/usr/share/povray-3.7/include/shapes3.inc is in povray-includes 1:3.7.0.0-8.
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licensed under the Creative Commons Attribution-ShareAlike 3.0 Unported License.
// To view a copy of this license, visit http://creativecommons.org/licenses/by-sa/3.0/ or send a
// letter to Creative Commons, 444 Castro Street, Suite 900, Mountain View, California, 94041, USA.
// Persistence of Vision Ray Tracer version 3.6 / 3.7 Include File
// file: shapes3.inc
// author: Friedrich A. Lohmueller, March-2013
//
// Description: This file contains macros for working with object shapes,
// as well as macros for creating shapes of special geometric objects.
//
// Segments of shapes
// #macro Segment_of_Object ( Segment_Object, Segment_Angle)
// #macro Segment_of_CylinderRing ( R_out, R_in, Height, Segment_Angle)
// #macro Segment_of_Torus ( R_major, R_minor, Segment_Angle)
//
// Angular shapes
// #macro Column_N (N, Radius_in, Height )
// #macro Column_N_AB (N, A, B, R_in)
// #macro Pyramid_N (N, Radius_in_1, Radius_in_2, Height )
// #macro Pyramid_N_AB(N, A, R_in_A, B, R_in_B)
//
// Facetted shapes
// #declare Egg (uses #macro Egg_Shape)
// #macro Facetted_Sphere (Quarter_Segments, Radial_Segments)
// #macro Facetted_Egg_Shape (Quarter_Segments, Radial_Segments, Lower_Scale, Upper_Scale)
// #macro Facetted_Egg(N_Quarter_Segments, N_Radial_Segments)
//
// Round shape
// #macro Egg_Shape (Lower_Scale, Upper_Scale)
//
// Wireframe shape
// #macro Ring_Sphere (Rmaj_H, Rmaj_V, Rmin_H, Rmin_V, Number_of_Rings_horizontal, Number_of_Rings_vertical)
//
// Rounded shapes
// #macro Round_Pyramid_N_out (N, A, CornerR_out_A, B, CornerR_out_B, R_Border, Filled, Merge )
// #macro Round_Pyramid_N_in (N, A, FaceR_in_A, B, FaceR_in_B, R_Border, Filled, Merge_On )
//
// #macro Round_Cylinder_Tube( A, B, R_major, R_minor, Filled, Merge)
// #macro Rounded_Tube( R_out, R_in, R_Border, Height, Merge)
// #macro Rounded_Tube_AB( A, B, R_out, R_in, R_Border, Merge)
//
// #macro Round_Conic_Torus( Center_Distance, R_upper, R_lower, R_Border, Merge)
// #macro Round_Conic_Prism( Center_Distance, R_upper, R_lower, Length_Zminus, R_Border, Merge)
// #macro Half_Hollowed_Rounded_Cylinder1( Length, R_out, R_border, BorderScale, Merge)
// #macro Half_Hollowed_Rounded_Cylinder2( Length, R_out, R_corner, R_border, BorderScale, Merge)
//
// #macro Round_N_Tube_Polygon (N, Tube_R, R_incircle, Edge_R, Filled, Merge)
//
//
//
//
//
// --------------------------------------------------------
#ifndef( Shapes3_Inc_Temp)
#declare Shapes3_Inc_Temp = version;
#version 3.6;
#ifdef(View_POV_Include_Stack)
#debug "including shapes3.inc\n"
#end
#ifndef ( SHAPES_INC_TEMP) //Shapes_Inc_Temp)
#include "shapes.inc"
#end
#ifndef ( TRANSFORMS_INC_TEMP )
#include "transforms.inc"
#end
#ifndef ( MATH_INC_TEMP )
#include "math.inc"
#end
#ifndef ( STRINGS_INC_TEMP)
#include "strings.inc"
#end
// -----------------------------------------------------------------------------------------
// -----------------------------------------------------------------------------------------
//-------------------------------------------------------------<<< macro Segment_of_Object()
#macro Segment_of_Object ( SEgment_OBject, Segment_Angle_)
// cuts out a segment of an shape object radial around y axis
// starting with the +x direction
// ----------------------------------------------------------------------------------
#local D = 0.000001; // just a little bit
#local Segment_Angle = Segment_Angle_;
#if (Segment_Angle = 0) #local Segment_Angle = D; #end
#if (abs(Segment_Angle) >= 360) #local Segment_Angle = mod (Segment_Angle, 360); #end
#local O_min = min_extent ( SEgment_OBject );
#local O_max = max_extent ( SEgment_OBject );
#local O_max_x = max (O_min.x, O_max.x);
#local O_max_z = max (O_min.z, O_max.z);
#local R_max = 1.5*max(O_max_x,O_max_z);
#if (Segment_Angle > 0)
#local Box_z = R_max+D;
#else
#local Box_z = -R_max+D;
#end
intersection{
object{ SEgment_OBject }
#if (abs(Segment_Angle) >= 180)
merge{
#end // then use merge!
box { <-R_max+D,O_min.y-D,0>,< R_max+D, O_max.y+D,-Box_z>
rotate<0,0,0>
}// end of box
box { <-R_max+D,O_min.y-D, Box_z>,< R_max+D, O_max.y+D,0>
rotate<0, Segment_Angle,0>
}// end of box
#if (abs(Segment_Angle) >= 180)
} // end of merge
#end // end of merge, if merge is used!
} // end of intersection
#end // end of macro -----------------------------------<<< end of macro Segment_of_Object()
// -----------------------------------------------------------------------------------------
// -----------------------------------------------------------------------------------------
// ------------------------------------------------------<<< macro Segment_of_CylinderRing()
#macro Segment_of_CylinderRing ( R_out, R_in, Height, Segment_Angle_)
// ------------------------------
#local D = 0.000001; // just a little bit
#local R_o = R_out;
#local R_i = R_in;
#local H = Height;
#local Segment_Angle = Segment_Angle_;
#if (H = 0 ) #local H = D; #end
#if (H < 0 ) #local D = -D; #end
#if (R_o < R_i) #local X=R_o; #local R_o=R_i; #local R_i=X; #end
#if (R_i <= 0) #local R_i = D; #end
#if (Segment_Angle < 0)
#local Negativ_Flag = 1;
#local Segment_Angle = -Segment_Angle;
#else
#local Negativ_Flag = 0;
#end
#if (Segment_Angle >= 360) #local Segment_Angle = mod (Segment_Angle, 360); #end
intersection{
cylinder { <0,0,0>,<0,H,0>, R_o
} // end of outer cylinder ----------
cylinder { <0,-D,0>,<0,H+D,0>, R_i
inverse
} // end of inner cylinder ----------
#if (Segment_Angle > 0) // ------------------------------------------------------
#if (Segment_Angle >= 180)
merge{
#end // then use merge!
box { <-R_o+D,-D,0>,< R_o+D, H+D, R_o+D>
rotate<0,0,0>
}// end of box
box { <-R_o+D,-D,-R_o+D>,< R_o+D, H+D,0>
rotate<0, Segment_Angle,0>
}// end of box
#if (Segment_Angle >= 180)
} // end of merge
#end // end of merge, if merge is used!
#if (Negativ_Flag = 1) rotate<0,-Segment_Angle,0> #end
scale<-1,1,-1>
#end // of "#if (Segment_Angle > 0)" --------------------------------------------
} // end of intersection
#end // end of macro -----------------------------<<< end of macro Segment_of_CylinderRing()
// -----------------------------------------------------------------------------------------
// -----------------------------------------------------------------------------------------
//--------------------------------------------------------------<<< macro Segment_of_Torus()
#macro Segment_of_Torus ( R_major_, R_minor_, Segment_Angle_)
//------------------------------------------------------------------------------------------
#local D = 0.000001;
#local R_major = R_major_;
#local R_minor = R_minor_;
#local Segment_Angle = Segment_Angle_;
#if (Segment_Angle < 0)
#local Negativ_Flag = 1;
#local Segment_Angle = -Segment_Angle;
#else
#local Negativ_Flag = 0;
#end
#if (Segment_Angle > 360) #local Segment_Angle = mod(Segment_Angle,360); #end
intersection{
torus { R_major, R_minor sturm }
#if (Segment_Angle > 180)
merge{
#end // use merge!
box { <-1,-1,0>,<1,1,1>
scale < R_major+R_minor+D, R_minor+D, R_major+R_minor+D>
}// end of box
box { <-1,-1,-1>,<1,1,0>
scale < R_major+R_minor+D, R_minor+D, R_major+R_minor+D>
rotate < 0,-Segment_Angle,0 >
}// end of box
#if (Segment_Angle > 180)
}
#end // end of merge, if merge is used!
#if (Negativ_Flag = 0) rotate<0,Segment_Angle,0> #end
} // end of intersection
#end // end of macro Torus_Segment( ... ) --------------<<< end of macro Segment_of_Torus()
// -----------------------------------------------------------------------------------------
//------------------------------------------------------------------------------ /////////
//----------------------------------------------------- Round_Tube_Polygon_N (...) macro
#macro Round_N_Tube_Polygon( // A round polygon tube ring with N corners, filled or not!
N_in, // number of corners
Tube_R_in, // tube radius
Base_Width_in, // R_incircle (center to edge middle)
Corner_R_in, // corner torus segment major radius
Filled, // 1 = filled, 0 = ring, filling percentage
Merge_On // 0 = union, 1 = merge
) //-----------------------------------------------
//---------------------------------------------------------------------------
#local D = 0.000001; // just a little bit
//---------------------------------------------------------------------------
// check inputs:
#local Corner_R = abs(Corner_R_in);
#local Base_Width = abs(Base_Width_in);
#if (Corner_R > Base_Width)
#local Corner_R=Base_Width;
#debug concat( "Attention: Corner radius > base width. Set corner radius = base width !","\n")
#end
#local N = N_in;
#if (int(N) != N ) #local N = int(N);
#debug concat( "Attention: Number of corners should be an integer!","\n")
#debug concat( " Number of corners set to int(number of corners)","\n")
#end
#if (N < 3 ) #local N = 3;
#debug concat( "Attention: Number of corners should be > 3. Set mumber of corners to 3 !","\n")
#end
#local Tube_R = Tube_R_in;
#if (Tube_R <= 0 )
#if (abs(Tube_R)<= 0.00001 )
#local Tube_R = 0.00001;
#else
#local Tube_R = abs(Tube_R);
#end
#debug concat( "Attention: Tube radius should > 0.00001. Tube radius set to max( abs(tube radius), 0.00001) !","\n")
#debug concat( " This could be unvisible in this scene !","\n")
#end
// --------------------------------------------------------------------------
#local Edge_Angle = 360/N ;
#local Linear_Half_Len = (Base_Width-Corner_R)*tan(radians(Edge_Angle/2));
//---------------------------------------------------------------------------
#local Edge_Part =
#if( Filled > 0)
#if( Merge_On = 1 )
merge{
#else
union{
#end // #if(Merge_On = 1 )
#end // #if(Filled > 0)
object{ Segment_of_Torus( Corner_R, Tube_R, -Edge_Angle)
rotate<-90,0,0> translate<Base_Width-Corner_R,Linear_Half_Len,0>
} // end of Torus_Segment(...)
#if( Filled > 0)
cylinder{ <0,0,-Tube_R*Filled>,<0,0,Tube_R*Filled>, Corner_R
translate<Base_Width-Corner_R,Linear_Half_Len,0>
}
}// end union or merge
#end // #if(Filled > 0)
//---------------------------------------------------------------------------
#if (Corner_R != Base_Width)
#local Linear_Part =
#if( Filled > 0)
#if( Merge_On = 1 )
merge{
#else
union{
#end // #if(Merge_On = 1 )
#end // #if(Filled > 0)
cylinder { <0,-Linear_Half_Len-D,0>,<0,Linear_Half_Len+D,0>,Tube_R
scale <1,1,1> rotate<0,0,0> translate<Base_Width,0,0>
} // end of cylinder
#if( Filled > 0)
// linear prism in z-direction: from ,to ,number of points (first = last)
prism{ -Tube_R*Filled-D ,Tube_R*Filled+D , 6
<-D, 0.00>, // first point
< Base_Width-Corner_R-D,-Linear_Half_Len-D>,
< Base_Width ,-Linear_Half_Len-D>,
< Base_Width , Linear_Half_Len+D>,
< Base_Width-Corner_R-D, Linear_Half_Len+D>,
<-D, 0.00> // last point = first point!!!!
rotate<-90,0,0> scale<1,1,-1> //turns prism in z direction! Don't change this line!
} // end of prism --------------------------------------------------------
}// end union or merge
#end // #if(Filled_On = 1)
#end // #if (Corner_R != Base_Width)
//---------------------------------------------------------------------------
#if (Corner_R != Base_Width)
#local One_Segment =
#if(Merge_On = 1 )
merge{
#else
union{
#end
object {Linear_Part}
object {Edge_Part}
translate<0,0,0>
} // end union or merge
#else
#local One_Segment =
object {Edge_Part}
#end
//---------------------------------------------------------------------------
// final union or merge
#if(Merge_On = 1 )
merge{
#else
union{
#end
#local Nr = 0; // start
#local EndNr = N; // end
#while (Nr< EndNr)
object{One_Segment rotate<0,0,Nr * 360/EndNr>}
#local Nr = Nr + 1; // next Nr
#end // --------------- end of loop
} // end union or merge
// --------------------------------------------------------------------------------------
#end// of macro ------------------------------------------------------// end of macro
// -----------------------------------------------------------------------------------------
// -----------------------------------------------------------------------------------------
// --------------------------------------------------------------------<<< macro Pyramid_N()
#macro Pyramid_N (N, Radius1, Radius2, Height )
// -----------------------------------------------------------------------------
#local D= 0.000001; // a little bit to avoid coincident surfaces in intersection
intersection{
#local Nr = 0; // start
#local EndNr = N; // end
#while (Nr< EndNr)
// linear prism in z-direction: from ,to ,number of points (first = last)
prism { -2.00 ,2.00 , 5
<-2.00, 0.00-Nr*D>,
< 1.00,0.00-Nr*D>,
< 0.00+Radius2/Radius1,1.00+Nr*D>,
<-2.00,1.00+Nr*D>,
<-2.00,0.00-Nr*D>
rotate<-90,0,0> scale<1,1,-1> //turns prism in z direction!
scale<Radius1+Nr*D,Height+Nr*D,Radius1+Nr*D>
rotate<0,Nr * 360/EndNr,0>
} // end of prism -------------------------------------------------------------
#local Nr = Nr + 1; // next Nr
#end // ---------------- end of loop
} // end of intersection
#end // ---------------------------<<< end of macro Pyramid_N (N, Radius1, Radius2, Height )
// -----------------------------------------------------------------------------------------
// -----------------------------------------------------------------------------------------
// -----------------------------------------------------------------<<< macro Pyramid_N_AB()
#macro Pyramid_N_AB (N, Point_A, Radius_A, Point_B, Radius_B )
// -----------------------------------------------------------------------------
#local A = Point_A;
#local B = Point_B;
#local AB = B-A;
#local H = vlength( AB); // pyramid height;
object{ Pyramid_N ( N, Radius_A, Radius_B, H )
Reorient_Trans(< 0,1,0>, AB ) // needs "transforms.inc":
translate A
} //
#end // -------------<<< end of macro Pyramid_N_AB(N, Point_A, Radius_A, Point_B, Radius_B )
// -----------------------------------------------------------------------------------------
// --------------------------------------------------------------------<<< macro Column_N()
#macro Column_N (N, Radius, Height )
//------------------------------------------------------------------
object{ Pyramid_N (N, Radius, Radius, Height )
}
#end // -------------------------------------<<< end of macro N_Column (N, Radius, Height )
// -----------------------------------------------------------------------------------------
// -----------------------------------------------------------------------------------------
// -----------------------------------------------------------------<<< macro Column_N_AB()
#macro Column_N_AB (N, Point_A, Point_B, Radius )
// -----------------------------------------------------------------------------
#local A = Point_A;
#local B = Point_B;
#local AB = B-A;
#local H = vlength( AB); // pyramid height;
object{ Pyramid_N ( N, Radius, Radius, H )
Reorient_Trans(< 0,1,0>, AB ) // needs "transforms.inc":
translate A
} //
#end // --------------------------<<< end of macro Column_N_AB(N, Point_A, Point_B, Radius )
// -----------------------------------------------------------------------------------------
// -----------------------------------------------------------------------------------------
// --------------------------------------------------------------------<<< macro Egg_Shape()
#macro Egg_Shape (Lower_Scale, Upper_Scale) //
// ------------------------------------------------------------
#local Egg_Lower_Part =
difference {
sphere{<0,0,0>,1 scale<1,Lower_Scale,1>}
box{<-1,0,-1>,<1,Lower_Scale,1>}
} //---------------------------------------
#local Egg_Upper_Part =
difference {
sphere {<0,0,0>,1 scale<1,Upper_Scale,1>}
box {<-1,-Upper_Scale,-1>,<1,0,1>}
}//---------------------------------------
//-------------------------------------------------------------
merge {
object {Egg_Upper_Part}
object {Egg_Lower_Part}
translate<0,Lower_Scale,0>
scale 2/(Lower_Scale+Upper_Scale)
} // end of merge ------------------------------------
#end //---------------------------------------------------------<<< end of macro Egg_Shape()
// -----------------------------------------------------------------------------------------
// -------------------------------------------------------- shape of simple egg: object Egg
#declare Egg = object { Egg_Shape (1.15,1.55)}
// ---------------------------------------------------------------<<< end of the object Egg
// -----------------------------------------------------------------------------------------
// --------------------------------------------------------------<<< macro Facetted_Sphere()
#macro Facetted_Sphere (Quarter_Meridian_Segments, Equatorial_Segments)
#local Facets_Silhouette =
prism {
-2 ,2 ,
2*Quarter_Meridian_Segments+4
< -2,-1.00>,
#local Nr = -Quarter_Meridian_Segments;
#local EndNr = Quarter_Meridian_Segments;
#while (Nr< EndNr+1)
#local Angle_degrees = Nr* 90/EndNr;
#local Angle_radians = radians(Angle_degrees);
< cos(Angle_radians) , sin(Angle_radians)>,
#local Nr = Nr + 1 ;
#end
< -2, 1>,
< -2,-1>
rotate<-90,0,0> scale<1,1,-1> //turns prism in z direction!
} // end of prism object ----------------------------------
intersection{
#local Nr = 0; // start
#local EndNr = Equatorial_Segments; // end
#while (Nr< EndNr)
object{ Facets_Silhouette rotate<0,Nr * 360/EndNr,0>}
#local Nr = Nr + 1; // next Nr
#end // --------------- end of loop
} // end of intersection
#end // --------------------------------------------------<<< end of macro Facetted_Sphere()
// -----------------------------------------------------------------------------------------
// -----------------------------------------------------------------------------------------
// -----------------------------------------------------------<<< macro Facetted_Egg_Shape()
#macro Facetted_Egg_Shape (Quarter_Segments, Radial_Segments, Lower_Scale, Upper_Scale)
//Facettierte_Kugel (Viertelskreis_Teilung, Radial_Teilung)
#local Facets_Silhouette =
union{
prism {
-2 ,2 , Quarter_Segments +4
< -2,-1.00>,
#local Nr = -Quarter_Segments;
#local EndNr = 0;
#while (Nr< EndNr+1)
#local Angle_degrees = Nr* 90/Quarter_Segments;
#local Angle_radians = radians(Angle_degrees);
< cos (Angle_radians) , sin (Angle_radians)> ,
#local Nr = Nr + 1 ;
#end
< -2, 0>,
< -2,-1.00>
rotate<-90,0,0> scale<1,1,-1> //turns prism in z direction! Don't change this line!
scale<1,Lower_Scale,1>
} // end of prism object ----------------------------------------------------------
prism {
-2 ,2 , Quarter_Segments+4
< -2, 0>,
#local Nr = 0;
#local EndNr = Quarter_Segments;
#while (Nr< EndNr+1)
#local Angle_degrees = Nr* 90/Quarter_Segments;
#local Angle_radians = radians(Angle_degrees);
< cos (Angle_radians) , sin (Angle_radians)> ,
#local Nr = Nr + 1 ;
#end
< -2, 1>,
< -2, 0>
rotate<-90,0,0> scale<1,1,-1> //turns prism in z direction!
scale<1,Upper_Scale,1>
} // end of prism object -------------------------------------------
}// end of union
intersection{
#local Nr = 0; // start
#local EndNr = Radial_Segments; // end
#while (Nr< EndNr)
object{ Facets_Silhouette rotate<0,Nr * 360/EndNr,0>}
#local Nr = Nr + 1; // next Nr
#end // --------------- end of loop
} // end of intersection
#end // ----------------------------------------------------<<<< end of macro Facetted_Egg()
// -----------------------------------------------------------------------------------------
// -----------------------------------------------------------------------------------------
// -----------------------------------------------------------------<<< macro Facetted_Egg()
#macro Facetted_Egg(N_Quarter_Segments, N_Radial_Segments)
object{ Facetted_Egg_Shape(N_Quarter_Segments, N_Radial_Segments, 1.15, 1.55)
translate < 0, 1.15, 0>
scale 2/(1.15 + 1.55)
}
#end
//------------------------------------------------------------<<<end of macro Facetted_Egg()
// -----------------------------------------------------------------------------------------
// -----------------------------------------------------------------------------------------
// ------------------------------------------------------------------<<< macro Ring_Sphere()
//Sphere with latitudes by steps in degrees - globus
#macro Ring_Sphere( Rmaj_H, Rmaj_V, Rmin_H, Rmin_V,
Number_of_Rings_horizontal, Number_of_Rings_vertical)
#if( (Rmin_H > 0) & (Number_of_Rings_horizontal > 0))
#local RingsH1 =
union{
#local AngleD = 180/ (Number_of_Rings_horizontal+1);
#local Nr = -90+AngleD; #local EndNr = 90; // --- start and end
// Nr = value of the angle
#while (Nr< EndNr)
#local RingR = Rmaj_H*cos(radians(Nr)); //sqrt( pow(R0,2) - pow((Nr*HDiff),2) );
#local RingH = Rmaj_H*sin(radians(Nr));
torus{RingR,Rmin_H scale <1,1,1>
rotate<0,0,0>
translate<0, RingH,0>}
#local Nr = Nr + AngleD;
#end // --------------- end of loop
} // -----------------
#end // of "#if ( (Rmin_H > 0) & (Number_of_Rings_horizontal > 0))"
#if ((Rmin_V > 0) &(Number_of_Rings_vertical > 0))
#local RingsV1 = // longitudes
union{
#local Nr = 0; #local EndNr = Number_of_Rings_vertical; // --- start and end
#while (Nr< EndNr)
torus{Rmaj_V-Rmin_V,Rmin_V scale <1,1,1>
rotate<90,0,0>
rotate<0, Nr*360/EndNr,0>}
#local Nr = Nr + 1;
#end // --------------- end of loop
} // ---------------------------------
#end // of "#if ((Rmin_V > 0) &(Number_of_Rings_vertical > 0))"
union{ #if ((Rmin_H > 0) & (Number_of_Rings_horizontal > 0)) object{ RingsH1} #end
#if ((Rmin_V > 0) & (Number_of_Rings_vertical > 0)) object{ RingsV1} #end
sphere{<0, Rmaj_H,0>,Rmin_H}
sphere{<0,-Rmaj_H,0>,Rmin_H}
}
#end // ------------------------------------------------------<<< end of macro Ring_Sphere()
// -----------------------------------------------------------------------------------------
// -----------------------------------------------------------------------------------------
// ---------------------------------------------------------<<< macro Round_Pyramid_N_in()
#macro Round_Pyramid_N_in ( // radius of the incircle radius
Number_of_Sidefaces, // >=3
Point_A, Radius_A_in, Point_B, Radius_B_in,// radii of edge middles (R_in_A,R_in_B)
Wire_Radius, // border radius (Fill_On = 1) or wire radius ( Fill_On = 0 )
Fill_On, // 1 = filled, 0 = wireframe,
Merge_On // 1 = use merge, 0 = use union
) // -------------------------------------------------
// -------------------------------------------
// calculating the radius of the circumcircle:
#local Half_Angle = 180/Number_of_Sidefaces;
#local R_out_A = Radius_A_in*sqrt( 1 + pow(tan(radians(Half_Angle)),2) ) ;
#local R_out_B = Radius_B_in*sqrt( 1 + pow(tan(radians(Half_Angle)),2) ) ;
// -------------------------------------------------------------
object{ Round_Pyramid_N_out ( // used radius of the circumcircle
Number_of_Sidefaces, // >=3
Point_A, R_out_A , Point_B, R_out_B,// radii of corner points (R_out_A,R_out_B)
Wire_Radius, // border radius (Fill_On = 1) or wire radius ( Fill_On = 0 )
Fill_On, // 1 = filled, 0 = wireframe,
Merge_On // 1 = use merge, 0 = use union
) // -------------------------------------------------
rotate<0,Half_Angle,0>
} // end of object
#end// -----------------------------------------------<<< end of macro Round_Pyramid_N_in()
// -----------------------------------------------------------------------------------------
// -----------------------------------------------------------------------------------------
// -----------------------------------------------------------------------------------------
// --------------------------------------------------------<<< macro Round_Pyramid_N_out()
#macro Round_Pyramid_N_out ( // used radius of the circumcircle
Number_of_Sidefaces, // >=3
Point_A, Radius_A, Point_B, Radius_B,// radii of corner points (R_out_A,R_out_B)
Wire_Radius, // border radius (Fill_On = 1) or wire radius ( Fill_On = 0 )
Fill_On, // 1 = filled, 0 = wireframe,
Merge_On // 1 = use merge, 0 = use union
) // -----------------------------------------------------------------------------
#local D = 0.000001;
#local N = Number_of_Sidefaces;
#local Rw = Wire_Radius;
#local A = Point_A;
#local B = Point_B;
#local AB = B-A;
#local Rc1= Radius_A-Rw; // base corner radius
#local Rc2= Radius_B-Rw; // top corner radius
#local H = vlength( AB)-2*Rw; // Pyramid_Height;
#if ( H <= 0 ) // ---------------------------
#debug "Warning: H must be > 0 "
#local H = 0 ;
#end // ----------------------------------------
#local D = 0.000001;
#if ( N < 3) #local N = 3; #end // 3 is minimum!!!
#if ( Rw = 0 ) #local Rw = D; #end
#if ( Rw < 0 ) #local Rw = abs(Rw) ; #end
#if ( Rc1 < 0 ) #local Rc1 = abs(Rc1) ; #end
#if ( Rc2 < 0 ) #local Rc2 = abs(Rc2) ; #end
// ---------------------------------------------------------------------------------------------------
#local Flip = 0;
#if ( Rc1 < Rc2 ) #local Delta_Xchange = Rc1; #local Rc1 = Rc2; #local Rc2 = Delta_Xchange;
#local Flip = 1;
#end // --------
// ---------------------------------------------------------------------------------------------------
// radii to middle of the horizontal edges
#local Re1 = Rc1*cos(radians(180/N));
#local Re2 = Rc2*cos(radians(180/N));
// length of the hor. edges:
#local HLe1 = Rc1*sin(radians(180/N)); // half length of base edge
#local HLe2 = Rc2*sin(radians(180/N)); // half length of top edge
//
#local P_Angle = degrees(atan2( H, (Re1-Re2))); // pending sides angle against vertical !!
// -----------------------------------------------------------
// wire radius depending relevant values
#local Rw_sin = Rw*sin(radians(P_Angle)); // side difference
#local Rw_cos = Rw*cos(radians(P_Angle)); // height diffence
//----------------------------------------------------------------------
// wireframe + filling ------------------------------------------------ global union
#if (Merge_On = 1)
merge{
#else
union{ // I
#end // of #if (Merge_On = 1) .............
//---------------------------- Wireframe
#if (Rc1 = 0 )
sphere{< 0, H, 0>,Rw } // only one base sphere
#end
#if (Rc2 = 0 )
sphere{< 0, H, 0>,Rw } // only one top sphere
#end
#local Nr = 0;
#while (Nr< N)
#if (Merge_On = 1) // Ia
merge{
#else
union{
#end // of "#if (Merge_On = 1)"
#if (Rc1 != 0 ) // else no base spheres and no base ring cylinders
sphere{< Rc1, 0, 0>,Rw} // base corner
cylinder {< 0, 0, -HLe1>, < 0, 0, HLe1>,Rw translate<Re1,0,0> rotate<0,-180/N,0 > } // lower sides hor.ring
#end
#if (H > 0)
#if (Rc2 != 0 ) // else no top sphere and no base ring cylinders
sphere{< Rc2, H, 0>,Rw} // top corner
cylinder {< 0, 0, -HLe2>, < 0, 0, HLe2>,Rw translate<Re2,H,0> rotate<0,-180/N,0 > } // upper sides hor.ring
#end
cylinder {< Rc1, 0, 0>,< Rc2, H, 0>,Rw } // side edge base to top
#end
rotate<0,Nr*360/N,0>
} // end of union or merge // Ia
#local Nr = Nr + 1;
#end // -------------------------- end of wire frame
// ---------------------------------------------------
#if (Fill_On = 1) // ------------------------ filling
#if (Merge_On = 1)
merge{ //II
#else
union{ //II
#end // of "#if (Merge_On = 1)"
#local Nr = 0;
#while (Nr< N)
#if (Merge_On = 1)
merge{ //III
#else
union{ //III
#end // of "#if (Merge_On = 1)"
intersection{
prism{ -Rw ,H+Rw , 4 // prism y
< Rw_sin+D , 0>,
< Re1+Rw_sin+D, HLe1>,
< Re1+Rw_sin+D,-HLe1>,
< Rw_sin+D , 0>
} // end of prism in y --------
prism{ -Rc1-D , Rc1+D, 5 // prism z
< 0 , Rw_cos>,
< Re1+Rw_sin , Rw_cos>,
< Re2+Rw_sin , H+Rw_cos>,
< 0 , H+Rw_cos>,
< 0 , Rw_cos>
rotate<-90,0,0> scale<1,1,-1>
} // end of prism ---------------
rotate<0,-180/N,0>
rotate<0,-Nr*360/N,0>
}// end of intersection
// inner between fillers, center to the corners:
prism{ -Rw_sin-D , Rw_sin+D, 5 // prism z
< -D ,Rw_cos -D>,
< Rc1 ,Rw_cos -D>,
< Rc2 ,Rw_cos +H +D>,
<-D ,Rw_cos +H +D>,
<-D ,Rw_cos -D>
rotate<-90,0,0> scale<1,1,-1> rotate<0,360/N/2,0>
rotate<0,-360/N/2 ,0>
rotate<0,-(Nr)*360/N,0>
} // end of prism -------------------------------------
}// end union/merge III
#local Nr = Nr + 1;
#end
// fillers cover and top ---------------------------------------
intersection{ // lower cover
#local Nr = 0;
#while (Nr< N)
box{ <-1.5*Rc1,-Rw-D*Nr,-Rc1-Rw_sin>, <Re1 ,Rw_cos+D+D*Nr, Rc1+Rw_sin>
rotate<0,(Nr+0.5)*360/N,0>}
#local Nr = Nr + 1;
#end
}// end of intersection
intersection{ // upper cover
#local Nr = 0;
#while (Nr< N)
box{<-1.5*Rc1,H-Rw,-Rc1>,<Re2,H+Rw-D*Nr, Rc1>
rotate<0,(Nr+0.5)*360/N,0>}
#local Nr = Nr + 1;
#end
}// end of intersection
}// end of union or merge // II
#end // of (Fill_On = 1) ---------- end of filling
translate<0,Rw,0>
#if (Flip = 1)
scale<1,-1,1> translate<0,H+2*Rw,0>
#end
Reorient_Trans(< 0,1,0>, AB ) // needs "transforms.inc":
translate A
} // end of global union
#end// ----------------------------------------------<<< end of macro Round_Pyramid_N_out()
// -----------------------------------------------------------------------------------------
// -----------------------------------------------------------------<<< macro Rounded_Tube()
#macro Rounded_Tube ( Tube_R_out__, // Tube radius outside
Tube_R_in__, // Tube inner radius
Border_R__, // border radius
Tube_Y__, // tube high
Merge_, // 0 = union, 1 = merge
) //----------------------------------------------------
// -------------------------------------------------------------------------
#local D = 0.000001; /// *Border_R__
#local Tube_R_out_ = Tube_R_out__;
#local Tube_R_in_ = Tube_R_in__;
#local Border_R_ = Border_R__;
#local Tube_Y_ = Tube_Y__;
// inner radius bigger than outer radius - exchange them
#if (Tube_R_in_ > Tube_R_out_)
#local Temporary_ = Tube_R_out_;
#local Tube_R_out_ = Tube_R_in_;
#local Tube_R_in_ = Temporary_;
#warning concat("\nTube inner radius > tube inner radius! \n Radii exchanged!")
#end
// too big border radii: reduce border radii.
#if ( Border_R_ >= min((Tube_Y_/2),(Tube_R_out_-Tube_R_in_) ))
#local Border_R_ = min((Tube_Y_/2),(Tube_R_out_-Tube_R_in_))-D;
#warning concat("\nTube height < 2*border radius! or
Difference of outer radius - inner radius < 2*border radius!
Border radius reduced!")
#end
#if (Merge_ = 1 )
merge{
#else
union {
#end
difference{ // outline
cylinder{<0,+Border_R_,0>,<0,Tube_Y_-Border_R_,0>,Tube_R_out_ }
cylinder{<0,-D ,0>,<0,Tube_Y_+D, 0>,Tube_R_in_ }
} // end of difference
difference{ // tween
cylinder{<0,0, 0>,<0,Tube_Y_ ,0>,Tube_R_out_-Border_R_}
cylinder{<0,-D,0>,<0,Tube_Y_+D,0>,Tube_R_in_ +Border_R_}
} // end of difference
torus{ Tube_R_out_-Border_R_, Border_R_ translate<0,Tube_Y_-Border_R_-D,0>}
torus{ Tube_R_out_-Border_R_, Border_R_ translate<0,0+Border_R_+D,0>}
torus{ Tube_R_in_ +Border_R_, Border_R_ translate<0,Tube_Y_-Border_R_-D,0>}
torus{ Tube_R_in_ +Border_R_, Border_R_ translate<0,0+Border_R_+D,0>}
} // end of merge or union
#end// of macro --------------------------------------------<<< end of macro Rounded_Tube()
// -----------------------------------------------------------------------------------------
// --------------------------------------------------------------<<< macro Rounded_Tube_AB()
#macro Rounded_Tube_AB ( Point_A, Point_B, Radius_out, Radius_in, Border_Radius, Merge)
// --------------------------------------------------------------
#local A = Point_A;
#local B = Point_B;
#local AB = B-A;
#local H = vlength( AB); // pyramid height;
object{ Rounded_Tube ( Radius_out, Radius_in, Border_Radius, H, Merge )
Reorient_Trans(< 0,1,0>, AB ) // needs "transforms.inc":
translate A
} //
#end // ------------<<< end of macro Rounded_Tube_AB(N, A, B, R_out, R_in, R_Border, Merge )
// -----------------------------------------------------------------------------------------
// ----------------------------------------------------------<<< macro Round_Cylinder_Tube()
#macro Round_Cylinder_Tube ( A, // starting point
B, // end point
Radius, // major radius
EdgeRadius, // minor radius
Filled, // if Filled = 1; otherwise: open tube
UseMerge // use merge for transparent materials
) //---------------------------------------------
//--------------------------------------------------------------------------
#local D = 0.00001;
#if( Filled = 0 )
difference{
#end
#if( UseMerge = 1 )
merge {
#else
union {
#end
#if( Radius<EdgeRadius ) // degenerated case
#warning "\nRound_Cylinder() macro called with Radius < EdgeRadius,\nresults may not be as expected\n"
#local AA = A + vnormalize(B - A)*Radius;
#local BB = B + vnormalize(A - B)*Radius;
cylinder {AA, BB, Radius}
sphere {0, Radius translate AA }
sphere {0, Radius translate BB }
#else // non-degenerated case
#local AA = A + vnormalize(B - A)*EdgeRadius;
#local BB = B + vnormalize(A - B)*EdgeRadius;
#if( Filled = 1 )
cylinder {A, B, Radius - EdgeRadius}
#end
cylinder {AA, BB, Radius}
torus {Radius - EdgeRadius, EdgeRadius translate y*EdgeRadius
Point_At_Trans(B - A)
translate A
}
torus {Radius - EdgeRadius, EdgeRadius translate y*(vlength(A - B) - EdgeRadius)
Point_At_Trans(B - A)
translate A
}
#end // end of degenerated by radius or not
} // end of union or merge
#if( Filled = 0) // A+D*(A-B), B+D*(B-A)
cylinder {A, B, Radius - 2*EdgeRadius}
}// end of difference
#end // of "#if( Filled = 0 )"
#end// of macro --------------------------------------<<< end of macro Round_Cylinder_Tube()
// -----------------------------------------------------------------------------------------
//-------------------------------------------------------------<<< macro Round_Conic_Torus()
#macro Round_Conic_Torus( C_distance_,// >0, vertical center distance of upper + lower torii
R_upper_, // >0, upper radius up by <0,C_distance,0>
R_lower_, // >0, lower radius on zero !!!
Border_R_, // max. = min(R_lower,R_upper)
Merge_On
) //------- looks in y+direction
//------------------------------------------------------------------
#local D = 0.000001; // just a little bit !!!
//------------------------------------------
#local C_distance = C_distance_;
#local R_upper = R_upper_;
#local R_lower = R_lower_;
#local Border_R = Border_R_;
//------------------------------------------
#if (C_distance = 0) #local C_distance = D;
#warning "\nRound_Conic_Torus() macro called with center distance = 0,\n center distance set to 0.000001 ! \n"
#end
#if (C_distance < 0) #local C_distance = abs(C_distance);
#warning "\nRound_Conic_Torus() macro called with center distance < 0,\n center distance set to abs(center distance) ! \n"
#end
#if (Border_R < 0 ) #local Border_R = abs( Border_R );
#warning "\nRound_Conic_Torus() macro called with border radius < 0,\n border radius set to abs(border radius) ! \n"
#end
#if (Border_R = 0 ) #local Border_R = 0.01;
#warning "\nRound_Conic_Torus() macro called with border radius = 0,\n border radius set to 0.001 ! \n"
#end
#if (Border_R > min(R_lower,R_upper) ) #local Border_R = min(R_lower,R_upper)+D;
#warning "\nRound_Conic_Torus() macro called with border radius > min(lower radius, upper radius),\n border radius set to min(lower radius, upper radius) + 0.000001 ! \n"
#end
#if (R_upper = 0) #local R_upper = 0.002;
#warning "\nRound_Conic_Torus() macro called with upper radius = 0,\n upper radius set to 0.002 ! \n"
#end
#if (R_upper < 0) #local R_upper = abs (R_upper);
#warning "\nRound_Conic_Torus() macro called with upper radius < 0,\n upper radius set to abs(upper radius) ! \n"
#end
#if (R_lower = 0) #local R_lower = 0.002;
#warning "\nRound_Conic_Torus() macro called with lower radius = 0,\n lower radius set to 0.002 ! \n"
#end
#if (R_lower < 0) #local R_lower = abs (R_upper);
#warning "\nRound_Conic_Torus() macro called with lower radius < 0,\n lower radius set to abs(lower radius) ! \n"
#end
//---------------------------------------------------------------------------------------------------
// exchange upper and lower for construction if necessary (later they will changed back!)
#if ( (R_upper >= R_lower) & (C_distance>0)) #local Ro = R_upper; #local Ru = R_lower; #local Flag=0;
#else #local Ro = R_lower; #local Ru = R_upper; #local Flag=1;
#end
//------------------------------------------------------
#local Side_Len = sqrt(pow(C_distance,2) - pow( (Ro-Ru),2) );
#local Side_Angle = degrees( atan( (Ro-Ru)/ Side_Len) );
#if ( Merge_On = 1 ) union{
#else merge{ #end
// +z /-z border cylinder pending
cylinder{< 0,0,-D>,<0,Side_Len,0>,Border_R translate<0,0,Ru> rotate< Side_Angle,0,0>}
cylinder{< 0,0,-D>,<0,Side_Len,0>,Border_R translate<0,0,Ru> rotate< Side_Angle,0,0> scale<1,1,-1>}
intersection{ // +z box pending
torus{ Ru, Border_R rotate<0,0,90> translate<0,0,0>}
box{< -Border_R-D,0,-Ru-Border_R-D>,<Border_R+D,Ru+Border_R+D,Ru+Border_R+D> rotate< Side_Angle,0,0> inverse}
box{< -Border_R-D,0,-Ru-Border_R-D>,<Border_R+D,Ru+Border_R+D,Ru+Border_R+D> rotate<-Side_Angle,0,0> inverse}
}// end inters
intersection{ // +z box pending
//union{
torus{ Ro, Border_R rotate<0,0,90> translate<0,C_distance,0>}
intersection{
box{< -Border_R-D,-Ro-Border_R-D,-Ro-Border_R-D>,<Border_R+D,0,Ro+Border_R+D> rotate< Side_Angle,0,0> }
box{< -Border_R-D,-Ro-Border_R-D,-Ro-Border_R-D>,<Border_R+D,0,Ro+Border_R+D> rotate<-Side_Angle,0,0> }
translate<0,C_distance,0> inverse}
}// end inters
//#end // of "#if ( Border_R > 0 )"
#if (Flag = 1) scale<1,-1,1> translate<0,C_distance,0> #end
rotate<0,90,0> // turn it in the xy-plane
} //end of union
#end// of macro ---------------------------------------<<< end of macro Round_Conic_Torus()
// -----------------------------------------------------------------------------------------
// ------------------------------------------------------------<<< macro Round_Conic_Prism()
#macro Round_Conic_Prism( C_distance_, // >0, vertical center distance of the upper and lower torii
R_upper_, // >0, upper radius up by <0,C_distance,0>
R_lower_, // >0, lower radius on zero !!!
Len_, // length in z-
Border_R_, //max. = min(R_lower,R_upper) 0 = without rounded borders
Merge_On
) //------- looks in y+direction
// -----------------------------------------------------------------------------------------
#local D = 0.000001; // just a little bit !!!
// ------------------------------------------
#local C_distance = C_distance_;
#local R_upper = R_upper_;
#local R_lower = R_lower_;
#local Len = Len_;
#local Border_R = Border_R_;
// ------------------------------------------
#if (C_distance = 0) #local C_distance = 0.001;
#warning "\nRound_Conic_Prism() macro called with center distance = 0,\n center distance set to 0.000001 ! \n"
#end
#if (C_distance < 0) #local C_distance = abs(C_distance);
#warning "\nRound_Conic_Prism() macro called with center distance < 0,\n center distance set to abs(center distance) ! \n"
#end
#if (Border_R < 0 ) #local Border_R = abs( Border_R );
#warning "\nRound_Conic_Prism() macro called with border radius < 0,\n border radius set to abs(border radius) ! \n"
#end
#if (Border_R = 0 ) // #local Border_R = 0.01;
// #warning "\nRound_Conic_Torus() macro called with border radius = 0,\n border radius set to 0.001 ! \n"
#end
#if (Border_R > min(R_lower,R_upper) ) #local Border_R = min(R_lower,R_upper)+D;
#warning "\nRound_Conic_Prism() macro called with border radius > min(lower radius, upper radius),\n border radius set to min(lower radius, upper radius) + 0.000001 ! \n"
#end
#if (R_upper = 0) #local R_upper = 0.0005;
#warning "\nRound_Conic_Prism() macro called with upper radius = 0,\n upper radius set to 0.0005 ! \n"
#end
#if (R_upper < 0) #local R_upper = abs (R_upper);
#warning "\nRound_Conic_Prism() macro called with upper radius < 0,\n upper radius set to abs(upper radius) ! \n"
#end
#if (R_lower = 0) #local R_lower = 0.0001;
#warning "\nRound_Conic_Prism() macro called with lower radius = 0,\n lower radius set to 0.0001 ! \n"
#end
#if (R_lower < 0) #local R_lower = abs (R_upper);
#warning "\nRound_Conic_Prism() macro called with lower radius < 0,\n lower radius set to abs(lower radius) ! \n"
#end
#if (Len < 0) #local Len = abs(Len);
#warning "\nRound_Conic_Prism() macro called with length in z+ = 0,\n length set to abs(length in z-) ! \n"
#end
#if (Len < 2*Border_R+D) #local Len = 2*Border_R+D;
#warning "\nRound_Conic_Prism() macro called with length <= 2*border radius,\n length set to 2*border radius+0.000001 ! \n"
#end
#if (Len = 0) #local Len = 2*Border_R+D;
#warning "\nRound_Conic_Prism() macro called with length in z- = 0,\n length set to 2*border radius+0.000001 ! \n"
#end
// ---------------------------------------------------------------------------------------------------
// ---------------------------------------------------------------------------------------------------
// exchange upper and lower for construction if necessary (later they will changed back!)
#if ( (R_upper >= R_lower) & (C_distance>0)) #local Ro = R_upper; #local Ru = R_lower; #local Flag=0;
#else #local Ro = R_lower; #local Ru = R_upper; #local Flag=1;
#end
// ----------------------------------------------------------------------------------------
#local Side_Len = sqrt(abs( pow(C_distance,2) - pow( ( abs(Ro-Ru)),2) ) );
#local Side_Angle = degrees( atan( abs((Ro-Ru))/ Side_Len) );
//----------------------------------------------------------------------------------------
#if ( Merge_On = 1 ) union{
#else merge{ #end
// around x-axis - turned later in z- direction
intersection{ // +z box pending
box{< Border_R,0,-1.1*Ro-D>,<Len-Border_R,Side_Len,-D> translate<0,0,Ru> rotate< Side_Angle,0,0>}
box{<-D,-Ro,-D>,<Len+D,C_distance+Ro,Ro+D>}
} //end of intersection
intersection{ // +z box pending
box{< Border_R,0,-1.1*Ro-D>,<Len-Border_R,Side_Len,-2*D> translate<0,0,Ru> rotate< Side_Angle,0,0>}
box{<-D,-Ro,-D>,<Len+D,C_distance+Ro,Ro+D>}
scale<1,1,-1>
} //end of intersection
cylinder{ <Border_R,0,0>,<Len-Border_R,0,0>,Ro translate<0,C_distance,0>}
cylinder{ <Border_R,0,0>,<Len-Border_R,0,0>,Ru translate<0,0,0>}
#if ( Border_R > 0 )
// inner boxes full lenght
intersection{ // +z box pending
box{< 0,0,-1.1*Ro-D>,<Len,Side_Len,D> translate<0,0,Ru-Border_R> rotate< Side_Angle,0,0>}
box{<-D,-Ro,0>,<Len+D,C_distance+Ro,Ro+D>}
} //end of intersection
intersection{ // +z box pending
box{< 0,0,-1.1*Ro-D>,<Len,Side_Len,0> translate<0,0,Ru-Border_R> rotate< Side_Angle,0,0>}
box{<-D,-Ro,-D>,<Len+D,C_distance+Ro,Ro+D>}
scale<1,1,-1>
} //end of intersection
// +z /-z border cylinder pending
cylinder{< 0,0,-D>,<0,Side_Len,0>,Border_R translate<Border_R,0,Ru-Border_R> rotate< Side_Angle,0,0>}
cylinder{< 0,0,-D>,<0,Side_Len,0>,Border_R translate<Border_R,0,Ru-Border_R> rotate< Side_Angle,0,0> scale<1,1,-1>}
cylinder{< 0,0,-D>,<0,Side_Len,0>,Border_R translate<Len-Border_R,0,Ru-Border_R> rotate< Side_Angle,0,0>}
cylinder{< 0,0,-D>,<0,Side_Len,0>,Border_R translate<Len-Border_R,0,Ru-Border_R> rotate< Side_Angle,0,0> scale<1,1,-1>}
torus{ Ro-Border_R, Border_R rotate<0,0,90> translate<Border_R,C_distance,0>}
torus{ Ru-Border_R, Border_R rotate<0,0,90> translate<Border_R,0,0>}
torus{ Ro-Border_R, Border_R rotate<0,0,90> translate<Len-Border_R,C_distance,0>}
torus{ Ru-Border_R, Border_R rotate<0,0,90> translate<Len-Border_R,0,0>}
cylinder{ <0,0,0>,<Len,0,0>,Ro-Border_R translate<0,C_distance,0>}
cylinder{ <0,0,0>,<Len,0,0>,Ru-Border_R translate<0,0,0>}
#end // of "#if ( Border_R > 0 )"
#if (Flag = 1) scale<1,-1,1> translate<0,C_distance,0> #end
rotate<0,90,0>
} //end of union
#end// of macro ---------------------------------------<<< end of macro Round_Conic_Prism()
// -----------------------------------------------------------------------------------------
// ----------------------------------------------<<< macro Half_Hollowed_Rounded_Cylinder1()
#macro Half_Hollowed_Rounded_Cylinder1(
Len_total_, // total_Lenght from end to end
R_out_, // outer radius
R_Border_, // border Radius < outer radius !!!
Border_Scale_y_, // ( >=0 ) 0 = no rounded borders!
Merge_On , // 0 = union, 1 = merge !
) //-----------------------------------------------
//------------------------------------------------------------------------------
#local D = 0.000001; // just a little bit !!!
//------------------------------------------
#local Len_total = Len_total_;
#local R_out = R_out_;
#local R_Border = R_Border_;
#local Border_Scale_y = Border_Scale_y_;
#if ( R_out < R_Border )
#warning "\nHalf_Hollowed_Rounded_Cylinder1() macro called with outer radius < border radius,\n radii exchanged ! \n"
#local Safe = R_Border;
#local R_Border = R_out;
#local R_out = Safe;
#end
#if ( R_out - R_Border <= 0 + D)
#warning "\nHalf_Hollowed_Rounded_Cylinder1() macro called with outer radius ~ border radius,\n border radius set to 0.00002 ! \n"
#local R_Border = 2*D
#end
#local R_in = R_out - R_Border ;
#if ( Len_total < 2*R_out )
#warning "\nHalf_Hollowed_Rounded_Cylinder1() macro called with total length < 2*outer radius,\n length increased to 2*outer radius. Results may not be as expected !\n"
#local Len_total = 2*R_out +D;
#end
#local Len = Len_total-2*R_out; // length of linear kernel
#local R_Border = (R_out-R_in)/2 ; // Radius of the upper borders
// -----------------------------------------------------------------
#if (Merge_On = 0)
union{
#else
merge{
#end
// hollow half rounded cylinder
difference{
#if (Merge_On = 0)
union{
#else
merge{
#end
cylinder{ <-Len/2,0,0>,<Len/2,0,0>,R_out}
sphere{ <-Len/2,0,0>,R_out}
sphere{ < Len/2,0,0>,R_out}
}// end of union or merge
cylinder {<-Len/2,0,0>,<Len/2,0,0>,R_in}
sphere { <-Len/2,0,0>,R_in}
sphere { < Len/2,0,0>,R_in}
// cut off the upper part
box{ <-Len-R_out-D, D,-R_out-D>,
< Len+R_out+D, R_out+D, R_out+D>}
}
#if( Border_Scale_y > 0 )
// rounded borders
#if (Merge_On = 0)
union{
#else
merge{
#end
// side cylinders
difference {
cylinder{ <-Len/2-D,0, R_in + R_Border >,
< Len/2+D,0, R_in + R_Border >,
R_Border }
box{ <-Len-R_out-D,-R_Border-D,-R_out-D>
< Len+R_out+D, -D, R_out+D>}
}
difference {
cylinder{ <-Len/2-D,0,-R_in - R_Border >,
< Len/2+D,0,-R_in - R_Border >,
R_Border }
box{ <-Len-R_out-D,-R_Border-D,-R_out-D>
< Len+R_out+D, -D, R_out+D>}
}
// ending with half torii
difference {
union { //
torus{ R_in+R_Border,R_Border sturm
translate <-Len/2,0,0>
}
torus{ R_in+R_Border,R_Border sturm
translate < Len/2,0,0>
}
} // end of inner union
cylinder {<-Len/2+D,0,0>,<Len/2-D,0,0>,R_out+D}
box{ <-Len-R_out-D,-R_Border-D,-R_out-D>
< Len+R_out+D, -D, R_out+D>}
} // end of rounded borders base shape
scale <1,Border_Scale_y,1>
}// end borders
#end// of "#if( Border_Scale_y > 0 )"
} // end of union or merge
#end // of macro -----------------------<<< end of macro Half_Hollowed_Rounded_Cylinder1()
// -----------------------------------------------------------------------------------------
// ----------------------------------------------<<< macro Half_Hollowed_Rounded_Cylinder2()
#macro Half_Hollowed_Rounded_Cylinder2(
Len_total_, // total_Lenght from end to end
R_out_, // Radius_out, outer radius
R_End_, // < R_out ! > 2*R_Border
R_Border_, // border radius
Border_Scale_y_ // ( >0 ), 0 = no rounded borders
Merge_On, // 0 = union, 1 = merge !
) //-----------------------------------------------
// -----------------------------------------------------------------------------------------
#local D = 0.000001; // just a little bit !!!
// ------------------------------------------
#local Len_total = Len_total_;
#local R_out = R_out_;
#local R_End = R_End_;
#local R_Border = R_Border_;
#local Border_Scale_y = Border_Scale_y_;
#if ( R_End > Len_total/2 )
#warning "\nHalf_Rounded_Hollowed_Cylinder2() macro called with end radius < total lenght/2,\nresults may not be as expected\n"
#local R_End = Len_total/2-2*D;
#end
#if ( R_out < R_Border )
#warning "\nHalf_Hollowed_Rounded_Cylinder1() macro called with outer radius < border radius,\n radii exchanged ! \n"
#local Safe = R_Border;
#local R_Border = R_out;
#local R_out = Safe;
#end
#local Len = Len_total-2*R_End; // length of linear kernel
#local R_in = (R_out-2*R_Border) ; // Radius of the inner round cylindere
#local D_Corner = R_out - R_End;
// ------------------------------------------------------------------------------
#local Corner_Border =
intersection{
torus{ R_End-R_Border, R_Border sturm
}
box {<0,-D,0>,<R_End+D,R_Border+D,R_End+D> // +x +z corner
}
} // end intersection
// ------------------------------------------------------------------------------
#if (Merge_On = 0)
union{
#else
merge{
#end
// hollow rounded cylinder
difference{
object{ //Round_Cylinder(point A, point B, Radius, EdgeRadius, UseMerge)
Round_Cylinder(<-Len/2,0,0>, <Len/2,0,0>, R_out, R_End, Merge_On)
} // --------------------------------------------------------------
object{ //Round_Cylinder(point A, point B, Radius, EdgeRadius, UseMerge)
Round_Cylinder(<-Len/2+2*R_Border,0,0>, <Len/2-2*R_Border,0,0>,
R_in, R_End-2*R_Border, Merge_On)
translate<0,D,0>
} // --------------------------------------------------------------
// cut off the upper part
box{ <-Len-R_out-D, D,-R_out-D>,
< Len+R_out+D, R_out+D, R_out+D>}
}
#if( Border_Scale_y > 0 )
// rounded borders
difference { // with 1/4 torii in the corners
#if (Merge_On = 0)
union{
#else
merge{
#end
cylinder{ <-Len/2-D +R_End,0, R_in + R_Border >,
< Len/2+D -R_End,0, R_in + R_Border >,
R_Border }
cylinder{ <-Len/2-D +R_End,0,-R_in - R_Border >,
< Len/2+D -R_End,0,-R_in - R_Border >,
R_Border }
object{ Corner_Border translate<Len/2-R_End,0,D_Corner> }
object{ Corner_Border translate<Len/2-R_End,0,D_Corner> scale<-1,1, 1> }
object{ Corner_Border translate<Len/2-R_End,0,D_Corner> scale<-1,1,-1> }
object{ Corner_Border translate<Len/2-R_End,0,D_Corner> scale< 1,1,-1> }
cylinder{ <0,0, R_out-R_End +D >,
<0,0,-(R_out-R_End)-D >,
R_Border
translate <-Len/2+R_Border,0,0> }
cylinder{ <0,0, R_out-R_End +D >,
<0,0,-(R_out-R_End)-D >,
R_Border
translate < Len/2-R_Border,0,0> }
} // end inner union
box{ <-Len-R_out-D,-R_Border-D,-R_out-D>
< Len+R_out+D, -D, R_out+D>}
scale <1,Border_Scale_y,1>
}// end difference borders
#end// of "#if( Border_Scale_y > 0 )"
} // end of union or merge
#end // of macro ----------------------<<< end of macro Half_Hollowed_Rounded_Cylinder2()
// -----------------------------------------------------------------------------------------
// --------------------------------------------------------
// --------------------------------------------------------
#version Shapes3_Inc_Temp;
#end
// --------------------------------------------------------
//--------------------------------------------------------- end of include file shapes3.inc
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