mirror of
https://github.com/BelfrySCAD/BOSL2.git
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336 lines
12 KiB
OpenSCAD
336 lines
12 KiB
OpenSCAD
//////////////////////////////////////////////////////////////////////
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// LibFile: coords.scad
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// Coordinate transformations and coordinate system conversions.
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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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// ```
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//////////////////////////////////////////////////////////////////////
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// Section: Coordinate Manipulation
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// Function: point2d()
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// Description:
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// Returns a 2D vector/point from a 2D or 3D vector.
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// If given a 3D point, removes the Z coordinate.
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// Arguments:
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// p = The coordinates to force into a 2D vector/point.
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// fill = Value to fill missing values in vector with.
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function point2d(p, fill=0) = [for (i=[0:1]) (p[i]==undef)? fill : p[i]];
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// Function: path2d()
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// Description:
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// Returns a list of 2D vectors/points from a list of 2D, 3D or higher
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// dimensional vectors/points. Removes the extra coordinates from
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// higher dimensional points. The input must be a path, where
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// every vector has the same length.
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// Arguments:
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// points = A list of 2D or 3D points/vectors.
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// fill = Value to fill missing values in vectors with.
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function path2d(points) =
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assert(is_path(points,dim=undef,fast=true),"Input to path2d is not a path")
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let (result = points * concat(ident(2), repeat([0,0], len(points[0])-2)))
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assert(is_def(result), "Invalid input to path2d")
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result;
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// Function: point3d()
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// Description:
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// Returns a 3D vector/point from a 2D or 3D vector.
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// Arguments:
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// p = The coordinates to force into a 3D vector/point.
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// fill = Value to fill missing values in vector with.
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function point3d(p, fill=0) = [for (i=[0:2]) (p[i]==undef)? fill : p[i]];
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// Function: path3d()
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// Description:
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// Returns a list of 3D vectors/points from a list of 2D or higher dimensional vectors/points
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// by removing extra coordinates or adding the z coordinate.
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// Arguments:
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// points = A list of 2D, 3D or higher dimensional points/vectors.
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// fill = Value to fill missing values in vectors with (in the 2D case)
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function path3d(points, fill=0) =
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assert(is_num(fill))
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assert(is_path(points, dim=undef, fast=true), "Input to path3d is not a path")
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let (
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change = len(points[0])-3,
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M = change < 0? [[1,0,0],[0,1,0]] :
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concat(ident(3), repeat([0,0,0],change)),
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result = points*M
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)
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assert(is_def(result), "Input to path3d is invalid")
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fill == 0 || change>=0 ? result : result + repeat([0,0,fill], len(result));
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// Function: point4d()
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// Description:
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// Returns a 4D vector/point from a 2D or 3D vector.
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// Arguments:
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// p = The coordinates to force into a 4D vector/point.
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// fill = Value to fill missing values in vector with.
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function point4d(p, fill=0) = [for (i=[0:3]) (p[i]==undef)? fill : p[i]];
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// Function: path4d()
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// Description:
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// Returns a list of 4D vectors/points from a list of 2D or 3D vectors/points.
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// Arguments:
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// points = A list of 2D or 3D points/vectors.
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// fill = Value to fill missing values in vectors with.
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function path4d(points, fill=0) =
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assert(is_num(fill) || is_vector(fill))
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assert(is_path(points, dim=undef, fast=true), "Input to path4d is not a path")
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let (
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change = len(points[0])-4,
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M = change < 0 ? select(ident(4), 0, len(points[0])-1) :
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concat(ident(4), repeat([0,0,0,0],change)),
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result = points*M
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)
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assert(is_def(result), "Input to path4d is invalid")
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fill == 0 || change >= 0 ? result :
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let(
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addition = is_list(fill) ? concat(0*points[0],fill) :
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concat(0*points[0],repeat(fill,-change))
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)
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assert(len(addition) == 4, "Fill is the wrong length")
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result + repeat(addition, len(result));
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// Section: Coordinate Systems
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// Function: polar_to_xy()
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// Usage:
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// polar_to_xy(r, theta);
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// polar_to_xy([r, theta]);
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// Description:
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// Convert polar coordinates to 2D cartesian coordinates.
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// Returns [X,Y] cartesian coordinates.
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// Arguments:
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// r = distance from the origin.
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// theta = angle in degrees, counter-clockwise of X+.
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// Examples:
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// xy = polar_to_xy(20,45); // Returns: ~[14.1421365, 14.1421365]
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// xy = polar_to_xy(40,30); // Returns: ~[34.6410162, 15]
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// xy = polar_to_xy([40,30]); // Returns: ~[34.6410162, 15]
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function polar_to_xy(r,theta=undef) = let(
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rad = theta==undef? r[0] : r,
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t = theta==undef? r[1] : theta
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) rad*[cos(t), sin(t)];
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// Function: xy_to_polar()
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// Usage:
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// xy_to_polar(x,y);
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// xy_to_polar([X,Y]);
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// Description:
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// Convert 2D cartesian coordinates to polar coordinates.
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// Returns [radius, theta] where theta is the angle counter-clockwise of X+.
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// Arguments:
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// x = X coordinate.
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// y = Y coordinate.
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// Examples:
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// plr = xy_to_polar(20,30);
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// plr = xy_to_polar([40,60]);
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function xy_to_polar(x,y=undef) = let(
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xx = y==undef? x[0] : x,
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yy = y==undef? x[1] : y
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) [norm([xx,yy]), atan2(yy,xx)];
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// Function: project_plane()
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// Usage:
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// xy = project_plane(point, a, b, c);
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// xy = project_plane(point, [A,B,C]];
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// Description:
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// Given three points defining a plane, returns the projected planar [X,Y] coordinates of the
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// closest point to a 3D `point`. The origin of the planar coordinate system [0,0] will be at point
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// `a`, and the Y+ axis direction will be towards point `b`. This coordinate system can be useful
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// in taking a set of nearly coplanar points, and converting them to a pure XY set of coordinates
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// for manipulation, before convering them back to the original 3D plane.
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// Arguments:
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// point = The 3D point, or list of 3D points to project into the plane's 2D coordinate system.
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// a = A 3D point that the plane passes through. Used to define the plane.
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// b = A 3D point that the plane passes through. Used to define the plane.
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// c = A 3D point that the plane passes through. Used to define the plane.
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// Example:
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// pt = [5,-5,5];
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// a=[0,0,0]; b=[10,-10,0]; c=[10,0,10];
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// xy = project_plane(pt, a, b, c);
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// xy2 = project_plane(pt, [a,b,c]);
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function project_plane(point, a, b, c) =
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is_undef(b) && is_undef(c) && is_list(a)? let(
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indices = find_noncollinear_points(a)
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) project_plane(point, a[indices[0]], a[indices[1]], a[indices[2]]) :
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assert(is_vector(a))
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assert(is_vector(b))
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assert(is_vector(c))
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assert(is_vector(point)||is_path(point))
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let(
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u = unit(b-a),
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v = unit(c-a),
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n = unit(cross(u,v)),
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w = unit(cross(n,u)),
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relpoint = apply(move(-a),point)
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) relpoint * transpose([w,u]);
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// Function: lift_plane()
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// Usage:
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// xyz = lift_plane(point, a, b, c);
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// xyz = lift_plane(point, [A,B,C]);
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// Description:
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// Given three points defining a plane, converts a planar [X,Y] coordinate to the actual
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// corresponding 3D point on the plane. The origin of the planar coordinate system [0,0]
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// will be at point `a`, and the Y+ axis direction will be towards point `b`.
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// Arguments:
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// point = The 2D point, or list of 2D points in the plane's coordinate system to get the 3D position of.
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// a = A 3D point that the plane passes through. Used to define the plane.
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// b = A 3D point that the plane passes through. Used to define the plane.
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// c = A 3D point that the plane passes through. Used to define the plane.
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function lift_plane(point, a, b, c) =
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is_undef(b) && is_undef(c) && is_list(a)? let(
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indices = find_noncollinear_points(a)
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) lift_plane(point, a[indices[0]], a[indices[1]], a[indices[2]]) :
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assert(is_vector(a))
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assert(is_vector(b))
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assert(is_vector(c))
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assert(is_vector(point)||is_path(point))
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let(
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u = unit(b-a),
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v = unit(c-a),
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n = unit(cross(u,v)),
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w = unit(cross(n,u)),
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remapped = point*[w,u]
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) apply(move(a),remapped);
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// Function: cylindrical_to_xyz()
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// Usage:
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// cylindrical_to_xyz(r, theta, z)
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// cylindrical_to_xyz([r, theta, z])
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// Description:
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// Convert cylindrical coordinates to 3D cartesian coordinates. Returns [X,Y,Z] cartesian coordinates.
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// Arguments:
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// r = distance from the Z axis.
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// theta = angle in degrees, counter-clockwise of X+ on the XY plane.
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// z = Height above XY plane.
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// Examples:
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// xyz = cylindrical_to_xyz(20,30,40);
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// xyz = cylindrical_to_xyz([40,60,50]);
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function cylindrical_to_xyz(r,theta=undef,z=undef) = let(
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rad = theta==undef? r[0] : r,
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t = theta==undef? r[1] : theta,
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zed = theta==undef? r[2] : z
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) [rad*cos(t), rad*sin(t), zed];
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// Function: xyz_to_cylindrical()
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// Usage:
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// xyz_to_cylindrical(x,y,z)
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// xyz_to_cylindrical([X,Y,Z])
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// Description:
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// Convert 3D cartesian coordinates to cylindrical coordinates.
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// Returns [radius,theta,Z]. Theta is the angle counter-clockwise
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// of X+ on the XY plane. Z is height above the XY plane.
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// Arguments:
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// x = X coordinate.
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// y = Y coordinate.
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// z = Z coordinate.
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// Examples:
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// cyl = xyz_to_cylindrical(20,30,40);
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// cyl = xyz_to_cylindrical([40,50,70]);
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function xyz_to_cylindrical(x,y=undef,z=undef) = let(
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p = is_num(x)? [x, default(y,0), default(z,0)] : point3d(x)
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) [norm([p.x,p.y]), atan2(p.y,p.x), p.z];
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// Function: spherical_to_xyz()
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// Usage:
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// spherical_to_xyz(r, theta, phi);
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// spherical_to_xyz([r, theta, phi]);
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// Description:
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// Convert spherical coordinates to 3D cartesian coordinates.
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// Returns [X,Y,Z] cartesian coordinates.
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// Arguments:
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// r = distance from origin.
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// theta = angle in degrees, counter-clockwise of X+ on the XY plane.
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// phi = angle in degrees from the vertical Z+ axis.
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// Examples:
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// xyz = spherical_to_xyz(20,30,40);
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// xyz = spherical_to_xyz([40,60,50]);
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function spherical_to_xyz(r,theta=undef,phi=undef) = let(
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rad = theta==undef? r[0] : r,
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t = theta==undef? r[1] : theta,
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p = theta==undef? r[2] : phi
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) rad*[sin(p)*cos(t), sin(p)*sin(t), cos(p)];
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// Function: xyz_to_spherical()
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// Usage:
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// xyz_to_spherical(x,y,z)
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// xyz_to_spherical([X,Y,Z])
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// Description:
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// Convert 3D cartesian coordinates to spherical coordinates.
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// Returns [r,theta,phi], where phi is the angle from the Z+ pole,
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// and theta is degrees counter-clockwise of X+ on the XY plane.
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// Arguments:
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// x = X coordinate.
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// y = Y coordinate.
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// z = Z coordinate.
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// Examples:
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// sph = xyz_to_spherical(20,30,40);
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// sph = xyz_to_spherical([40,50,70]);
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function xyz_to_spherical(x,y=undef,z=undef) = let(
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p = is_num(x)? [x, default(y,0), default(z,0)] : point3d(x)
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) [norm(p), atan2(p.y,p.x), atan2(norm([p.x,p.y]),p.z)];
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// Function: altaz_to_xyz()
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// Usage:
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// altaz_to_xyz(alt, az, r);
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// altaz_to_xyz([alt, az, r]);
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// Description:
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// Convert altitude/azimuth/range coordinates to 3D cartesian coordinates.
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// Returns [X,Y,Z] cartesian coordinates.
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// Arguments:
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// alt = altitude angle in degrees above the XY plane.
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// az = azimuth angle in degrees clockwise of Y+ on the XY plane.
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// r = distance from origin.
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// Examples:
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// xyz = altaz_to_xyz(20,30,40);
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// xyz = altaz_to_xyz([40,60,50]);
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function altaz_to_xyz(alt,az=undef,r=undef) = let(
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p = az==undef? alt[0] : alt,
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t = 90 - (az==undef? alt[1] : az),
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rad = az==undef? alt[2] : r
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) rad*[cos(p)*cos(t), cos(p)*sin(t), sin(p)];
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// Function: xyz_to_altaz()
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// Usage:
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// xyz_to_altaz(x,y,z);
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// xyz_to_altaz([X,Y,Z]);
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// Description:
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// Convert 3D cartesian coordinates to altitude/azimuth/range coordinates.
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// Returns [altitude,azimuth,range], where altitude is angle above the
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// XY plane, azimuth is degrees clockwise of Y+ on the XY plane, and
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// range is the distance from the origin.
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// Arguments:
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// x = X coordinate.
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// y = Y coordinate.
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// z = Z coordinate.
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// Examples:
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// aa = xyz_to_altaz(20,30,40);
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// aa = xyz_to_altaz([40,50,70]);
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function xyz_to_altaz(x,y=undef,z=undef) = let(
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p = is_num(x)? [x, default(y,0), default(z,0)] : point3d(x)
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) [atan2(p.z,norm([p.x,p.y])), atan2(p.x,p.y), norm(p)];
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// vim: noexpandtab tabstop=4 shiftwidth=4 softtabstop=4 nowrap
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