SysError(const char* method, const char* msgfmt) const
Bool_tTObject::TestBit(UInt_t f) const
Int_tTObject::TestBits(UInt_t f) const
voidTestEdge(Double_t del, Double_t** xyz, Int_t i1, Int_t i2, Int_t* iface, Double_t* abcd, Int_t& irep)
virtual voidTObject::UseCurrentStyle()
virtual voidTObject::Warning(const char* method, const char* msgfmt) const
virtual Int_tTObject::Write(const char* name = 0, Int_t option = 0, Int_t bufsize = 0)
virtual Int_tTObject::Write(const char* name = 0, Int_t option = 0, Int_t bufsize = 0) const
voidZDepth(Double_t** xyz, Int_t& nface, Int_t** iface, Double_t** dface, Double_t** abcd, Int_t* iorder)
protected:
virtual voidTObject::DoError(int level, const char* location, const char* fmt, va_list va) const
voidTObject::MakeZombie()

Data Members

private:
Double_tfAphi[183]
Int_tfColorBottom
Int_t*fColorDark
Int_tfColorLevel[258]Color levels corresponding to functions
Int_t*fColorMain
Int_tfColorTop
Double_tfD[2000]
Double_tfDX
Double_tfDXrast
Double_tfDYrast
G__p2memfuncfDrawFacepointer to face drawing function
Double_tfF8[8]
Double_tfFmaxIsoSurface maximum function value
Double_tfFminIsoSurface minimum function value
Double_tfFunLevel[257]Function levels corresponding to colors
Double_tfG8[8][3]
Int_tfIc1Base colour for the 1st Iso Surface
Int_tfIc2Base colour for the 2nd Iso Surface
Int_tfIc3Base colour for the 3rd Iso Surface
Int_tfIfrast
Int_tfJmask[30]
G__p2memfuncfLegoFunctionpointer to lego function
Int_tfLevelLine[200]
Int_tfLoff
Int_tfMask[465]
Int_tfMesh(=1 if mesh to draw, o otherwise)
Int_tfNStackNumber of histograms in the stack to be painted
Int_tfNT
Int_tfNcolorNumber of colours per Iso surface
Int_tfNlevelNumber of color levels
Int_tfNlines
Int_tfNqs
Int_tfNxrast
Int_tfNyrast
Double_tfP8[8][3]
Double_tfPlines[1200]
Double_tfQA
Double_tfQD
Double_tfQS
Int_t*fRasterpointer to raster buffer
Double_tfRmax[3]Upper limits of lego
Double_tfRmin[3]Lower limits of lego
G__p2memfuncfSurfaceFunctionpointer to surface function
Int_tfSystemCoordinate system
Double_tfT[200]
Double_tfU[2000]
Double_tfVls[12]
Double_tfX0
Double_tfXrast
Double_tfYdl
Double_tfYls[4]
Double_tfYrast
static TF3*fgCurrentF3Pointer to the 3D function to be paint.
static Int_tfgF3ClippingClipping box is off (0) or on (1)
static Double_tfgF3XClipClipping plne along X
static Double_tfgF3YClipClipping plne along Y
static Double_tfgF3ZClipClipping plne along Y

Class Charts

Inheritance Inherited Members Includes Libraries
Class Charts

Function documentation

TPainter3dAlgorithms()
 Lego default constructor
TPainter3dAlgorithms(Double_t* rmin, Double_t* rmax, Int_t system = 1)
 Normal default constructor

  rmin[3], rmax[3] are the limits of the lego object depending on
  the selected coordinate system
~TPainter3dAlgorithms()
 Lego default destructor
void BackBox(Double_t ang)
 Draw back surfaces of surrounding box

    Input  ANG     - angle between X and Y axis

           DRFACE(ICODES,XYZ,NP,IFACE,T) - routine for face drawing
             ICODES(*) - set of codes for this face
             NP        - number of nodes in face
             IFACE(NP) - face
             T(NP)     - additional function
void ClearRaster()
 Clear screen
void ColorFunction(Int_t nl, Double_t* fl, Int_t* icl, Int_t& irep)
 Set correspondance between function and color levels

    Input: NL        - number of levels
           FL(NL)    - function levels
           ICL(NL+1) - colors for levels

    Output: IREP     - reply: 0 O.K.
                             -1 error in parameters:
                         illegal number of levels
                         function levels must be in increasing order
                         negative color index
void DefineGridLevels(Int_t ndivz)
 Define the grid levels drawn in the background of surface and lego plots.
 The grid levels are aligned on the  Z axis' main tick marks.
void DrawFaceMode1(Int_t* icodes, Double_t* xyz, Int_t np, Int_t* iface, Double_t* t)
 Draw face - 1st variant

    Function: Draw face - 1st variant
              (2 colors: 1st for external surface, 2nd for internal)

    References: WCtoNDC

    Input: ICODES(*) - set of codes for the line (not used)
             ICODES(1) - IX
             ICODES(2) - IY
           XYZ(3,*)  - coordinates of nodes
           NP        - number of nodes
           IFACE(NP) - face
           T(NP)     - additional function defined on this face
                       (not used in this routine)
void DrawFaceMode2(Int_t* icodes, Double_t* xyz, Int_t np, Int_t* iface, Double_t* t)
 Draw face - 2nd option

    Function: Draw face - 2nd option
              (fill in correspondance with function levels)

    References: WCtoNDC, FillPolygon

    Input: ICODES(*) - set of codes for the line (not used)
             ICODES(1) - IX
             ICODES(2) - IY
           XYZ(3,*)  - coordinates of nodes
           NP        - number of nodes
           IFACE(NP) - face
           T(NP)     - additional function defined on this face
void DrawFaceMode3(Int_t* icodes, Double_t* xyz, Int_t np, Int_t* iface, Double_t* t)
 Draw face - 3rd option

    Function: Draw face - 3rd option
              (draw face for stacked lego plot)

    References: WCtoNDC

    Input: ICODES(*) - set of codes for the line
             ICODES(1) - IX coordinate of the line cell
             ICODES(2) - IY coordinate of the line cell
             ICODES(3) - lego number
             ICODES(4) - side: 1-face,2-right,3-back,4-left,
                               5-bottom, 6-top
             XYZ(3,*)  - coordinates of nodes
             NP        - number of nodes
             IFACE(NP) - face
             T(*)      - additional function (not used here)
void DrawFaceMove1(Int_t* icodes, Double_t* xyz, Int_t np, Int_t* iface, Double_t* tt)
 Draw face - 1st variant for "MOVING SCREEN" algorithm

    Function: Draw face - 1st variant for "MOVING SCREEN" algorithm
              (draw face with level lines)

    References: FindLevelLines, WCtoNDC,
                FindVisibleDraw, ModifyScreen

    Input: ICODES(*) - set of codes for the line (not used)
             ICODES(1) - IX
             ICODES(2) - IY
           XYZ(3,*)  - coordinates of nodes
           NP        - number of nodes
           IFACE(NP) - face
           TT(NP)    - additional function defined on this face
                       (not used in this routine)
void DrawFaceMove3(Int_t* icodes, Double_t* xyz, Int_t np, Int_t* iface, Double_t* tt)
 Draw face - 3rd variant for "MOVING SCREEN" algorithm

    Function: Draw face - 1st variant for "MOVING SCREEN" algorithm
              (draw level lines only)

    References: FindLevelLines, WCtoNDC,
                FindVisibleDraw, ModifyScreen

    Input: ICODES(*) - set of codes for the line (not used)
             ICODES(1) - IX
             ICODES(2) - IY
           XYZ(3,*)  - coordinates of nodes
           NP        - number of nodes
           IFACE(NP) - face
           TT(NP)    - additional function defined on this face
                       (not used in this routine)
void DrawFaceMove2(Int_t* icodes, Double_t* xyz, Int_t np, Int_t* iface, Double_t* tt)
 Draw face - 2nd variant for "MOVING SCREEN" algorithm

    Function: Draw face - 2nd variant for "MOVING SCREEN" algorithm
              (draw face for stacked lego plot)

    References: FindLevelLines, WCtoNDC,
                FindVisibleDraw, ModifyScreen

    Input: ICODES(*) - set of codes for the line (not used)
             ICODES(1) - IX
             ICODES(2) - IY
             ICODES(3) - line code (N of lego)
           XYZ(3,*)  - coordinates of nodes
           NP        - number of nodes
           IFACE(NP) - face
           TT(NP)    - additional function defined on this face
                       (not used in this routine)
void DrawFaceRaster1(Int_t* icodes, Double_t* xyz, Int_t np, Int_t* iface, Double_t* tt)
 Draw face - 1st variant for "RASTER SCREEN" algorithm

    Function: Draw face - 1st variant for "RASTER SCREEN" algorithm
              (draw face with level lines)

    References: FindLevelLines, WCtoNDC,
                FindVisibleLine, FillPolygonBorder

    Input: ICODES(*) - set of codes for the line (not used)
             ICODES(1) - IX
             ICODES(2) - IY
           XYZ(3,*)  - coordinates of nodes
           NP        - number of nodes
           IFACE(NP) - face
           TT(NP)    - additional function defined on this face
                       (not used in this routine)
void DrawFaceRaster2(Int_t* icodes, Double_t* xyz, Int_t np, Int_t* iface, Double_t* tt)
 Draw face - 2nd variant for "RASTER SCREEN" algorithm

    Function: Draw face - 2nd variant for "RASTER SCREEN" algorithm
              (draw face for stacked lego plot)

    References: WCtoNDC, FindVisibleLine, FillPolygonBorder

    Input: ICODES(*) - set of codes for the line (not used)
             ICODES(1) - IX
             ICODES(2) - IY
             ICODES(3) - line code (N of lego)
           XYZ(3,*)  - coordinates of nodes
           NP        - number of nodes
           IFACE(NP) - face
           TT(NP)    - additional function defined on this face
                       (not used in this routine)
void FillPolygon(Int_t n, Double_t* p, Double_t* f)
 Fill polygon with function values at vertexes

    Input: N      - number of vertexes
           P(3,*) - polygon
           F(*)   - function values at nodes

    Errors: - illegal number of vertexes in polygon
            - illegal call of FillPolygon: no levels
void FillPolygonBorder(Int_t nn, Double_t* xy)
 Fill a polygon including border ("RASTER SCREEN")

    Input: NN      - number of polygon nodes
           XY(2,*) - polygon nodes
void FindLevelLines(Int_t np, Double_t* f, Double_t* t)
 Find level lines for face

    Input: NP      - number of nodes
           F(3,NP) - face
           T(NP)   - additional function

    Error: number of points for line not equal 2
void FindPartEdge(Double_t* p1, Double_t* p2, Double_t f1, Double_t f2, Double_t fmin, Double_t fmax, Int_t& kpp, Double_t* pp)
 Find part of edge

    Function: Find part of edge where function defined on this edge
              has value from FMIN to FMAX

    Input: P1(3) - 1st point
           P2(3) - 2nd point
           F1    - function value at 1st point
           F2    - function value at 2nd point
           FMIN  - min value of layer
           FMAX  - max value of layer

    Output: KPP - current number of point
            PP(3,*) - coordinates of new face
void FindVisibleDraw(Double_t* r1, Double_t* r2)
 Find visible parts of line (draw line)

    Input: R1(3)  - 1-st point of the line
           R2(3)  - 2-nd point of the line
void FindVisibleLine(Double_t* p1, Double_t* p2, Int_t ntmax, Int_t& nt, Double_t* t)
 Find visible part of a line ("RASTER SCREEN")

    Input: P1(2) - 1st point of the line
           P2(2) - 2nd point of the line
           NTMAX - max allowed number of visible segments

    Output: NT     - number of visible segments of the line
            T(2,*) - visible segments
void FrontBox(Double_t ang)
 Draw forward faces of surrounding box & axes

    Function: Draw forward faces of surrounding box & axes

    References: AxisVertex, Gaxis

    Input  ANG     - angle between X and Y axis

           DRFACE(ICODES,XYZ,NP,IFACE,T) - routine for face drawing
             ICODES(*) - set of codes for this face
             NP        - number of nodes in face
             IFACE(NP) - face
             T(NP)     - additional function
void GouraudFunction(Int_t ia, Int_t ib, Double_t* f, Double_t* t)
 Find part of surface with luminosity in the corners

              This routine is used for Gouraud shading
void InitMoveScreen(Double_t xmin, Double_t xmax)
 Initialize "MOVING SCREEN" method

    Input: XMIN - left boundary
           XMAX - right boundary
void InitRaster(Double_t xmin, Double_t ymin, Double_t xmax, Double_t ymax, Int_t nx, Int_t ny)
 Initialize hidden lines removal algorithm (RASTER SCREEN)

    Input: XMIN - Xmin in the normalized coordinate system
           YMIN - Ymin in the normalized coordinate system
           XMAX - Xmax in the normalized coordinate system
           YMAX - Ymax in the normalized coordinate system
           NX   - number of pixels along X
           NY   - number of pixels along Y
void LegoFunction(Int_t ia, Int_t ib, Int_t& nv, Double_t* ab, Double_t* vv, Double_t* t)
 Service function for Legos
void LegoCartesian(Double_t ang, Int_t nx, Int_t ny, const char* chopt)
 Draw stack of lego-plots in cartesian coordinates

    Input: ANG      - angle between X ang Y
           NX       - number of cells along X
           NY       - number of cells along Y

           FUN(IX,IY,NV,XY,V,T) - external routine
             IX     - X number of the cell
             IY     - Y number of the cell
             NV     - number of values for given cell
             XY(2,4)- coordinates of the cell corners
             V(NV)  - cell values
             T(4,NV)- additional function (for example: temperature)

           DRFACE(ICODES,XYZ,NP,IFACE,T) - routine for face drawing
             ICODES(*) - set of codes for this line
               ICODES(1) - IX
               ICODES(2) - IY
               ICODES(3) - IV
               ICODES(4) - side: 1-face,2-right,3-back,4-left,
                                 5-bottom, 6-top
               XYZ(3,*)  - coordinates of nodes
               NP        - number of nodes
               IFACE(NP) - face
                T(4)   - additional function (here Z-coordinate)

           CHOPT - options: 'BF' - from BACK to FRONT
                            'FB' - from FRONT to BACK


/* */
void LegoPolar(Int_t iordr, Int_t na, Int_t nb, const char* chopt)
 Draw stack of lego-plots in polar coordinates

    Input: IORDR - order of variables (0 - R,PHI; 1 - PHI,R)
           NA    - number of steps along 1st variable
           NB    - number of steps along 2nd variable

           FUN(IA,IB,NV,AB,V,TT) - external routine
             IA      - cell number for 1st variable
             IB      - cell number for 2nd variable
             NV      - number of values for given cell
             AB(2,4) - coordinates of the cell corners
             V(NV)   - cell values
             TT(4,*) - additional function

           DRFACE(ICODES,XYZ,NP,IFACE,T) - routine for face drawing
             ICODES(*) - set of codes for this face
               ICODES(1) - IA
               ICODES(2) - IB
               ICODES(3) - IV
               ICODES(4) - side: 1-internal,2-right,3-external,4-left
                                 5-bottom, 6-top
             XYZ(3,*)  - coordinates of nodes
             NP        - number of nodes in face
             IFACE(NP) - face
             T(NP)     - additional function

            CHOPT       - options: 'BF' - from BACK to FRONT
                                  'FB' - from FRONT to BACK


/* */
void LegoCylindrical(Int_t iordr, Int_t na, Int_t nb, const char* chopt)
 Draw stack of lego-plots in cylindrical coordinates

    Input: IORDR - order of variables (0 - Z,PHI; 1 - PHI,Z)
           NA    - number of steps along 1st variable
           NPHI  - number of steps along 2nd variable

           FUN(IA,IB,NV,AB,V,TT) - external routine
             IA      - cell number for 1st variable
             IB      - cell number for 2nd variable
             NV      - number of values for given cell
             AB(2,4) - coordinates of the cell corners
             V(NV)   - cell values
             TT(4,*) - additional function

           DRFACE(ICODES,XYZ,NP,IFACE,T) - routine for face drawing
             ICODES(*) - set of codes for this face
               ICODES(1) - IA
               ICODES(2) - IB
               ICODES(3) - IV
               ICODES(4) - side: 1,2,3,4 - ordinary sides
                                 5-bottom,6-top
             XYZ(3,*)  - coordinates of nodes
             NP        - number of nodes in face
             IFACE(NP) - face
             T(NP)     - additional function

           CHOPT       - options: 'BF' - from BACK to FRONT
                                  'FB' - from FRONT to BACK


/* */
void LegoSpherical(Int_t ipsdr, Int_t iordr, Int_t na, Int_t nb, const char* chopt)
 Draw stack of lego-plots spheric coordinates

    Input: IPSDR - pseudo-rapidity flag
           IORDR - order of variables (0 - THETA,PHI; 1 - PHI,THETA)
           NA    - number of steps along 1st variable
           NB    - number of steps along 2nd variable

           FUN(IA,IB,NV,AB,V,TT) - external routine
             IA      - cell number for 1st variable
             IB      - cell number for 2nd variable
             NV      - number of values for given cell
             AB(2,4) - coordinates of the cell corners
             V(NV)   - cell values
             TT(4,*) - additional function

           DRFACE(ICODES,XYZ,NP,IFACE,T) - routine for face drawing
             ICODES(*) - set of codes for this face
               ICODES(1) - IA
               ICODES(2) - IB
               ICODES(3) - IV
               ICODES(4) - side: 1,2,3,4 - ordinary sides
                                 5-bottom,6-top
             XYZ(3,*)  - coordinates of nodes
             NP        - number of nodes in face
             IFACE(NP) - face
             T(NP)     - additional function

           CHOPT       - options: 'BF' - from BACK to FRONT
                                  'FB' - from FRONT to BACK
void LightSource(Int_t nl, Double_t yl, Double_t xscr, Double_t yscr, Double_t zscr, Int_t& irep)
 Set light source

    Input: NL   - source number: -1 off all light sources
                                  0 set diffused light
           YL   - intensity of the light source
           XSCR |
           YSCR  > direction of the light (in respect of the screen)
           ZSCR |

    Output: IREP   - reply : 0 - O.K.
                            -1 - error in light sources definition:
                                 negative intensity
                                 source number greater than max
                                 light source is placed at origin
void Luminosity(Double_t* anorm, Double_t& flum)
 Find surface luminosity at given point
                                         --
    Lightness model formula: Y = YD*QA + > YLi*(QD*cosNi+QS*cosRi)
                                         --

            B1     = VN(3)*VL(2) - VN(2)*VL(3)
            B2     = VN(1)*VL(3) - VN(3)*VL(1)
            B3     = VN(2)*VL(1) - VN(1)*VL(2)
            B4     = VN(1)*VL(1) + VN(2)*VL(2) + VN(3)*VL(3)
            VR(1)  = VN(3)*B2 - VN(2)*B3 + VN(1)*B4
            VR(2)  =-VN(3)*B1 + VN(1)*B3 + VN(2)*B4
            VR(3)  = VN(2)*B1 - VN(1)*B2 + VN(3)*B4
            S      = SQRT(VR(1)*VR(1)+VR(2)*VR(2)+VR(3)*VR(3))
            VR(1)  = VR(1)/S
            VR(2)  = VR(2)/S
            VR(3)  = VR(3)/S
            COSR   = VR(1)*0. + VR(2)*0. + VR(3)*1.

    References: WCtoNDC

    Input: ANORM(3) - surface normal at given point

    Output: FLUM - luminosity
void ModifyScreen(Double_t* r1, Double_t* r2)
 Modify SCREEN

    Input: R1(3) - 1-st point of the line
           R2(3) - 2-nd point of the line
void SetDrawFace(TPainter3dAlgorithms::DrawFaceFunc_t pointer)
 Store pointer to current algorithm to draw faces
void SetLegoFunction(TPainter3dAlgorithms::LegoFunc_t pointer)
 Store pointer to current lego function
void SetSurfaceFunction(TPainter3dAlgorithms::SurfaceFunc_t pointer)
 Store pointer to current surface function
void SetF3(TF3* f3)
 Static function
 Store pointer to current implicit function
void SetF3ClippingBoxOff()
 static function
 Set the implicit function clipping box "off".
void SetF3ClippingBoxOn(Double_t xclip, Double_t yclip, Double_t zclip)
 static function
 Set the implicit function clipping box "on" and define the clipping box.
 xclip, yclip and zclip is a point within the function range. All the
 function value having x<=xclip and y<=yclip and z>=zclip are clipped.
void SetColorDark(Color_t color, Int_t n = 0)
 Store dark color for stack number n
void SetColorMain(Color_t color, Int_t n = 0)
 Store color for stack number n
void SideVisibilityDecode(Double_t val, Int_t& iv1, Int_t& iv2, Int_t& iv3, Int_t& iv4, Int_t& iv5, Int_t& iv6, Int_t& ir)
 Decode side visibilities and order along R for sector

    Input: VAL - encoded value

    Output: IV1 ... IV6  - visibility of the sides
            IR           - increment along R
void SideVisibilityEncode(Int_t iopt, Double_t phi1, Double_t phi2, Double_t& val)
 Encode side visibilities and order along R for sector

    Input: IOPT - options: 1 - from BACK to FRONT 'BF'
                           2 - from FRONT to BACK 'FB'
           PHI1 - 1st phi of sector
           PHI2 - 2nd phi of sector

    Output: VAL - encoded value
void Spectrum(Int_t nl, Double_t fmin, Double_t fmax, Int_t ic, Int_t idc, Int_t& irep)
 Set Spectrum

    Input: NL   - number of levels
           FMIN - MIN function value
           FMAX - MAX function value
           IC   - initial color index (for 1st level)
           IDC  - color index increment

    Output: IREP - reply: 0 O.K.
                         -1 error in parameters
                            F_max less than F_min
                            illegal number of levels
                            initial color index is negative
                            color index increment must be positive
void SurfaceCartesian(Double_t ang, Int_t nx, Int_t ny, const char* chopt)
 Draw surface in cartesian coordinate system

    Input: ANG      - angle between X ang Y
           NX       - number of steps along X
           NY       - number of steps along Y

           FUN(IX,IY,F,T) - external routine
             IX     - X number of the cell
             IY     - Y number of the cell
             F(3,4) - face which corresponds to the cell
             T(4)   - additional function (for example: temperature)

           DRFACE(ICODES,XYZ,NP,IFACE,T) - routine for face drawing
             ICODES(*) - set of codes for this face
               ICODES(1) - IX
               ICODES(2) - IY
             NP        - number of nodes in face
             IFACE(NP) - face
             T(NP)     - additional function

           CHOPT - options: 'BF' - from BACK to FRONT
                            'FB' - from FRONT to BACK
void SurfaceFunction(Int_t ia, Int_t ib, Double_t* f, Double_t* t)
 Service function for Surfaces
void SurfacePolar(Int_t iordr, Int_t na, Int_t nb, const char* chopt)
 Draw surface in polar coordinates

    Input: IORDR - order of variables (0 - R,PHI, 1 - PHI,R)
           NA    - number of steps along 1st variable
           NB    - number of steps along 2nd variable

           FUN(IA,IB,F,T) - external routine
             IA     - cell number for 1st variable
             IB     - cell number for 2nd variable
             F(3,4) - face which corresponds to the cell
               F(1,*) - A
               F(2,*) - B
               F(3,*) - Z
             T(4)   - additional function (for example: temperature)

           DRFACE(ICODES,XYZ,NP,IFACE,T) - routine for face drawing
             ICODES(*) - set of codes for this face
               ICODES(1) - IA
               ICODES(2) - IB
             XYZ(3,*)  - coordinates of nodes
             NP        - number of nodes in face
             IFACE(NP) - face
             T(NP)     - additional function

           CHOPT       - options: 'BF' - from BACK to FRONT
                                  'FB' - from FRONT to BACK
void SurfaceCylindrical(Int_t iordr, Int_t na, Int_t nb, const char* chopt)
 Draw surface in cylindrical coordinates

    Input: IORDR - order of variables (0 - Z,PHI, 1 - PHI,Z)
           NA    - number of steps along 1st variable
           NB    - number of steps along 2nd variable

           FUN(IA,IB,F,T) - external routine
             IA     - cell number for 1st variable
             IB     - cell number for 2nd variable
             F(3,4) - face which corresponds to the cell
               F(1,*) - A
               F(2,*) - B
               F(3,*) - R
             T(4)   - additional function (for example: temperature)

           DRFACE(ICODES,XYZ,NP,IFACE,T) - routine for face drawing
             ICODES(*) - set of codes for this face
               ICODES(1) - IA
               ICODES(2) - IB
             XYZ(3,*)  - coordinates of nodes
             NP        - number of nodes in face
             IFACE(NP) - face
             T(NP)     - additional function

           CHOPT       - options: 'BF' - from BACK to FRONT
                                  'FB' - from FRONT to BACK


/* */
void SurfaceSpherical(Int_t ipsdr, Int_t iordr, Int_t na, Int_t nb, const char* chopt)
 Draw surface in spheric coordinates

    Input: IPSDR - pseudo-rapidity flag
           IORDR - order of variables (0 - THETA,PHI; 1 - PHI,THETA)
           NA    - number of steps along 1st variable
           NB    - number of steps along 2nd variable

           FUN(IA,IB,F,T) - external routine
             IA     - cell number for 1st variable
             IB     - cell number for 2nd variable
             F(3,4) - face which corresponds to the cell
               F(1,*) - A
               F(2,*) - B
               F(3,*) - R
             T(4)   - additional function (for example: temperature)

           DRFACE(ICODES,XYZ,NP,IFACE,T) - routine for face drawing
             ICODES(*) - set of codes for this face
               ICODES(1) - IA
               ICODES(2) - IB
             XYZ(3,*)  - coordinates of nodes
             NP        - number of nodes in face
             IFACE(NP) - face
             T(NP)     - additional function

           CHOPT       - options: 'BF' - from BACK to FRONT
                                  'FB' - from FRONT to BACK
void SurfaceProperty(Double_t qqa, Double_t qqd, Double_t qqs, Int_t nnqs, Int_t& irep)
 Set surface property coefficients

    Input: QQA  - diffusion coefficient for diffused light  [0.,1.]
           QQD  - diffusion coefficient for direct light    [0.,1.]
           QQS  - diffusion coefficient for reflected light [0.,1.]
           NNCS - power coefficient for reflected light     (.GE.1)

                                         --
    Lightness model formula: Y = YD*QA + > YLi*(QD*cosNi+QS*cosRi)
                                         --

    Output: IREP   - reply : 0 - O.K.
                            -1 - error in cooefficients
void ImplicitFunction(Double_t* rmin, Double_t* rmax, Int_t nx, Int_t ny, Int_t nz, const char* chopt)
 Draw implicit function FUN(X,Y,Z) = 0 in cartesian coordinates using
 hidden surface removal algorithm "Painter".

     Input: FUN      - external routine FUN(X,Y,Z)
            RMIN(3)  - min scope coordinates
            RMAX(3)  - max scope coordinates
            NX       - number of steps along X
            NY       - number of steps along Y
            NZ       - number of steps along Z

            DRFACE(ICODES,XYZ,NP,IFACE,T) - routine for face drawing
              ICODES(*) - set of codes for this face
                ICODES(1) - 1
                ICODES(2) - 1
                ICODES(3) - 1
              NP        - number of nodes in face
              IFACE(NP) - face
              T(NP)     - additional function (lightness)

            CHOPT - options: 'BF' - from BACK to FRONT
                             'FB' - from FRONT to BACK
void MarchingCube(Double_t fiso, Double_t** p, Double_t* f, Double_t** g, Int_t& nnod, Int_t& ntria, Double_t** xyz, Double_t** grad, Int_t** itria)
 Topological decider for "Marching Cubes" algorithm Find set of triangles
 aproximating the isosurface F(x,y,z)=Fiso inside the cube
 (improved version)

 Input: FISO   - function value for isosurface
        P(3,8) - cube vertexes
        F(8)   - function values at the vertexes
        G(3,8) - function gradients at the vertexes

 Output: NNOD       - number of nodes     (maximum 13)
         NTRIA      - number of triangles (maximum 12)
         XYZ(3,*)   - nodes
         GRAD(3,*)  - node normales       (not normalized)
         ITRIA(3,*) - triangles

void MarchingCubeCase00(Int_t k1, Int_t k2, Int_t k3, Int_t k4, Int_t k5, Int_t k6, Int_t& nnod, Int_t& ntria, Double_t** xyz, Double_t** grad, Int_t** itria)
 Consideration of trivial cases: 1,2,5,8,9,11,14

 Input: K1,...,K6 - edges intersected with isosurface

 Output: the same as for IHMCUB
void MarchingCubeCase03(Int_t& nnod, Int_t& ntria, Double_t** xyz, Double_t** grad, Int_t** itria)
 Consider case No 3

 Input: see common HCMCUB

 Output: the same as for IHMCUB
void MarchingCubeCase04(Int_t& nnod, Int_t& ntria, Double_t** xyz, Double_t** grad, Int_t** itria)
 Consider case No 4

 Input: see common HCMCUB

 Output: the same as for IHMCUB
void MarchingCubeCase06(Int_t& nnod, Int_t& ntria, Double_t** xyz, Double_t** grad, Int_t** itria)
 Consider case No 6

 Input: see common HCMCUB

 Output: the same as for IHMCUB
void MarchingCubeCase07(Int_t& nnod, Int_t& ntria, Double_t** xyz, Double_t** grad, Int_t** itria)
 Consider case No 7

 Input: see common HCMCUB

 Output: the same as for IHMCUB
void MarchingCubeCase10(Int_t& nnod, Int_t& ntria, Double_t** xyz, Double_t** grad, Int_t** itria)
 Consider case No 10

 Input: see common HCMCUB

 Output: the same as for IHMCUB
void MarchingCubeCase12(Int_t& nnod, Int_t& ntria, Double_t** xyz, Double_t** grad, Int_t** itria)
 Consider case No 12

 Input: see common HCMCUB

 Output: the same as for IHMCUB
void MarchingCubeCase13(Int_t& nnod, Int_t& ntria, Double_t** xyz, Double_t** grad, Int_t** itria)
 Consider case No 13

 Input: see common HCMCUB

 Output: the same as for IHMCUB
void MarchingCubeSetTriangles(Int_t ntria, Int_t** it, Int_t** itria)
 Set triangles (if parameter IALL=1, all edges will be visible)

 Input: NTRIA   - number of triangles
        IT(3,*) - triangles

 Output: ITRIA(3,*) - triangles
void MarchingCubeMiddlePoint(Int_t nnod, Double_t** xyz, Double_t** grad, Int_t** it, Double_t* pxyz, Double_t* pgrad)
 Find middle point of a polygon

 Input: NNOD      - number of nodes in the polygon
        XYZ(3,*)  - node coordinates
        GRAD(3,*) - node normales
        IT(3,*)   - division of the polygons into triangles

 Output: PXYZ(3)  - middle point coordinates
         PGRAD(3) - middle point normale
void MarchingCubeSurfacePenetration(Double_t a00, Double_t a10, Double_t a11, Double_t a01, Double_t b00, Double_t b10, Double_t b11, Double_t b01, Int_t& irep)
 Check for surface penetration ("bottle neck")

 Input: A00,A10,A11,A01 - vertex values for 1st face
        B00,B10,B11,B01 - vertex values for opposite face

 Output: IREP - 1,2 - there is surface penetration
                0   - there is not surface penetration
void MarchingCubeFindNodes(Int_t nnod, Int_t* ie, Double_t** xyz, Double_t** grad)
 Find nodes and normales

 Input: NNOD  - number of nodes
        IE(*) - edges which have section node

 Output: XYZ(3,*)  - nodes
         GRAD(3,*) - node normales (not normalized)
void ZDepth(Double_t** xyz, Int_t& nface, Int_t** iface, Double_t** dface, Double_t** abcd, Int_t* iorder)
 Z-depth algorithm for set of triangles

 Input: XYZ(3,*)   - nodes
        NFACE      - number of triangular faces
        IFACE(3,*) - faces (triangles)

 Arrays: DFACE(6,*) - array for min-max scopes
         ABCD(4,*)  - array for face plane equations

 Output: IORDER(*) - face order
void TestEdge(Double_t del, Double_t** xyz, Int_t i1, Int_t i2, Int_t* iface, Double_t* abcd, Int_t& irep)
 Test edge against face (triangle)

 Input: DEL      - precision
        XYZ(3,*) - nodes
        I1       - 1-st node of edge
        I2       - 2-nd node of edge
        IFACE(3) - triangular face
        ABCD(4)  - face plane

 Output: IREP:-1 - edge under face
               0 - no decision
              +1 - edge before face
void IsoSurface(Int_t ns, Double_t* s, Int_t nx, Int_t ny, Int_t nz, Double_t* x, Double_t* y, Double_t* z, const char* chopt)
 Draw set of isosurfaces for a scalar function defined on a grid.

     Input: NS          - number of isosurfaces
            S(*)        - isosurface values
            NX          - number of slices along X
            NY          - number of slices along Y
            NZ          - number of slices along Z
            X(*)        - slices along X
            Y(*)        - slices along Y
            Z(*)        - slices along Z
            F(NX,NY,NZ) - function values <- Not used, current histo used instead

            DRFACE(ICODES,XYZ,NP,IFACE,T) - routine for face drawing
              ICODES(1) - isosurface number
              ICODES(2) - isosurface number
              ICODES(3) - isosurface number
              NP        - number of nodes in face
              IFACE(NP) - face
              T(NP)     - additional function (lightness)

            CHOPT - options: 'BF' - from BACK to FRONT
                             'FB' - from FRONT to BACK
void DrawFaceGouraudShaded(Int_t* icodes, Double_t** xyz, Int_t np, Int_t* iface, Double_t* t)
 Draw the faces for the Gouraud Shaded Iso surfaces
TPainter3dAlgorithms()
void SetIsoSurfaceParameters(Double_t fmin, Double_t fmax, Int_t ncolor, Int_t ic1, Int_t ic2, Int_t ic3)
{fFmin=fmin; fFmax=fmax; fNcolor=ncolor; fIc1=ic1; fIc2=ic2; fIc3=ic3;}
void SetMesh(Int_t mesh = 1)
{fMesh=mesh;}