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doc fixes
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2 changed files with 13 additions and 9 deletions
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@ -1405,8 +1405,9 @@ function polygon_area(poly, signed=false) =
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// Function: centroid()
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// Usage:
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// c = centroid(object);
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// c = centroid(object, [eps]);
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// Topics: Geometry, Polygons, Centroid
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// Description:
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// Given a simple 2D polygon, returns the 2D coordinates of the polygon's centroid.
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// Given a simple 3D planar polygon, returns the 3D coordinates of the polygon's centroid.
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// If you provide a non-planar or collinear polygon you will get an error. For self-intersecting
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@ -1415,6 +1416,9 @@ function polygon_area(poly, signed=false) =
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// If object is a manifold VNF then returns the 3d centroid of the polyhedron. The VNF must
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// describe a valid polyhedron with consistent face direction and no holes in the mesh; otherwise
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// the results are undefined.
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// Arguments:
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// object = object to compute the centroid of
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// eps = epsilon value for identifying degenerate cases
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function centroid(object,eps=EPSILON) =
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assert(is_finite(eps) && (eps>=0), "The tolerance should a non-negative value." )
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is_vnf(object) ? _vnf_centroid(object,eps)
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@ -1423,8 +1427,8 @@ function centroid(object,eps=EPSILON) =
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: assert(false, "Input must be a VNF, a region, or a 2D or 3D polygon");
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// Internal Function: _region_centroid()
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// Compute centroid of region
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/// Internal Function: _region_centroid()
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/// Compute centroid of region
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function _region_centroid(region,eps=EPSILON) =
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let(
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region=force_region(region),
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@ -1668,21 +1672,21 @@ function point_in_polygon(point, poly, nonzero=false, eps=EPSILON) =
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// color("lightblue") for(tri=tris) polygon(select(poly,tri));
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// color("blue") up(1) for(tri=tris) { stroke(select(poly,tri),.15,closed=true); }
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// color("magenta") up(2) stroke(poly,.25,closed=true);
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// color("black") up(3) vnf_debug([poly,[]],faces=false,size=1);
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// color("black") up(3) vnf_debug([path3d(poly),[]],faces=false,size=1);
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// Example(2D,NoAxes): a polygon with a hole and one "contact" edge
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// poly = [ [-10,0], [10,0], [0,10], [-10,0], [-4,4], [4,4], [0,2], [-4,4] ];
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// tris = polygon_triangulate(poly);
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// color("lightblue") for(tri=tris) polygon(select(poly,tri));
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// color("blue") up(1) for(tri=tris) { stroke(select(poly,tri),.15,closed=true); }
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// color("magenta") up(2) stroke(poly,.25,closed=true);
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// color("black") up(3) vnf_debug([poly,[]],faces=false,size=1);
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// color("black") up(3) vnf_debug([path3d(poly),[]],faces=false,size=1);
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// Example(2D,NoAxes): a polygon with "touching" vertices and no holes
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// poly = [ [0,0], [5,5], [-5,5], [0,0], [-5,-5], [5,-5] ];
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// tris = polygon_triangulate(poly);
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// color("lightblue") for(tri=tris) polygon(select(poly,tri));
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// color("blue") up(1) for(tri=tris) { stroke(select(poly,tri),.15,closed=true); }
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// color("magenta") up(2) stroke(poly,.25,closed=true);
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// color("black") up(3) vnf_debug([poly,[]],faces=false,size=1);
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// color("black") up(3) vnf_debug([path3d(poly),[]],faces=false,size=1);
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// Example(2D,NoAxes): a polygon with "contact" edges and no holes
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// poly = [ [0,0], [10,0], [10,10], [0,10], [0,0], [3,3], [7,3],
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// [7,7], [7,3], [3,3] ];
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@ -1690,7 +1694,7 @@ function point_in_polygon(point, poly, nonzero=false, eps=EPSILON) =
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// color("lightblue") for(tri=tris) polygon(select(poly,tri));
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// color("blue") up(1) for(tri=tris) { stroke(select(poly,tri),.15,closed=true); }
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// color("magenta") up(2) stroke(poly,.25,closed=true);
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// color("black") up(3) vnf_debug([poly,[]],faces=false,size=1);
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// color("black") up(3) vnf_debug([path3d(poly),[]],faces=false,size=1);
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// Example(3D):
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// include <BOSL2/polyhedra.scad>
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// vnf = regular_polyhedron_info(name="dodecahedron",side=5,info="vnf");
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@ -93,8 +93,8 @@ function _is_cw(a,b,c,all) =
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// Returns a path as a list of indices into `points`.
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// When all==true, returns extra points that are on edges of the hull.
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// Arguments:
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// points - list of 2d points to get the hull of.
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// all - when true, includes all points on the edges of the convex hull. Default: false.
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// points = list of 2d points to get the hull of.
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// all = when true, includes all points on the edges of the convex hull. Default: false.
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// Example(2D):
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// pts = [[-10,-10], [0,10], [10,10], [12,-10]];
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// path = hull2d_path(pts);
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