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653 lines
21 KiB
OpenSCAD
653 lines
21 KiB
OpenSCAD
//////////////////////////////////////////////////////////////////////
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// LibFile: vnf.scad
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// VNF structures, holding Vertices 'N' Faces for use with `polyhedron().`
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// To use, add the following lines to the beginning of your file:
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// ```
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// use <BOSL2/std.scad>
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// use <BOSL2/vnf.scad>
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// ```
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//////////////////////////////////////////////////////////////////////
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include <triangulation.scad>
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// Section: Creating Polyhedrons with VNF Structures
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// VNF stands for "Vertices'N'Faces". VNF structures are 2-item lists, `[VERTICES,FACES]` where the
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// first item is a list of vertex points, and the second is a list of face indices into the vertex
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// list. Each VNF is self contained, with face indices referring only to its own vertex list.
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// You can construct a `polyhedron()` in parts by describing each part in a self-contained VNF, then
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// merge the various VNFs to get the completed polyhedron vertex list and faces.
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EMPTY_VNF = [[],[]]; // The standard empty VNF with no vertices or faces.
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// Function: is_vnf()
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// Description: Returns true if the given value looks passingly like a VNF structure.
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function is_vnf(x) = is_list(x) && len(x)==2 && is_list(x[0]) && is_list(x[1]) && (x[0]==[] || is_vector(x[0][0])) && (x[1]==[] || is_vector(x[1][0]));
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// Function: is_vnf_list()
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// Description: Returns true if the given value looks passingly like a list of VNF structures.
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function is_vnf_list(x) = is_list(x) && all([for (v=x) is_vnf(v)]);
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// Function: vnf_vertices()
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// Description: Given a VNF structure, returns the list of vertex points.
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function vnf_vertices(vnf) = vnf[0];
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// Function: vnf_faces()
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// Description: Given a VNF structure, returns the list of faces, where each face is a list of indices into the VNF vertex list.
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function vnf_faces(vnf) = vnf[1];
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// Function: vnf_quantize()
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// Usage:
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// vnf2 = vnf_quantize(vnf,[q]);
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// Description:
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// Quantizes the vertex coordinates of the VNF to the given quanta `q`.
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// Arguments:
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// vnf = The VNF to quantize.
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// q = The quanta to quantize the VNF coordinates to.
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function vnf_quantize(vnf,q=pow(2,-12)) =
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[[for (pt = vnf[0]) quant(pt,q)], vnf[1]];
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// Function: vnf_get_vertex()
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// Usage:
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// vvnf = vnf_get_vertex(vnf, p);
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// Description:
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// Finds the index number of the given vertex point `p` in the given VNF structure `vnf`. If said
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// point does not already exist in the VNF vertex list, it is added. Returns: `[INDEX, VNF]` where
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// INDEX if the index of the point, and VNF is the possibly modified new VNF structure.
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// If `p` is given as a list of points, then INDEX will be a list of indices.
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// Arguments:
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// vnf = The VNF structue to get the point index from.
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// p = The point, or list of points to get the index of.
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// Example:
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// vnf1 = vnf_get_vertex(p=[3,5,8]); // Returns: [0, [[[3,5,8]],[]]]
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// vnf2 = vnf_get_vertex(vnf1, p=[3,2,1]); // Returns: [1, [[[3,5,8],[3,2,1]],[]]]
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// vnf3 = vnf_get_vertex(vnf2, p=[3,5,8]); // Returns: [0, [[[3,5,8],[3,2,1]],[]]]
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// vnf4 = vnf_get_vertex(vnf3, p=[[1,3,2],[3,2,1]]); // Returns: [[1,2], [[[3,5,8],[3,2,1],[1,3,2]],[]]]
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function vnf_get_vertex(vnf=EMPTY_VNF, p) =
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is_path(p)? _vnf_get_vertices(vnf, p) :
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assert(is_vnf(vnf))
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assert(is_vector(p))
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let(
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v = search([p], vnf[0])[0]
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) [
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v != []? v : len(vnf[0]),
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[
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concat(vnf[0], v != []? [] : [p]),
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vnf[1]
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]
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];
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// Internal use only
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function _vnf_get_vertices(vnf=EMPTY_VNF, pts, _i=0, _idxs=[]) =
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_i>=len(pts)? [_idxs, vnf] :
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let(
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vvnf = vnf_get_vertex(vnf, pts[_i])
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) _vnf_get_vertices(vvnf[1], pts, _i=_i+1, _idxs=concat(_idxs,[vvnf[0]]));
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// Function: vnf_add_face()
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// Usage:
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// vnf_add_face(vnf, pts);
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// Description:
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// Given a VNF structure and a list of face vertex points, adds the face to the VNF structure.
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// Returns the modified VNF structure `[VERTICES, FACES]`. It is up to the caller to make
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// sure that the points are in the correct order to make the face normal point outwards.
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// Arguments:
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// vnf = The VNF structure to add a face to.
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// pts = The vertex points for the face.
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function vnf_add_face(vnf=EMPTY_VNF, pts) =
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assert(is_vnf(vnf))
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assert(is_path(pts))
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let(
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vvnf = vnf_get_vertex(vnf, pts),
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face = deduplicate(vvnf[0], closed=true),
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vnf2 = vvnf[1]
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) [
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vnf_vertices(vnf2),
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concat(vnf_faces(vnf2), len(face)>2? [face] : [])
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];
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// Function: vnf_add_faces()
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// Usage:
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// vnf_add_faces(vnf, faces);
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// Description:
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// Given a VNF structure and a list of faces, where each face is given as a list of vertex points,
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// adds the faces to the VNF structure. Returns the modified VNF structure `[VERTICES, FACES]`.
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// It is up to the caller to make sure that the points are in the correct order to make the face
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// normals point outwards.
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// Arguments:
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// vnf = The VNF structure to add a face to.
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// faces = The list of faces, where each face is given as a list of vertex points.
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function vnf_add_faces(vnf=EMPTY_VNF, faces, _i=0) =
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(assert(is_vnf(vnf)) assert(is_list(faces)) _i>=len(faces))? vnf :
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vnf_add_faces(vnf_add_face(vnf, faces[_i]), faces, _i=_i+1);
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// Function: vnf_merge()
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// Usage:
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// vnf = vnf_merge([VNF, VNF, VNF, ...]);
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// Description:
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// Given a list of VNF structures, merges them all into a single VNF structure.
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function vnf_merge(vnfs=[],_i=0,_acc=EMPTY_VNF) =
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(assert(is_vnf_list(vnfs)) _i>=len(vnfs))? _acc :
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vnf_merge(
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vnfs, _i=_i+1,
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_acc = let(base=len(_acc[0])) [
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concat(_acc[0], vnfs[_i][0]),
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concat(_acc[1], [for (f=vnfs[_i][1]) [for (i=f) i+base]]),
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]
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);
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// Function: vnf_compact()
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// Usage:
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// cvnf = vnf_compact(vnf);
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// Description:
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// Takes a VNF and consolidates all duplicate vertices, and drops unreferenced vertices.
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function vnf_compact(vnf) =
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let(
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verts = vnf[0],
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faces = [
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for (face=vnf[1]) [
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for (i=face) verts[i]
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]
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]
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) vnf_add_faces(faces=faces);
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// Function: vnf_triangulate()
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// Usage:
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// vnf2 = vnf_triangulate(vnf);
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// Description:
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// Forces triangulation of faces in the VNF that have more than 3 vertices.
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function vnf_triangulate(vnf) =
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let(
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vnf = is_vnf_list(vnf)? vnf_merge(vnf) : vnf
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) [vnf[0], triangulate_faces(vnf[0], vnf[1])];
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// Function: vnf_vertex_array()
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// Usage:
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// vnf = vnf_vertex_array(points, [caps], [cap1], [cap2], [reverse], [col_wrap], [row_wrap], [vnf]);
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// Description:
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// Creates a VNF structure from a vertex list, by dividing the vertices into columns and rows,
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// adding faces to tile the surface. You can optionally have faces added to wrap the last column
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// back to the first column, or wrap the last row to the first. Endcaps can be added to either
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// the first and/or last rows.
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// Arguments:
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// points = A list of vertices to divide into columns and rows.
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// caps = If true, add endcap faces to the first AND last rows.
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// cap1 = If true, add an endcap face to the first row.
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// cap2 = If true, add an endcap face to the last row.
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// col_wrap = If true, add faces to connect the last column to the first.
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// row_wrap = If true, add faces to connect the last row to the first.
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// reverse = If true, reverse all face normals.
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// style = The style of subdividing the quads into faces. Valid options are "default", "alt", and "quincunx".
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// vnf = If given, add all the vertices and faces to this existing VNF structure.
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// Example(3D):
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// vnf = vnf_vertex_array(
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// points=[
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// for (h = [0:5:180-EPSILON]) [
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// for (t = [0:5:360-EPSILON])
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// cylindrical_to_xyz(100 + 12 * cos((h/2 + t)*6), t, h)
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// ]
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// ],
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// col_wrap=true, caps=true, reverse=true, style="alt"
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// );
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// vnf_polyhedron(vnf);
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// Example(3D): Both `col_wrap` and `row_wrap` are true to make a torus.
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// vnf = vnf_vertex_array(
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// points=[
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// for (a=[0:5:360-EPSILON])
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// apply(
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// zrot(a) * right(30) * xrot(90),
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// path3d(circle(d=20))
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// )
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// ],
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// col_wrap=true, row_wrap=true, reverse=true
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// );
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// vnf_polyhedron(vnf);
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// Example(3D): Möbius Strip. Note that `row_wrap` is not used, and the first and last profile copies are the same.
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// vnf = vnf_vertex_array(
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// points=[
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// for (a=[0:5:360]) apply(
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// zrot(a) * right(30) * xrot(90) * zrot(a/2+60),
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// path3d(square([1,10], center=true))
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// )
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// ],
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// col_wrap=true, reverse=true
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// );
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// vnf_polyhedron(vnf);
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// Example(3D): Assembling a Polyhedron from Multiple Parts
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// wall_points = [
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// for (a = [-90:2:90]) apply(
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// up(a) * scale([1-0.1*cos(a*6),1-0.1*cos((a+90)*6),1]),
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// path3d(circle(d=100))
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// )
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// ];
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// cap = [
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// for (a = [0:0.01:1+EPSILON]) apply(
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// up(90-5*sin(a*360*2)) * scale([a,a,1]),
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// wall_points[0]
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// )
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// ];
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// cap1 = [for (p=cap) down(90, p=zscale(-1, p=p))];
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// cap2 = [for (p=cap) up(90, p=p)];
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// vnf1 = vnf_vertex_array(points=wall_points, col_wrap=true);
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// vnf2 = vnf_vertex_array(points=cap1, col_wrap=true);
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// vnf3 = vnf_vertex_array(points=cap2, col_wrap=true, reverse=true);
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// vnf_polyhedron([vnf1, vnf2, vnf3]);
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function vnf_vertex_array(
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points,
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caps, cap1, cap2,
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col_wrap=false,
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row_wrap=false,
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reverse=false,
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style="default",
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vnf=EMPTY_VNF
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) =
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assert((!caps)||(caps&&col_wrap))
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assert(in_list(style,["default","alt","quincunx"]))
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let(
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pts = flatten(points),
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pcnt = len(pts),
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rows = len(points),
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cols = len(points[0]),
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errchk = [for (row=points) assert(len(row)==cols, "All rows much have the same number of columns.") 0],
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cap1 = first_defined([cap1,caps,false]),
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cap2 = first_defined([cap2,caps,false]),
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colcnt = cols - (col_wrap?0:1),
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rowcnt = rows - (row_wrap?0:1)
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)
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vnf_merge([
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vnf, [
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concat(
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pts,
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style!="quincunx"? [] : [
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for (r = [0:1:rowcnt-1]) (
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for (c = [0:1:colcnt-1]) (
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let(
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i1 = ((r+0)%rows)*cols + ((c+0)%cols),
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i2 = ((r+1)%rows)*cols + ((c+0)%cols),
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i3 = ((r+1)%rows)*cols + ((c+1)%cols),
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i4 = ((r+0)%rows)*cols + ((c+1)%cols)
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) mean([pts[i1], pts[i2], pts[i3], pts[i4]])
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)
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)
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]
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),
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concat(
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[
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for (r = [0:1:rowcnt-1]) (
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for (c = [0:1:colcnt-1]) each (
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let(
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i1 = ((r+0)%rows)*cols + ((c+0)%cols),
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i2 = ((r+1)%rows)*cols + ((c+0)%cols),
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i3 = ((r+1)%rows)*cols + ((c+1)%cols),
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i4 = ((r+0)%rows)*cols + ((c+1)%cols)
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)
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style=="quincunx"? (
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let(i5 = pcnt + r*colcnt + c)
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reverse? [[i1,i2,i5],[i2,i3,i5],[i3,i4,i5],[i4,i1,i5]] : [[i1,i5,i2],[i2,i5,i3],[i3,i5,i4],[i4,i5,i1]]
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) : style=="alt"? (
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reverse? [[i1,i2,i4],[i2,i3,i4]] : [[i1,i4,i2],[i2,i4,i3]]
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) : (
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reverse? [[i1,i2,i3],[i1,i3,i4]] : [[i1,i3,i2],[i1,i4,i3]]
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)
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)
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)
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],
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!cap1? [] : [
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reverse?
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[for (c = [0:1:cols-1]) c] :
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[for (c = [cols-1:-1:0]) c]
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],
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!cap2? [] : [
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reverse?
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[for (c = [cols-1:-1:0]) (rows-1)*cols + c] :
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[for (c = [0:1:cols-1]) (rows-1)*cols + c]
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]
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)
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]
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]);
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// Module: vnf_polyhedron()
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// Usage:
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// vnf_polyhedron(vnf);
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// vnf_polyhedron([VNF, VNF, VNF, ...]);
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// Description:
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// Given a VNF structure, or a list of VNF structures, creates a polyhedron from them.
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// Arguments:
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// vnf = A VNF structure, or list of VNF structures.
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// convexity = Max number of times a line could intersect a wall of the shape.
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module vnf_polyhedron(vnf, convexity=2) {
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vnf = is_vnf_list(vnf)? vnf_merge(vnf) : vnf;
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polyhedron(vnf[0], vnf[1], convexity=convexity);
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}
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// Function: vnf_volume()
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// Usage:
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// vol = vnf_volume(vnf);
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// Description:
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// Returns the volume enclosed by the given manifold VNF. May return a negative value if faces are reversed.
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function vnf_volume(vnf) =
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let(vnf = vnf_triangulate(vnf))
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sum([
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for(face_index=vnf[1]) let(
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face = select(vnf[0], face_index),
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n = cross(face[2]-face[0],face[1]-face[0])
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) face[0] * n
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])/6;
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// Function: vnf_centroid()
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// Usage:
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// vol = vnf_centroid(vnf);
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// Description:
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// Returns the centroid of the given manifold VNF.
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function vnf_centroid(vnf) =
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let(
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vnf = vnf_triangulate(vnf),
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val=sum([
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for(face_index=vnf[1])
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let(
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face = select(vnf[0], face_index),
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n = cross(face[2]-face[0],face[1]-face[0])
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) [
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face[0] * n,
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vmul(n,
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vsqr(face[0] + face[1]) +
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vsqr(face[0] + face[2]) +
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vsqr(face[1] + face[2])
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)
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]
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])
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) val[1]/val[0]/8;
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// Function&Module: vnf_validate()
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// Usage: As Function
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// fails = vnf_validate(vnf);
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// Usage: As Module
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// vnf_validate(vnf);
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// Description:
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// When called as a function, returns a list of non-manifold errors with the given VNF.
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// Each error has the format `[ERR_OR_WARN,CODE,MESG,POINTS,COLOR]`.
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// When called as a module, echoes the non-manifold errors to the console, and color hilites the
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// bad edges and vertices, overlaid on a transparent gray polyhedron of the VNF.
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//
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// Currently checks for these problems:
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// Type | Color | Code | Message
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// ------- | -------- | ------------ | ---------------------------------
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// WARNING | Yellow | BIG_FACE | Face has more than 3 vertices, and may confuse CGAL
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// WARNING | Brown | NULL_FACE | Face has zero area
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// ERROR | Cyan | NONPLANAR | Face vertices are not coplanar
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// ERROR | Orange | OVRPOP_EDGE | Too many faces attached at edge
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// ERROR | Violet | REVERSAL | Faces reverse across edge
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// ERROR | Red | T_JUNCTION | Vertex is mid-edge on another Face
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// ERROR | Blue | FACE_ISECT | Faces intersect
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// ERROR | Magenta | HOLE_EDGE | Edge bounds Hole
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//
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// Still to implement:
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// - Overlapping coplanar faces.
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// Arguments:
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// vnf = The VNF to validate.
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// size = The width of the lines and diameter of points used to highlight edges and vertices. Module only. Default: 1
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// check_isects = If true, performs slow checks for intersecting faces. Default: false
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// Example: BIG_FACE Warnings; Faces with More Than 3 Vertices. CGAL often will fail to accept that a face is planar after a rotation, if it has more than 3 vertices.
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// vnf = skin([
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// path3d(regular_ngon(n=3, d=100),0),
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// path3d(regular_ngon(n=5, d=100),100)
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// ], slices=0, caps=true, method="tangent");
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// vnf_validate(vnf);
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// Example: NONPLANAR Errors; Face Vertices are Not Coplanar
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// a = [ 0, 0,-50];
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// b = [-50,-50, 50];
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// c = [-50, 50, 50];
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// d = [ 50, 50, 60];
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// e = [ 50,-50, 50];
|
|
// vnf = vnf_add_faces(faces=[
|
|
// [a, b, e], [a, c, b], [a, d, c], [a, e, d], [b, c, d, e]
|
|
// ]);
|
|
// vnf_validate(vnf);
|
|
// Example: OVRPOP_EDGE Errors; More Than Two Faces Attached to the Same Edge. This confuses CGAL, and can lead to failed renders.
|
|
// vnf = vnf_triangulate(linear_sweep(union(square(50), square(50,anchor=BACK+RIGHT)), height=50));
|
|
// vnf_validate(vnf);
|
|
// Example: REVERSAL Errors; Faces Reversed Across Edge
|
|
// vnf1 = skin([
|
|
// path3d(square(100,center=true),0),
|
|
// path3d(square(100,center=true),100),
|
|
// ], slices=0, caps=false);
|
|
// vnf = vnf_add_faces(vnf=vnf1, faces=[
|
|
// [[-50,-50, 0], [ 50, 50, 0], [-50, 50, 0]],
|
|
// [[-50,-50, 0], [ 50,-50, 0], [ 50, 50, 0]],
|
|
// [[-50,-50,100], [-50, 50,100], [ 50, 50,100]],
|
|
// [[-50,-50,100], [ 50,-50,100], [ 50, 50,100]],
|
|
// ]);
|
|
// vnf_validate(vnf);
|
|
// Example: T_JUNCTION Errors; Vertex is Mid-Edge on Another Face.
|
|
// vnf1 = skin([
|
|
// path3d(square(100,center=true),0),
|
|
// path3d(square(100,center=true),100),
|
|
// ], slices=0, caps=false);
|
|
// vnf = vnf_add_faces(vnf=vnf1, faces=[
|
|
// [[-50,-50,0], [50,50,0], [-50,50,0]],
|
|
// [[-50,-50,0], [50,-50,0], [50,50,0]],
|
|
// [[-50,-50,100], [-50,50,100], [0,50,100]],
|
|
// [[-50,-50,100], [0,50,100], [0,-50,100]],
|
|
// [[0,-50,100], [0,50,100], [50,50,100]],
|
|
// [[0,-50,100], [50,50,100], [50,-50,100]],
|
|
// ]);
|
|
// vnf_validate(vnf);
|
|
// Example: FACE_ISECT Errors; Faces Intersect
|
|
// vnf = vnf_merge([
|
|
// vnf_triangulate(linear_sweep(square(100,center=true), height=100)),
|
|
// move([75,35,30],p=vnf_triangulate(linear_sweep(square(100,center=true), height=100)))
|
|
// ]);
|
|
// vnf_validate(vnf,size=2,check_isects=true);
|
|
// Example: HOLE_EDGE Errors; Edges Adjacent to Holes.
|
|
// vnf = skin([
|
|
// path3d(regular_ngon(n=4, d=100),0),
|
|
// path3d(regular_ngon(n=5, d=100),100)
|
|
// ], slices=0, caps=false);
|
|
// vnf_validate(vnf,size=2);
|
|
function vnf_validate(vnf, show_warns=true, check_isects=false) =
|
|
let(
|
|
vnf = vnf_compact(vnf),
|
|
edges = sort([
|
|
for (face=vnf[1], edge=pair_wrap(face))
|
|
edge[0]<edge[1]? edge : [edge[1],edge[0]]
|
|
]),
|
|
edgecnts = unique_count(edges),
|
|
uniq_edges = edgecnts[0],
|
|
big_faces = !show_warns? [] : [
|
|
for (face = vnf[1])
|
|
if (len(face) > 3) [
|
|
"WARNING",
|
|
"BIG_FACE",
|
|
"Face has more than 3 vertices, and may confuse CGAL",
|
|
[for (i=face) vnf[0][i]],
|
|
"yellow"
|
|
]
|
|
],
|
|
null_faces = !show_warns? [] : [
|
|
for (face = vnf[1]) let(
|
|
verts = [for (k=face) vnf[0][k]],
|
|
area = abs(polygon_area(verts))
|
|
) if (area < EPSILON) [
|
|
"WARNING",
|
|
"NULL_FACE",
|
|
str("Face has zero area: ",fmt_float(area,15)),
|
|
verts,
|
|
"brown"
|
|
]
|
|
],
|
|
nonplanars = unique([
|
|
for (face = vnf[1]) let(
|
|
verts = [for (k=face) vnf[0][k]]
|
|
) if (!points_are_coplanar(verts)) [
|
|
"ERROR",
|
|
"NONPLANAR",
|
|
"Face vertices are not coplanar",
|
|
verts,
|
|
"cyan"
|
|
]
|
|
]),
|
|
overpop_edges = unique([
|
|
for (i=idx(uniq_edges))
|
|
if (edgecnts[1][i]>2) [
|
|
"ERROR",
|
|
"OVRPOP_EDGE",
|
|
"Too many faces attached at Edge",
|
|
[for (i=uniq_edges[i]) vnf[0][i]],
|
|
"#f70"
|
|
]
|
|
]),
|
|
reversals = unique([
|
|
for(i = idx(vnf[1]), j = idx(vnf[1])) if(i != j)
|
|
for(edge1 = pair_wrap(vnf[1][i]))
|
|
for(edge2 = pair_wrap(vnf[1][j]))
|
|
if(edge1 == edge2) // Valid adjacent faces will never have the same vertex ordering.
|
|
if(_edge_not_reported(edge1, vnf, overpop_edges))
|
|
[
|
|
"ERROR",
|
|
"REVERSAL",
|
|
"Faces Reverse Across Edge",
|
|
[for (i=edge1) vnf[0][i]],
|
|
"violet"
|
|
]
|
|
]),
|
|
t_juncts = unique([
|
|
for (v=idx(vnf[0]), edge=uniq_edges)
|
|
if (v!=edge[0] && v!=edge[1]) let(
|
|
a = vnf[0][edge[0]],
|
|
b = vnf[0][v],
|
|
c = vnf[0][edge[1]],
|
|
pt = segment_closest_point([a,c],b)
|
|
) if (pt == b) [
|
|
"ERROR",
|
|
"T_JUNCTION",
|
|
"Vertex is mid-edge on another Face",
|
|
[b],
|
|
"red"
|
|
]
|
|
]),
|
|
isect_faces = !check_isects? [] : unique([
|
|
for (i = [0:1:len(vnf[1])-2])
|
|
for (j = [i+1:1:len(vnf[1])-1]) let(
|
|
f1 = vnf[1][i],
|
|
f2 = vnf[1][j],
|
|
shared_edges = [
|
|
for (edge1 = pair_wrap(f1), edge2 = pair_wrap(f2)) let(
|
|
e1 = edge1[0]<edge1[1]? edge1 : [edge1[1],edge1[0]],
|
|
e2 = edge2[0]<edge2[1]? edge2 : [edge2[1],edge2[0]]
|
|
) if (e1==e2) 1
|
|
]
|
|
)
|
|
if (!shared_edges) let(
|
|
plane1 = plane3pt_indexed(vnf[0], f1[0], f1[1], f1[2]),
|
|
plane2 = plane3pt_indexed(vnf[0], f2[0], f2[1], f2[2]),
|
|
line = plane_intersection(plane1, plane2)
|
|
)
|
|
if (!is_undef(line)) let(
|
|
poly1 = select(vnf[0],f1),
|
|
isects = polygon_line_intersection(poly1,line)
|
|
)
|
|
if (!is_undef(isects))
|
|
for (isect=isects)
|
|
if (len(isect)>1) let(
|
|
poly2 = select(vnf[0],f2),
|
|
isects2 = polygon_line_intersection(poly2,isect,bounded=true)
|
|
)
|
|
if (!is_undef(isects2))
|
|
for (seg=isects2)
|
|
if (seg[0] != seg[1]) [
|
|
"ERROR",
|
|
"FACE_ISECT",
|
|
"Faces intersect",
|
|
seg,
|
|
"blue"
|
|
]
|
|
]),
|
|
hole_edges = unique([
|
|
for (i=idx(uniq_edges))
|
|
if (edgecnts[1][i]<2)
|
|
if (_pts_not_reported(uniq_edges[i], vnf, t_juncts))
|
|
if (_pts_not_reported(uniq_edges[i], vnf, isect_faces))
|
|
[
|
|
"ERROR",
|
|
"HOLE_EDGE",
|
|
"Edge bounds Hole",
|
|
[for (i=uniq_edges[i]) vnf[0][i]],
|
|
"magenta"
|
|
]
|
|
])
|
|
) concat(
|
|
big_faces,
|
|
null_faces,
|
|
nonplanars,
|
|
overpop_edges,
|
|
reversals,
|
|
t_juncts,
|
|
isect_faces,
|
|
hole_edges
|
|
);
|
|
|
|
|
|
function _pts_not_reported(pts, vnf, reports) =
|
|
[
|
|
for (i = pts, report = reports, pt = report[3])
|
|
if (vnf[0][i] == pt) 1
|
|
] == [];
|
|
|
|
|
|
function _edge_not_reported(edge, vnf, reports) =
|
|
let(
|
|
edge = sort([for (i=edge) vnf[0][i]])
|
|
) [
|
|
for (report = reports) let(
|
|
pts = sort(report[3])
|
|
) if (len(pts)==2 && edge == pts) 1
|
|
] == [];
|
|
|
|
|
|
module vnf_validate(vnf, size=1, show_warns=true, check_isects=false) {
|
|
faults = vnf_validate(
|
|
vnf, show_warns=show_warns,
|
|
check_isects=check_isects
|
|
);
|
|
for (fault = faults) {
|
|
typ = fault[0];
|
|
err = fault[1];
|
|
msg = fault[2];
|
|
pts = fault[3];
|
|
clr = fault[4];
|
|
echo(str(typ, " ", err, ": ", msg, " at ", pts));
|
|
color(clr) {
|
|
if (len(pts)==2) {
|
|
stroke(pts, width=size);
|
|
} else if (len(pts)>2) {
|
|
stroke(pts, width=size, closed=true);
|
|
polyhedron(pts,[[for (i=idx(pts)) i]]);
|
|
} else {
|
|
place_copies(pts) sphere(d=size*3, $fn=18);
|
|
}
|
|
}
|
|
}
|
|
color([0.5,0.5,0.5,0.5]) vnf_polyhedron(vnf);
|
|
}
|
|
|
|
|
|
// vim: noexpandtab tabstop=4 shiftwidth=4 softtabstop=4 nowrap
|