mirror of
https://github.com/BelfrySCAD/BOSL2.git
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05fe090fed
eliminate subdivide_long_segments
1667 lines
76 KiB
OpenSCAD
1667 lines
76 KiB
OpenSCAD
//////////////////////////////////////////////////////////////////////
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// LibFile: shapes2d.scad
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// This file includes redefinitions of the core modules to
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// work with attachment, and functional forms of those modules
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// that produce paths. You can create regular polygons
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// with optional rounded corners and alignment features not
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// available with circle(). The file also provides teardrop2d,
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// which is useful for 3D printable holes.
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// Many of the commands have module forms that produce geometry and
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// function forms that produce a path.
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// Includes:
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// include <BOSL2/std.scad>
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// FileGroup: Basic Modeling
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// FileSummary: Attachable circles, squares, polygons, teardrop. Can make geometry or paths.
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// FileFootnotes: STD=Included in std.scad
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//////////////////////////////////////////////////////////////////////
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use <builtins.scad>
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// Section: 2D Primitives
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// Function&Module: square()
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// Topics: Shapes (2D), Path Generators (2D)
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// Usage: As a Module
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// square(size, [center], ...);
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// Usage: With Attachments
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// square(size, [center], ...) { attachables }
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// Usage: As a Function
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// path = square(size, [center], ...);
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// See Also: rect()
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// Description:
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// When called as the builtin module, creates a 2D square or rectangle of the given size.
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// When called as a function, returns a 2D path/list of points for a square/rectangle of the given size.
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// Arguments:
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// size = The size of the square to create. If given as a scalar, both X and Y will be the same size.
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// center = If given and true, overrides `anchor` to be `CENTER`. If given and false, overrides `anchor` to be `FRONT+LEFT`.
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// ---
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// anchor = Translate so anchor point is at origin (0,0,0). See [anchor](attachments.scad#subsection-anchor). Default: `CENTER`
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// spin = Rotate this many degrees around the Z axis after anchor. See [spin](attachments.scad#subsection-spin). Default: `0`
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// Example(2D):
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// square(40);
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// Example(2D): Centered
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// square([40,30], center=true);
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// Example(2D): Called as Function
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// path = square([40,30], anchor=FRONT, spin=30);
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// stroke(path, closed=true);
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// move_copies(path) color("blue") circle(d=2,$fn=8);
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function square(size=1, center, anchor, spin=0) =
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let(
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anchor = get_anchor(anchor, center, [-1,-1], [-1,-1]),
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size = is_num(size)? [size,size] : point2d(size),
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path = [
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[ size.x,-size.y],
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[-size.x,-size.y],
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[-size.x, size.y],
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[ size.x, size.y]
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] / 2
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) reorient(anchor,spin, two_d=true, size=size, p=path);
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module square(size=1, center, anchor, spin) {
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anchor = get_anchor(anchor, center, [-1,-1], [-1,-1]);
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size = is_num(size)? [size,size] : point2d(size);
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attachable(anchor,spin, two_d=true, size=size) {
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_square(size, center=true);
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children();
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}
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}
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// Function&Module: rect()
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// Usage: As Module
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// rect(size, [rounding], [chamfer], ...);
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// Usage: With Attachments
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// rect(size, ...) { attachables }
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// Usage: As Function
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// path = rect(size, [rounding], [chamfer], ...);
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// Topics: Shapes (2D), Paths (2D), Path Generators, Attachable
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// See Also: square()
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// Description:
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// When called as a module, creates a 2D rectangle of the given size, with optional rounding or chamfering.
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// When called as a function, returns a 2D path/list of points for a square/rectangle of the given size.
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// Arguments:
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// size = The size of the rectangle to create. If given as a scalar, both X and Y will be the same size.
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// ---
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// rounding = The rounding radius for the corners. If negative, produces external roundover spikes on the X axis. If given as a list of four numbers, gives individual radii for each corner, in the order [X+Y+,X-Y+,X-Y-,X+Y-]. Default: 0 (no rounding)
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// chamfer = The chamfer size for the corners. If negative, produces external chamfer spikes on the X axis. If given as a list of four numbers, gives individual chamfers for each corner, in the order [X+Y+,X-Y+,X-Y-,X+Y-]. Default: 0 (no chamfer)
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// atype = The type of anchoring to use with `anchor=`. Valid opptions are "box" and "perim". This lets you choose between putting anchors on the rounded or chamfered perimeter, or on the square bounding box of the shape. Default: "box"
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// anchor = Translate so anchor point is at origin (0,0,0). See [anchor](attachments.scad#subsection-anchor). Default: `CENTER`
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// spin = Rotate this many degrees around the Z axis after anchor. See [spin](attachments.scad#subsection-spin). Default: `0`
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// Anchor Types:
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// box = Anchor is with respect to the rectangular bounding box of the shape.
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// perim = Anchors are placed along the rounded or chamfered perimeter of the shape.
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// Example(2D):
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// rect(40);
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// Example(2D): Anchored
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// rect([40,30], anchor=FRONT);
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// Example(2D): Spun
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// rect([40,30], anchor=FRONT, spin=30);
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// Example(2D): Chamferred Rect
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// rect([40,30], chamfer=5);
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// Example(2D): Rounded Rect
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// rect([40,30], rounding=5);
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// Example(2D): Negative-Chamferred Rect
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// rect([40,30], chamfer=-5);
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// Example(2D): Negative-Rounded Rect
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// rect([40,30], rounding=-5);
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// Example(2D): Default "box" Anchors
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// color("red") rect([40,30]);
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// rect([40,30], rounding=10)
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// show_anchors();
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// Example(2D): "perim" Anchors
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// rect([40,30], rounding=10, atype="perim")
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// show_anchors();
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// Example(2D): Mixed Chamferring and Rounding
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// rect([40,30],rounding=[5,0,10,0],chamfer=[0,8,0,15],$fa=1,$fs=1);
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// Example(2D): Called as Function
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// path = rect([40,30], chamfer=5, anchor=FRONT, spin=30);
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// stroke(path, closed=true);
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// move_copies(path) color("blue") circle(d=2,$fn=8);
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module rect(size=1, rounding=0, atype="box", chamfer=0, anchor=CENTER, spin=0) {
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errchk = assert(in_list(atype, ["box", "perim"]));
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size = is_num(size)? [size,size] : point2d(size);
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if (rounding==0 && chamfer==0) {
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attachable(anchor, spin, two_d=true, size=size) {
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square(size, center=true);
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children();
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}
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} else {
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pts = rect(size=size, rounding=rounding, chamfer=chamfer);
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if (atype == "perim") {
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attachable(anchor, spin, two_d=true, path=pts) {
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polygon(pts);
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children();
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}
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} else {
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attachable(anchor, spin, two_d=true, size=size) {
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polygon(pts);
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children();
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}
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}
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}
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}
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function rect(size=1, rounding=0, chamfer=0, atype="box", anchor=CENTER, spin=0) =
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assert(is_num(size) || is_vector(size))
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assert(is_num(chamfer) || len(chamfer)==4)
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assert(is_num(rounding) || len(rounding)==4)
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assert(in_list(atype, ["box", "perim"]))
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let(
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anchor=point2d(anchor),
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size = is_num(size)? [size,size] : point2d(size),
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complex = rounding!=0 || chamfer!=0
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)
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(rounding==0 && chamfer==0)? let(
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path = [
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[ size.x/2, -size.y/2],
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[-size.x/2, -size.y/2],
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[-size.x/2, size.y/2],
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[ size.x/2, size.y/2]
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]
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)
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rot(spin, p=move(-v_mul(anchor,size/2), p=path)) :
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let(
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chamfer = is_list(chamfer)? chamfer : [for (i=[0:3]) chamfer],
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rounding = is_list(rounding)? rounding : [for (i=[0:3]) rounding],
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quadorder = [3,2,1,0],
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quadpos = [[1,1],[-1,1],[-1,-1],[1,-1]],
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eps = 1e-9,
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insets = [for (i=[0:3]) abs(chamfer[i])>=eps? chamfer[i] : abs(rounding[i])>=eps? rounding[i] : 0],
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insets_x = max(insets[0]+insets[1],insets[2]+insets[3]),
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insets_y = max(insets[0]+insets[3],insets[1]+insets[2])
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)
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assert(insets_x <= size.x, "Requested roundings and/or chamfers exceed the rect width.")
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assert(insets_y <= size.y, "Requested roundings and/or chamfers exceed the rect height.")
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let(
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path = [
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for(i = [0:3])
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let(
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quad = quadorder[i],
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qinset = insets[quad],
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qpos = quadpos[quad],
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qchamf = chamfer[quad],
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qround = rounding[quad],
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cverts = quant(segs(abs(qinset)),4)/4,
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step = 90/cverts,
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cp = v_mul(size/2-[qinset,abs(qinset)], qpos),
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qpts = abs(qchamf) >= eps? [[0,abs(qinset)], [qinset,0]] :
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abs(qround) >= eps? [for (j=[0:1:cverts]) let(a=90-j*step) v_mul(polar_to_xy(abs(qinset),a),[sign(qinset),1])] :
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[[0,0]],
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qfpts = [for (p=qpts) v_mul(p,qpos)],
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qrpts = qpos.x*qpos.y < 0? reverse(qfpts) : qfpts
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)
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each move(cp, p=qrpts)
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]
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) complex && atype=="perim"?
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reorient(anchor,spin, two_d=true, path=path, p=path) :
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reorient(anchor,spin, two_d=true, size=size, p=path);
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// Function&Module: circle()
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// Topics: Shapes (2D), Path Generators (2D)
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// Usage: As a Module
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// circle(r|d=, ...);
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// Usage: With Attachments
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// circle(r|d=, ...) { attachables }
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// Usage: As a Function
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// path = circle(r|d=, ...);
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// See Also: ellipse(), circle_2tangents(), circle_3points()
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// Description:
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// When called as the builtin module, creates a 2D polygon that approximates a circle of the given size.
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// When called as a function, returns a 2D list of points (path) for a polygon that approximates a circle of the given size.
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// Arguments:
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// r = The radius of the circle to create.
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// d = The diameter of the circle to create.
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// ---
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// anchor = Translate so anchor point is at origin (0,0,0). See [anchor](attachments.scad#subsection-anchor). Default: `CENTER`
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// spin = Rotate this many degrees around the Z axis after anchor. See [spin](attachments.scad#subsection-spin). Default: `0`
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// Example(2D): By Radius
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// circle(r=25);
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// Example(2D): By Diameter
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// circle(d=50);
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// Example(NORENDER): Called as Function
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// path = circle(d=50, anchor=FRONT, spin=45);
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function circle(r, d, anchor=CENTER, spin=0) =
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let(
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r = get_radius(r=r, d=d, dflt=1),
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sides = segs(r),
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path = [for (i=[0:1:sides-1]) let(a=360-i*360/sides) r*[cos(a),sin(a)]]
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) reorient(anchor,spin, two_d=true, r=r, p=path);
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module circle(r, d, anchor=CENTER, spin=0) {
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r = get_radius(r=r, d=d, dflt=1);
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attachable(anchor,spin, two_d=true, r=r) {
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_circle(r=r);
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children();
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}
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}
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// Function&Module: ellipse()
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// Usage: As a Module
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// ellipse(r|d=, [realign=], [circum=], ...);
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// Usage: With Attachments
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// ellipse(r|d=, [realign=], [circum=], ...) { attachables }
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// Usage: As a Function
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// path = ellipse(r|d=, [realign=], [circum=], ...);
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// Topics: Shapes (2D), Paths (2D), Path Generators, Attachable
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// See Also: circle(), circle_2tangents(), circle_3points()
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// Description:
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// When called as a module, creates a 2D polygon that approximates a circle or ellipse of the given size.
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// When called as a function, returns a 2D list of points (path) for a polygon that approximates a circle or ellipse of the given size.
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// By default the point list or shape is the same as the one you would get by scaling the output of {{circle()}}, but with this module your
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// attachments to the ellipse will retain their dimensions, whereas scaling a circle with attachments will also scale the attachments.
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// If you set unifom to true then you will get a polygon with congruent sides whose vertices lie on the ellipse.
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// Arguments:
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// r = Radius of the circle or pair of semiaxes of ellipse
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// ---
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// d = Diameter of the circle or a pair giving the full X and Y axis lengths.
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// realign = If false starts the approximate ellipse with a point on the X+ axis. If true the midpoint of a side is on the X+ axis and the first point of the polygon is below the X+ axis. This can result in a very different polygon when $fn is small. Default: false
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// circum = If true, the polygon that approximates the circle will be upsized slightly to circumscribe the theoretical circle. If false, it inscribes the theoretical circle. Default: false
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// anchor = Translate so anchor point is at origin (0,0,0). See [anchor](attachments.scad#subsection-anchor). Default: `CENTER`
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// spin = Rotate this many degrees around the Z axis after anchor. See [spin](attachments.scad#subsection-spin). Default: `0`
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// Example(2D): By Radius
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// ellipse(r=25);
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// Example(2D): By Diameter
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// ellipse(d=50);
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// Example(2D): Anchoring
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// ellipse(d=50, anchor=FRONT);
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// Example(2D): Spin
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// ellipse(d=50, anchor=FRONT, spin=45);
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// Example(NORENDER): Called as Function
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// path = ellipse(d=50, anchor=FRONT, spin=45);
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// Example(2D,NoAxes): Uniformly sampled hexagon at the top, regular non-uniform one at the bottom
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// r=[10,3];
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// ydistribute(7){
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// union(){
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// stroke([ellipse(r=r, $fn=100)],width=0.05,color="blue");
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// stroke([ellipse(r=r, $fn=6)],width=0.1,color="red");
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// }
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// union(){
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// stroke([ellipse(r=r, $fn=100)],width=0.05,color="blue");
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// stroke([ellipse(r=r, $fn=6,uniform=true)],width=0.1,color="red");
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// }
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// }
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// Example(2D): The realigned hexagons are even more different
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// r=[10,3];
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// ydistribute(7){
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// union(){
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// stroke([ellipse(r=r, $fn=100)],width=0.05,color="blue");
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// stroke([ellipse(r=r, $fn=6,realign=true)],width=0.1,color="red");
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// }
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// union(){
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// stroke([ellipse(r=r, $fn=100)],width=0.05,color="blue");
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// stroke([ellipse(r=r, $fn=6,realign=true,uniform=true)],width=0.1,color="red");
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// }
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// }
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// Example(2D): For odd $fn the result may not look very elliptical:
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// r=[10,3];
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// ydistribute(7){
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// union(){
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// stroke([ellipse(r=r, $fn=100)],width=0.05,color="blue");
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// stroke([ellipse(r=r, $fn=5,realign=false)],width=0.1,color="red");
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// }
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// union(){
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// stroke([ellipse(r=r, $fn=100)],width=0.05,color="blue");
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// stroke([ellipse(r=r, $fn=5,realign=false,uniform=true)],width=0.1,color="red");
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// }
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// }
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// Example(2D): The same ellipse, turned 90 deg, gives a very different result:
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// r=[3,10];
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// xdistribute(7){
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// union(){
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// stroke([ellipse(r=r, $fn=100)],width=0.1,color="blue");
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// stroke([ellipse(r=r, $fn=5,realign=false)],width=0.2,color="red");
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// }
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// union(){
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// stroke([ellipse(r=r, $fn=100)],width=0.1,color="blue");
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// stroke([ellipse(r=r, $fn=5,realign=false,uniform=true)],width=0.2,color="red");
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// }
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// }
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module ellipse(r, d, realign=false, circum=false, uniform=false, anchor=CENTER, spin=0)
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{
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r = force_list(get_radius(r=r, d=d, dflt=1),2);
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dummy = assert(is_vector(r,2) && all_positive(r), "Invalid radius or diameter for ellipse");
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sides = segs(max(r));
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sc = circum? (1 / cos(180/sides)) : 1;
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rx = r.x * sc;
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ry = r.y * sc;
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attachable(anchor,spin, two_d=true, r=[rx,ry]) {
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if (uniform) {
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assert(!circum, "Circum option not allowed when \"uniform\" is true");
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polygon(ellipse(r,realign=realign, circum=circum, uniform=true));
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}
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else if (rx < ry) {
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xscale(rx/ry) {
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zrot(realign? 180/sides : 0) {
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circle(r=ry, $fn=sides);
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}
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}
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} else {
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yscale(ry/rx) {
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zrot(realign? 180/sides : 0) {
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circle(r=rx, $fn=sides);
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}
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}
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}
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children();
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}
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}
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// Iterative refinement to produce an inscribed polygon
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// in an ellipse whose side lengths are all equal
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function _ellipse_refine(a,b,N, _theta=[]) =
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len(_theta)==0? _ellipse_refine(a,b,N,lerpn(0,360,N,endpoint=false))
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:
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let(
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pts = [for(t=_theta) [a*cos(t),b*sin(t)]],
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lenlist= path_segment_lengths(pts,closed=true),
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meanlen = mean(lenlist),
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error = lenlist/meanlen
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)
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all_equal(error,EPSILON) ? pts
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:
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let(
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dtheta = [each deltas(_theta),
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360-last(_theta)],
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newdtheta = [for(i=idx(dtheta)) dtheta[i]/error[i]],
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adjusted = [0,each cumsum(list_head(newdtheta / sum(newdtheta) * 360))]
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)
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_ellipse_refine(a,b,N,adjusted);
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function _ellipse_refine_realign(a,b,N, _theta=[],i=0) =
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len(_theta)==0?
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_ellipse_refine_realign(a,b,N, count(N-1,180/N,360/N))
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:
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let(
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pts = [for(t=_theta) [a*cos(t),b*sin(t)],
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[a*cos(_theta[0]), -b*sin(_theta[0])]],
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lenlist= path_segment_lengths(pts,closed=true),
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meanlen = mean(lenlist),
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error = lenlist/meanlen
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)
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all_equal(error,EPSILON) ? pts
|
|
:
|
|
let(
|
|
dtheta = [each deltas(_theta),
|
|
360-last(_theta)-_theta[0],
|
|
2*_theta[0]],
|
|
newdtheta = [for(i=idx(dtheta)) dtheta[i]/error[i]],
|
|
normdtheta = newdtheta / sum(newdtheta) * 360,
|
|
adjusted = cumsum([last(normdtheta)/2, each list_head(normdtheta, -3)])
|
|
)
|
|
_ellipse_refine_realign(a,b,N,adjusted, i+1);
|
|
|
|
|
|
|
|
function ellipse(r, d, realign=false, circum=false, uniform=false, anchor=CENTER, spin=0) =
|
|
let(
|
|
r = force_list(get_radius(r=r, d=d, dflt=1),2),
|
|
sides = segs(max(r))
|
|
)
|
|
uniform ? assert(!circum, "Circum option not allowed when \"uniform\" is true")
|
|
reorient(anchor,spin,two_d=true,r=[r.x,r.y],
|
|
p=realign ? reverse(_ellipse_refine_realign(r.x,r.y,sides))
|
|
: reverse_polygon(_ellipse_refine(r.x,r.y,sides)))
|
|
:
|
|
let(
|
|
offset = realign? 180/sides : 0,
|
|
sc = circum? (1 / cos(180/sides)) : 1,
|
|
rx = r.x * sc,
|
|
ry = r.y * sc,
|
|
pts = [for (i=[0:1:sides-1]) let(a=360-offset-i*360/sides) [rx*cos(a), ry*sin(a)]]
|
|
) reorient(anchor,spin, two_d=true, r=[rx,ry], p=pts);
|
|
|
|
|
|
// Section: Polygons
|
|
|
|
// Function&Module: regular_ngon()
|
|
// Usage:
|
|
// regular_ngon(n, r/d=/or=/od=, [realign=]);
|
|
// regular_ngon(n, ir=/id=, [realign=]);
|
|
// regular_ngon(n, side=, [realign=]);
|
|
// Topics: Shapes (2D), Paths (2D), Path Generators, Attachable
|
|
// See Also: circle(), pentagon(), hexagon(), octagon(), ellipse(), star()
|
|
// Description:
|
|
// When called as a function, returns a 2D path for a regular N-sided polygon.
|
|
// When called as a module, creates a 2D regular N-sided polygon.
|
|
// Arguments:
|
|
// n = The number of sides.
|
|
// r/or = Outside radius, at points.
|
|
// ---
|
|
// d/od = Outside diameter, at points.
|
|
// ir = Inside radius, at center of sides.
|
|
// id = Inside diameter, at center of sides.
|
|
// side = Length of each side.
|
|
// rounding = Radius of rounding for the tips of the polygon. Default: 0 (no rounding)
|
|
// realign = If false, vertex 0 will lie on the X+ axis. If true then the midpoint of the last edge will lie on the X+ axis, and vertex 0 will be below the X axis. Default: false
|
|
// align_tip = If given as a 2D vector, rotates the whole shape so that the first vertex points in that direction. This occurs before spin.
|
|
// align_side = If given as a 2D vector, rotates the whole shape so that the normal of side0 points in that direction. This occurs before spin.
|
|
// anchor = Translate so anchor point is at origin (0,0,0). See [anchor](attachments.scad#subsection-anchor). Default: `CENTER`
|
|
// spin = Rotate this many degrees around the Z axis after anchor. See [spin](attachments.scad#subsection-spin). Default: `0`
|
|
// Extra Anchors:
|
|
// "tip0", "tip1", etc. = Each tip has an anchor, pointing outwards.
|
|
// "side0", "side1", etc. = The center of each side has an anchor, pointing outwards.
|
|
// Example(2D): by Outer Size
|
|
// regular_ngon(n=5, or=30);
|
|
// regular_ngon(n=5, od=60);
|
|
// Example(2D): by Inner Size
|
|
// regular_ngon(n=5, ir=30);
|
|
// regular_ngon(n=5, id=60);
|
|
// Example(2D): by Side Length
|
|
// regular_ngon(n=8, side=20);
|
|
// Example(2D): Realigned
|
|
// regular_ngon(n=8, side=20, realign=true);
|
|
// Example(2D): Alignment by Tip
|
|
// regular_ngon(n=5, r=30, align_tip=BACK+RIGHT)
|
|
// attach("tip0", FWD) color("blue")
|
|
// stroke([[0,0],[0,7]], endcap2="arrow2");
|
|
// Example(2D): Alignment by Side
|
|
// regular_ngon(n=5, r=30, align_side=BACK+RIGHT)
|
|
// attach("side0", FWD) color("blue")
|
|
// stroke([[0,0],[0,7]], endcap2="arrow2");
|
|
// Example(2D): Rounded
|
|
// regular_ngon(n=5, od=100, rounding=20, $fn=20);
|
|
// Example(2D): Called as Function
|
|
// stroke(closed=true, regular_ngon(n=6, or=30));
|
|
function regular_ngon(n=6, r, d, or, od, ir, id, side, rounding=0, realign=false, align_tip, align_side, anchor=CENTER, spin=0, _mat, _anchs) =
|
|
assert(is_undef(align_tip) || is_vector(align_tip))
|
|
assert(is_undef(align_side) || is_vector(align_side))
|
|
assert(is_undef(align_tip) || is_undef(align_side), "Can only specify one of align_tip and align-side")
|
|
let(
|
|
sc = 1/cos(180/n),
|
|
ir = is_finite(ir)? ir*sc : undef,
|
|
id = is_finite(id)? id*sc : undef,
|
|
side = is_finite(side)? side/2/sin(180/n) : undef,
|
|
r = get_radius(r1=ir, r2=or, r=r, d1=id, d2=od, d=d, dflt=side)
|
|
)
|
|
assert(!is_undef(r), "regular_ngon(): need to specify one of r, d, or, od, ir, id, side.")
|
|
let(
|
|
inset = opp_ang_to_hyp(rounding, (180-360/n)/2),
|
|
mat = !is_undef(_mat) ? _mat :
|
|
( realign? zrot(-180/n) : ident(4)) * (
|
|
!is_undef(align_tip)? rot(from=RIGHT, to=point2d(align_tip)) :
|
|
!is_undef(align_side)? rot(from=RIGHT, to=point2d(align_side)) * zrot(180/n) :
|
|
1
|
|
),
|
|
path4 = rounding==0? ellipse(r=r, $fn=n) : (
|
|
let(
|
|
steps = floor(segs(r)/n),
|
|
step = 360/n/steps,
|
|
path2 = [
|
|
for (i = [0:1:n-1]) let(
|
|
a = 360 - i*360/n,
|
|
p = polar_to_xy(r-inset, a)
|
|
)
|
|
each arc(n=steps, cp=p, r=rounding, start=a+180/n, angle=-360/n)
|
|
],
|
|
maxx_idx = max_index(column(path2,0)),
|
|
path3 = list_rotate(path2,maxx_idx)
|
|
) path3
|
|
),
|
|
path = apply(mat, path4),
|
|
anchors = !is_undef(_anchs) ? _anchs :
|
|
!is_string(anchor)? [] : [
|
|
for (i = [0:1:n-1]) let(
|
|
a1 = 360 - i*360/n,
|
|
a2 = a1 - 360/n,
|
|
p1 = apply(mat, polar_to_xy(r,a1)),
|
|
p2 = apply(mat, polar_to_xy(r,a2)),
|
|
tipp = apply(mat, polar_to_xy(r-inset+rounding,a1)),
|
|
pos = (p1+p2)/2
|
|
) each [
|
|
named_anchor(str("tip",i), tipp, unit(tipp,BACK), 0),
|
|
named_anchor(str("side",i), pos, unit(pos,BACK), 0),
|
|
]
|
|
]
|
|
) reorient(anchor,spin, two_d=true, path=path, extent=false, p=path, anchors=anchors);
|
|
|
|
|
|
module regular_ngon(n=6, r, d, or, od, ir, id, side, rounding=0, realign=false, align_tip, align_side, anchor=CENTER, spin=0) {
|
|
sc = 1/cos(180/n);
|
|
ir = is_finite(ir)? ir*sc : undef;
|
|
id = is_finite(id)? id*sc : undef;
|
|
side = is_finite(side)? side/2/sin(180/n) : undef;
|
|
r = get_radius(r1=ir, r2=or, r=r, d1=id, d2=od, d=d, dflt=side);
|
|
assert(!is_undef(r), "regular_ngon(): need to specify one of r, d, or, od, ir, id, side.");
|
|
mat = ( realign? zrot(-180/n) : ident(4) ) * (
|
|
!is_undef(align_tip)? rot(from=RIGHT, to=point2d(align_tip)) :
|
|
!is_undef(align_side)? rot(from=RIGHT, to=point2d(align_side)) * zrot(180/n) :
|
|
1
|
|
);
|
|
inset = opp_ang_to_hyp(rounding, (180-360/n)/2);
|
|
anchors = [
|
|
for (i = [0:1:n-1]) let(
|
|
a1 = 360 - i*360/n,
|
|
a2 = a1 - 360/n,
|
|
p1 = apply(mat, polar_to_xy(r,a1)),
|
|
p2 = apply(mat, polar_to_xy(r,a2)),
|
|
tipp = apply(mat, polar_to_xy(r-inset+rounding,a1)),
|
|
pos = (p1+p2)/2
|
|
) each [
|
|
named_anchor(str("tip",i), tipp, unit(tipp,BACK), 0),
|
|
named_anchor(str("side",i), pos, unit(pos,BACK), 0),
|
|
]
|
|
];
|
|
path = regular_ngon(n=n, r=r, rounding=rounding, _mat=mat, _anchs=anchors);
|
|
attachable(anchor,spin, two_d=true, path=path, extent=false, anchors=anchors) {
|
|
polygon(path);
|
|
children();
|
|
}
|
|
}
|
|
|
|
|
|
// Function&Module: pentagon()
|
|
// Usage:
|
|
// pentagon(or|od=, [realign=]);
|
|
// pentagon(ir=|id=, [realign=]);
|
|
// pentagon(side=, [realign=]);
|
|
// Topics: Shapes (2D), Paths (2D), Path Generators, Attachable
|
|
// See Also: circle(), regular_ngon(), hexagon(), octagon(), ellipse(), star()
|
|
// Description:
|
|
// When called as a function, returns a 2D path for a regular pentagon.
|
|
// When called as a module, creates a 2D regular pentagon.
|
|
// Arguments:
|
|
// r/or = Outside radius, at points.
|
|
// ---
|
|
// d/od = Outside diameter, at points.
|
|
// ir = Inside radius, at center of sides.
|
|
// id = Inside diameter, at center of sides.
|
|
// side = Length of each side.
|
|
// rounding = Radius of rounding for the tips of the polygon. Default: 0 (no rounding)
|
|
// realign = If false, vertex 0 will lie on the X+ axis. If true then the midpoint of the last edge will lie on the X+ axis, and vertex 0 will be below the X axis. Default: false
|
|
// align_tip = If given as a 2D vector, rotates the whole shape so that the first vertex points in that direction. This occurs before spin.
|
|
// align_side = If given as a 2D vector, rotates the whole shape so that the normal of side0 points in that direction. This occurs before spin.
|
|
// anchor = Translate so anchor point is at origin (0,0,0). See [anchor](attachments.scad#subsection-anchor). Default: `CENTER`
|
|
// spin = Rotate this many degrees around the Z axis after anchor. See [spin](attachments.scad#subsection-spin). Default: `0`
|
|
// Extra Anchors:
|
|
// "tip0" ... "tip4" = Each tip has an anchor, pointing outwards.
|
|
// "side0" ... "side4" = The center of each side has an anchor, pointing outwards.
|
|
// Example(2D): by Outer Size
|
|
// pentagon(or=30);
|
|
// pentagon(od=60);
|
|
// Example(2D): by Inner Size
|
|
// pentagon(ir=30);
|
|
// pentagon(id=60);
|
|
// Example(2D): by Side Length
|
|
// pentagon(side=20);
|
|
// Example(2D): Realigned
|
|
// pentagon(side=20, realign=true);
|
|
// Example(2D): Alignment by Tip
|
|
// pentagon(r=30, align_tip=BACK+RIGHT)
|
|
// attach("tip0", FWD) color("blue")
|
|
// stroke([[0,0],[0,7]], endcap2="arrow2");
|
|
// Example(2D): Alignment by Side
|
|
// pentagon(r=30, align_side=BACK+RIGHT)
|
|
// attach("side0", FWD) color("blue")
|
|
// stroke([[0,0],[0,7]], endcap2="arrow2");
|
|
// Example(2D): Rounded
|
|
// pentagon(od=100, rounding=20, $fn=20);
|
|
// Example(2D): Called as Function
|
|
// stroke(closed=true, pentagon(or=30));
|
|
function pentagon(r, d, or, od, ir, id, side, rounding=0, realign=false, align_tip, align_side, anchor=CENTER, spin=0) =
|
|
regular_ngon(n=5, r=r, d=d, or=or, od=od, ir=ir, id=id, side=side, rounding=rounding, realign=realign, align_tip=align_tip, align_side=align_side, anchor=anchor, spin=spin);
|
|
|
|
|
|
module pentagon(r, d, or, od, ir, id, side, rounding=0, realign=false, align_tip, align_side, anchor=CENTER, spin=0)
|
|
regular_ngon(n=5, r=r, d=d, or=or, od=od, ir=ir, id=id, side=side, rounding=rounding, realign=realign, align_tip=align_tip, align_side=align_side, anchor=anchor, spin=spin) children();
|
|
|
|
|
|
// Function&Module: hexagon()
|
|
// Usage: As Module
|
|
// hexagon(r/or, [realign=], <align_tip=|align_side=>, [rounding=], ...);
|
|
// hexagon(d=/od=, ...);
|
|
// hexagon(ir=/id=, ...);
|
|
// hexagon(side=, ...);
|
|
// Usage: With Attachments
|
|
// hexagon(r/or, ...) { attachments }
|
|
// Usage: As Function
|
|
// path = hexagon(r/or, ...);
|
|
// path = hexagon(d=/od=, ...);
|
|
// path = hexagon(ir=/id=, ...);
|
|
// path = hexagon(side=, ...);
|
|
// Topics: Shapes (2D), Paths (2D), Path Generators, Attachable
|
|
// See Also: circle(), regular_ngon(), pentagon(), octagon(), ellipse(), star()
|
|
// Description:
|
|
// When called as a function, returns a 2D path for a regular hexagon.
|
|
// When called as a module, creates a 2D regular hexagon.
|
|
// Arguments:
|
|
// r/or = Outside radius, at points.
|
|
// ---
|
|
// d/od = Outside diameter, at points.
|
|
// ir = Inside radius, at center of sides.
|
|
// id = Inside diameter, at center of sides.
|
|
// side = Length of each side.
|
|
// rounding = Radius of rounding for the tips of the polygon. Default: 0 (no rounding)
|
|
// realign = If false, vertex 0 will lie on the X+ axis. If true then the midpoint of the last edge will lie on the X+ axis, and vertex 0 will be below the X axis. Default: false
|
|
// align_tip = If given as a 2D vector, rotates the whole shape so that the first vertex points in that direction. This occurs before spin.
|
|
// align_side = If given as a 2D vector, rotates the whole shape so that the normal of side0 points in that direction. This occurs before spin.
|
|
// anchor = Translate so anchor point is at origin (0,0,0). See [anchor](attachments.scad#subsection-anchor). Default: `CENTER`
|
|
// spin = Rotate this many degrees around the Z axis after anchor. See [spin](attachments.scad#subsection-spin). Default: `0`
|
|
// Extra Anchors:
|
|
// "tip0" ... "tip5" = Each tip has an anchor, pointing outwards.
|
|
// "side0" ... "side5" = The center of each side has an anchor, pointing outwards.
|
|
// Example(2D): by Outer Size
|
|
// hexagon(or=30);
|
|
// hexagon(od=60);
|
|
// Example(2D): by Inner Size
|
|
// hexagon(ir=30);
|
|
// hexagon(id=60);
|
|
// Example(2D): by Side Length
|
|
// hexagon(side=20);
|
|
// Example(2D): Realigned
|
|
// hexagon(side=20, realign=true);
|
|
// Example(2D): Alignment by Tip
|
|
// hexagon(r=30, align_tip=BACK+RIGHT)
|
|
// attach("tip0", FWD) color("blue")
|
|
// stroke([[0,0],[0,7]], endcap2="arrow2");
|
|
// Example(2D): Alignment by Side
|
|
// hexagon(r=30, align_side=BACK+RIGHT)
|
|
// attach("side0", FWD) color("blue")
|
|
// stroke([[0,0],[0,7]], endcap2="arrow2");
|
|
// Example(2D): Rounded
|
|
// hexagon(od=100, rounding=20, $fn=20);
|
|
// Example(2D): Called as Function
|
|
// stroke(closed=true, hexagon(or=30));
|
|
function hexagon(r, d, or, od, ir, id, side, rounding=0, realign=false, align_tip, align_side, anchor=CENTER, spin=0) =
|
|
regular_ngon(n=6, r=r, d=d, or=or, od=od, ir=ir, id=id, side=side, rounding=rounding, realign=realign, align_tip=align_tip, align_side=align_side, anchor=anchor, spin=spin);
|
|
|
|
|
|
module hexagon(r, d, or, od, ir, id, side, rounding=0, realign=false, align_tip, align_side, anchor=CENTER, spin=0)
|
|
regular_ngon(n=6, r=r, d=d, or=or, od=od, ir=ir, id=id, side=side, rounding=rounding, realign=realign, align_tip=align_tip, align_side=align_side, anchor=anchor, spin=spin) children();
|
|
|
|
|
|
// Function&Module: octagon()
|
|
// Usage: As Module
|
|
// octagon(r/or, [realign=], <align_tip=|align_side=>, [rounding=], ...);
|
|
// octagon(d=/od=, ...);
|
|
// octagon(ir=/id=, ...);
|
|
// octagon(side=, ...);
|
|
// Usage: With Attachments
|
|
// octagon(r/or, ...) { attachments }
|
|
// Usage: As Function
|
|
// path = octagon(r/or, ...);
|
|
// path = octagon(d=/od=, ...);
|
|
// path = octagon(ir=/id=, ...);
|
|
// path = octagon(side=, ...);
|
|
// Topics: Shapes (2D), Paths (2D), Path Generators, Attachable
|
|
// See Also: circle(), regular_ngon(), pentagon(), hexagon(), ellipse(), star()
|
|
// Description:
|
|
// When called as a function, returns a 2D path for a regular octagon.
|
|
// When called as a module, creates a 2D regular octagon.
|
|
// Arguments:
|
|
// r/or = Outside radius, at points.
|
|
// d/od = Outside diameter, at points.
|
|
// ir = Inside radius, at center of sides.
|
|
// id = Inside diameter, at center of sides.
|
|
// side = Length of each side.
|
|
// rounding = Radius of rounding for the tips of the polygon. Default: 0 (no rounding)
|
|
// realign = If false, vertex 0 will lie on the X+ axis. If true then the midpoint of the last edge will lie on the X+ axis, and vertex 0 will be below the X axis. Default: false
|
|
// align_tip = If given as a 2D vector, rotates the whole shape so that the first vertex points in that direction. This occurs before spin.
|
|
// align_side = If given as a 2D vector, rotates the whole shape so that the normal of side0 points in that direction. This occurs before spin.
|
|
// anchor = Translate so anchor point is at origin (0,0,0). See [anchor](attachments.scad#subsection-anchor). Default: `CENTER`
|
|
// spin = Rotate this many degrees around the Z axis after anchor. See [spin](attachments.scad#subsection-spin). Default: `0`
|
|
// Extra Anchors:
|
|
// "tip0" ... "tip7" = Each tip has an anchor, pointing outwards.
|
|
// "side0" ... "side7" = The center of each side has an anchor, pointing outwards.
|
|
// Example(2D): by Outer Size
|
|
// octagon(or=30);
|
|
// octagon(od=60);
|
|
// Example(2D): by Inner Size
|
|
// octagon(ir=30);
|
|
// octagon(id=60);
|
|
// Example(2D): by Side Length
|
|
// octagon(side=20);
|
|
// Example(2D): Realigned
|
|
// octagon(side=20, realign=true);
|
|
// Example(2D): Alignment by Tip
|
|
// octagon(r=30, align_tip=BACK+RIGHT)
|
|
// attach("tip0", FWD) color("blue")
|
|
// stroke([[0,0],[0,7]], endcap2="arrow2");
|
|
// Example(2D): Alignment by Side
|
|
// octagon(r=30, align_side=BACK+RIGHT)
|
|
// attach("side0", FWD) color("blue")
|
|
// stroke([[0,0],[0,7]], endcap2="arrow2");
|
|
// Example(2D): Rounded
|
|
// octagon(od=100, rounding=20, $fn=20);
|
|
// Example(2D): Called as Function
|
|
// stroke(closed=true, octagon(or=30));
|
|
function octagon(r, d, or, od, ir, id, side, rounding=0, realign=false, align_tip, align_side, anchor=CENTER, spin=0) =
|
|
regular_ngon(n=8, r=r, d=d, or=or, od=od, ir=ir, id=id, side=side, rounding=rounding, realign=realign, align_tip=align_tip, align_side=align_side, anchor=anchor, spin=spin);
|
|
|
|
|
|
module octagon(r, d, or, od, ir, id, side, rounding=0, realign=false, align_tip, align_side, anchor=CENTER, spin=0)
|
|
regular_ngon(n=8, r=r, d=d, or=or, od=od, ir=ir, id=id, side=side, rounding=rounding, realign=realign, align_tip=align_tip, align_side=align_side, anchor=anchor, spin=spin) children();
|
|
|
|
|
|
// Function&Module: right_triangle()
|
|
// Usage: As Module
|
|
// right_triangle(size, [center], ...);
|
|
// Usage: With Attachments
|
|
// right_triangle(size, [center], ...) { attachments }
|
|
// Usage: As Function
|
|
// path = right_triangle(size, [center], ...);
|
|
// Description:
|
|
// Creates a right triangle with the Hypotenuse in the X+Y+ quadrant.
|
|
// Arguments:
|
|
// size = The width and length of the right triangle, given as a scalar or an XY vector.
|
|
// center = If true, forces `anchor=CENTER`. If false, forces `anchor=[-1,-1]`. Default: undef (use `anchor=`)
|
|
// ---
|
|
// anchor = Translate so anchor point is at origin (0,0,0). See [anchor](attachments.scad#subsection-anchor). Default: `CENTER`
|
|
// spin = Rotate this many degrees around the Z axis after anchor. See [spin](attachments.scad#subsection-spin). Default: `0`
|
|
// Example(2D):
|
|
// right_triangle([40,30]);
|
|
// Example(2D): With `center=true`
|
|
// right_triangle([40,30], center=true);
|
|
// Example(2D): Anchors
|
|
// right_triangle([40,30])
|
|
// show_anchors();
|
|
function right_triangle(size=[1,1], center, anchor, spin=0) =
|
|
let(
|
|
size = is_num(size)? [size,size] : size,
|
|
anchor = get_anchor(anchor, center, [-1,-1], [-1,-1])
|
|
)
|
|
assert(is_vector(size,2))
|
|
let(
|
|
path = [ [size.x/2,-size.y/2], [-size.x/2,-size.y/2], [-size.x/2,size.y/2] ]
|
|
) reorient(anchor,spin, two_d=true, size=[size.x,size.y], size2=0, shift=-size.x/2, p=path);
|
|
|
|
module right_triangle(size=[1,1], center, anchor, spin=0) {
|
|
size = is_num(size)? [size,size] : size;
|
|
anchor = get_anchor(anchor, center, [-1,-1], [-1,-1]);
|
|
assert(is_vector(size,2));
|
|
path = right_triangle(size, center=true);
|
|
attachable(anchor,spin, two_d=true, size=[size.x,size.y], size2=0, shift=-size.x/2) {
|
|
polygon(path);
|
|
children();
|
|
}
|
|
}
|
|
|
|
|
|
// Function&Module: trapezoid()
|
|
// Usage: As Module
|
|
// trapezoid(h, w1, w2, [shift=], [rounding=], [chamfer=], ...);
|
|
// trapezoid(h, w1, angle=, ...);
|
|
// trapezoid(h, w2, angle=, ...);
|
|
// trapezoid(w1, w2, angle=, ...);
|
|
// Usage: With Attachments
|
|
// trapezoid(h, w1, w2, ...) { attachments }
|
|
// Usage: As Function
|
|
// path = trapezoid(h, w1, w2, ...);
|
|
// path = trapezoid(h, w1, angle=, ...);
|
|
// path = trapezoid(h, w2=, angle=, ...);
|
|
// path = trapezoid(w1=, w2=, angle=, ...);
|
|
// Topics: Shapes (2D), Paths (2D), Path Generators, Attachable
|
|
// See Also: rect(), square()
|
|
// Description:
|
|
// When called as a function, returns a 2D path for a trapezoid with parallel front and back sides.
|
|
// When called as a module, creates a 2D trapezoid with parallel front and back sides.
|
|
// Arguments:
|
|
// h = The Y axis height of the trapezoid.
|
|
// w1 = The X axis width of the front end of the trapezoid.
|
|
// w2 = The X axis width of the back end of the trapezoid.
|
|
// ---
|
|
// angle = If given in place of `h`, `w1`, or `w2`, then the missing value is calculated such that the right side has that angle away from the Y axis.
|
|
// shift = Scalar value to shift the back of the trapezoid along the X axis by. Default: 0
|
|
// rounding = The rounding radius for the corners. If given as a list of four numbers, gives individual radii for each corner, in the order [X+Y+,X-Y+,X-Y-,X+Y-]. Default: 0 (no rounding)
|
|
// chamfer = The Length of the chamfer faces at the corners. If given as a list of four numbers, gives individual chamfers for each corner, in the order [X+Y+,X-Y+,X-Y-,X+Y-]. Default: 0 (no chamfer)
|
|
// flip = If true, negative roundings and chamfers will point forward and back instead of left and right. Default: `false`.
|
|
// anchor = Translate so anchor point is at origin (0,0,0). See [anchor](attachments.scad#subsection-anchor). Default: `CENTER`
|
|
// spin = Rotate this many degrees around the Z axis after anchor. See [spin](attachments.scad#subsection-spin). Default: `0`
|
|
// Examples(2D):
|
|
// trapezoid(h=30, w1=40, w2=20);
|
|
// trapezoid(h=25, w1=20, w2=35);
|
|
// trapezoid(h=20, w1=40, w2=0);
|
|
// trapezoid(h=20, w1=30, angle=30);
|
|
// trapezoid(h=20, w1=20, angle=-30);
|
|
// trapezoid(h=20, w2=10, angle=30);
|
|
// trapezoid(h=20, w2=30, angle=-30);
|
|
// trapezoid(w1=30, w2=10, angle=30);
|
|
// Example(2D): Chamfered Trapezoid
|
|
// trapezoid(h=30, w1=60, w2=40, chamfer=5);
|
|
// Example(2D): Negative Chamfered Trapezoid
|
|
// trapezoid(h=30, w1=60, w2=40, chamfer=-5);
|
|
// Example(2D): Flipped Negative Chamfered Trapezoid
|
|
// trapezoid(h=30, w1=60, w2=40, chamfer=-5, flip=true);
|
|
// Example(2D): Rounded Trapezoid
|
|
// trapezoid(h=30, w1=60, w2=40, rounding=5);
|
|
// Example(2D): Negative Rounded Trapezoid
|
|
// trapezoid(h=30, w1=60, w2=40, rounding=-5);
|
|
// Example(2D): Flipped Negative Rounded Trapezoid
|
|
// trapezoid(h=30, w1=60, w2=40, rounding=-5, flip=true);
|
|
// Example(2D): Mixed Chamfering and Rounding
|
|
// trapezoid(h=30, w1=60, w2=40, rounding=[5,0,-10,0],chamfer=[0,8,0,-15],$fa=1,$fs=1);
|
|
// Example(2D): Called as Function
|
|
// stroke(closed=true, trapezoid(h=30, w1=40, w2=20));
|
|
function trapezoid(h, w1, w2, angle, shift=0, chamfer=0, rounding=0, flip=false, anchor=CENTER, spin=0) =
|
|
assert(is_undef(h) || is_finite(h))
|
|
assert(is_undef(w1) || is_finite(w1))
|
|
assert(is_undef(w2) || is_finite(w2))
|
|
assert(is_undef(angle) || is_finite(angle))
|
|
assert(num_defined([h, w1, w2, angle]) == 3, "Must give exactly 3 of the arguments h, w1, w2, and angle.")
|
|
assert(is_finite(shift))
|
|
assert(is_finite(chamfer) || is_vector(chamfer,4))
|
|
assert(is_finite(rounding) || is_vector(rounding,4))
|
|
let(
|
|
simple = chamfer==0 && rounding==0,
|
|
h = !is_undef(h)? h : opp_ang_to_adj(abs(w2-w1)/2, abs(angle)),
|
|
w1 = !is_undef(w1)? w1 : w2 + 2*(adj_ang_to_opp(h, angle) + shift),
|
|
w2 = !is_undef(w2)? w2 : w1 - 2*(adj_ang_to_opp(h, angle) + shift),
|
|
chamfs = is_num(chamfer)? [for (i=[0:3]) chamfer] :
|
|
assert(len(chamfer)==4) chamfer,
|
|
rounds = is_num(rounding)? [for (i=[0:3]) rounding] :
|
|
assert(len(rounding)==4) rounding,
|
|
srads = [for (i=[0:3]) rounds[i]? rounds[i] : chamfs[i]],
|
|
rads = v_abs(srads)
|
|
)
|
|
assert(w1>=0 && w2>=0 && h>0, "Degenerate trapezoid geometry.")
|
|
assert(w1+w2>0, "Degenerate trapezoid geometry.")
|
|
let(
|
|
base = [
|
|
[ w2/2+shift, h/2],
|
|
[-w2/2+shift, h/2],
|
|
[-w1/2,-h/2],
|
|
[ w1/2,-h/2],
|
|
],
|
|
ang1 = v_theta(base[0]-base[3])-90,
|
|
ang2 = v_theta(base[1]-base[2])-90,
|
|
angs = [ang1, ang2, ang2, ang1],
|
|
qdirs = [[1,1], [-1,1], [-1,-1], [1,-1]],
|
|
hyps = [for (i=[0:3]) adj_ang_to_hyp(rads[i],angs[i])],
|
|
offs = [
|
|
for (i=[0:3]) let(
|
|
xoff = adj_ang_to_opp(rads[i],angs[i]),
|
|
a = [xoff, -rads[i]] * qdirs[i].y * (srads[i]<0 && flip? -1 : 1),
|
|
b = a + [hyps[i] * qdirs[i].x * (srads[i]<0 && !flip? 1 : -1), 0]
|
|
) b
|
|
],
|
|
cpath = [
|
|
each (
|
|
let(i = 0)
|
|
rads[i] == 0? [base[i]] :
|
|
srads[i] > 0? arc(n=rounds[i]?undef:2, cp=base[i]+offs[i], angle=[angs[i], 90], r=rads[i]) :
|
|
flip? arc(n=rounds[i]?undef:2, cp=base[i]+offs[i], angle=[angs[i],-90], r=rads[i]) :
|
|
arc(n=rounds[i]?undef:2, cp=base[i]+offs[i], angle=[180+angs[i],90], r=rads[i])
|
|
),
|
|
each (
|
|
let(i = 1)
|
|
rads[i] == 0? [base[i]] :
|
|
srads[i] > 0? arc(n=rounds[i]?undef:2, cp=base[i]+offs[i], angle=[90,180+angs[i]], r=rads[i]) :
|
|
flip? arc(n=rounds[i]?undef:2, cp=base[i]+offs[i], angle=[270,180+angs[i]], r=rads[i]) :
|
|
arc(n=rounds[i]?undef:2, cp=base[i]+offs[i], angle=[90,angs[i]], r=rads[i])
|
|
),
|
|
each (
|
|
let(i = 2)
|
|
rads[i] == 0? [base[i]] :
|
|
srads[i] > 0? arc(n=rounds[i]?undef:2, cp=base[i]+offs[i], angle=[180+angs[i],270], r=rads[i]) :
|
|
flip? arc(n=rounds[i]?undef:2, cp=base[i]+offs[i], angle=[180+angs[i],90], r=rads[i]) :
|
|
arc(n=rounds[i]?undef:2, cp=base[i]+offs[i], angle=[angs[i],-90], r=rads[i])
|
|
),
|
|
each (
|
|
let(i = 3)
|
|
rads[i] == 0? [base[i]] :
|
|
srads[i] > 0? arc(n=rounds[i]?undef:2, cp=base[i]+offs[i], angle=[-90,angs[i]], r=rads[i]) :
|
|
flip? arc(n=rounds[i]?undef:2, cp=base[i]+offs[i], angle=[90,angs[i]], r=rads[i]) :
|
|
arc(n=rounds[i]?undef:2, cp=base[i]+offs[i], angle=[270,180+angs[i]], r=rads[i])
|
|
),
|
|
],
|
|
path = reverse(cpath)
|
|
) simple
|
|
? reorient(anchor,spin, two_d=true, size=[w1,h], size2=w2, shift=shift, p=path)
|
|
: reorient(anchor,spin, two_d=true, path=path, p=path);
|
|
|
|
|
|
|
|
module trapezoid(h, w1, w2, angle, shift=0, chamfer=0, rounding=0, flip=false, anchor=CENTER, spin=0) {
|
|
path = trapezoid(h=h, w1=w1, w2=w2, angle=angle, shift=shift, chamfer=chamfer, rounding=rounding, flip=flip);
|
|
union() {
|
|
simple = chamfer==0 && rounding==0;
|
|
h = !is_undef(h)? h : opp_ang_to_adj(abs(w2-w1)/2, abs(angle));
|
|
w1 = !is_undef(w1)? w1 : w2 + 2*(adj_ang_to_opp(h, angle) + shift);
|
|
w2 = !is_undef(w2)? w2 : w1 - 2*(adj_ang_to_opp(h, angle) + shift);
|
|
if (simple) {
|
|
attachable(anchor,spin, two_d=true, size=[w1,h], size2=w2, shift=shift) {
|
|
polygon(path);
|
|
children();
|
|
}
|
|
} else {
|
|
attachable(anchor,spin, two_d=true, path=path) {
|
|
polygon(path);
|
|
children();
|
|
}
|
|
}
|
|
}
|
|
}
|
|
|
|
|
|
|
|
// Function&Module: star()
|
|
// Usage: As Module
|
|
// star(n, r/or, ir, [realign=], [align_tip=], [align_pit=], ...);
|
|
// star(n, r/or, step=, ...);
|
|
// Usage: With Attachments
|
|
// star(n, r/or, ir, ...) { attachments }
|
|
// Usage: As Function
|
|
// path = star(n, r/or, ir, [realign=], [align_tip=], [align_pit=], ...);
|
|
// path = star(n, r/or, step=, ...);
|
|
// Topics: Shapes (2D), Paths (2D), Path Generators, Attachable
|
|
// See Also: circle(), ellipse()
|
|
// Description:
|
|
// When called as a function, returns the path needed to create a star polygon with N points.
|
|
// When called as a module, creates a star polygon with N points.
|
|
// Arguments:
|
|
// n = The number of stellate tips on the star.
|
|
// r/or = The radius to the tips of the star.
|
|
// ir = The radius to the inner corners of the star.
|
|
// ---
|
|
// d/od = The diameter to the tips of the star.
|
|
// id = The diameter to the inner corners of the star.
|
|
// step = Calculates the radius of the inner star corners by virtually drawing a straight line `step` tips around the star. 2 <= step < n/2
|
|
// realign = If false, vertex 0 will lie on the X+ axis. If true then the midpoint of the last edge will lie on the X+ axis, and vertex 0 will be below the X axis. Default: false
|
|
// align_tip = If given as a 2D vector, rotates the whole shape so that the first star tip points in that direction. This occurs before spin.
|
|
// align_pit = If given as a 2D vector, rotates the whole shape so that the first inner corner is pointed towards that direction. This occurs before spin.
|
|
// anchor = Translate so anchor point is at origin (0,0,0). See [anchor](attachments.scad#subsection-anchor). Default: `CENTER`
|
|
// spin = Rotate this many degrees around the Z axis after anchor. See [spin](attachments.scad#subsection-spin). Default: `0`
|
|
// atype = Choose "hull" or "intersect" anchor methods. Default: "hull"
|
|
// Extra Anchors:
|
|
// "tip0" ... "tip4" = Each tip has an anchor, pointing outwards.
|
|
// "pit0" ... "pit4" = The inside corner between each tip has an anchor, pointing outwards.
|
|
// "midpt0" ... "midpt4" = The center-point between each pair of tips has an anchor, pointing outwards.
|
|
// Examples(2D):
|
|
// star(n=5, r=50, ir=25);
|
|
// star(n=5, r=50, step=2);
|
|
// star(n=7, r=50, step=2);
|
|
// star(n=7, r=50, step=3);
|
|
// Example(2D): Realigned
|
|
// star(n=7, r=50, step=3, realign=true);
|
|
// Example(2D): Alignment by Tip
|
|
// star(n=5, ir=15, or=30, align_tip=BACK+RIGHT)
|
|
// attach("tip0", FWD) color("blue")
|
|
// stroke([[0,0],[0,7]], endcap2="arrow2");
|
|
// Example(2D): Alignment by Pit
|
|
// star(n=5, ir=15, or=30, align_pit=BACK+RIGHT)
|
|
// attach("pit0", FWD) color("blue")
|
|
// stroke([[0,0],[0,7]], endcap2="arrow2");
|
|
// Example(2D): Called as Function
|
|
// stroke(closed=true, star(n=5, r=50, ir=25));
|
|
function star(n, r, ir, d, or, od, id, step, realign=false, align_tip, align_pit, anchor=CENTER, spin=0, atype="hull", _mat, _anchs) =
|
|
assert(in_list(atype, _ANCHOR_TYPES), "Anchor type must be \"hull\" or \"intersect\"")
|
|
assert(is_undef(align_tip) || is_vector(align_tip))
|
|
assert(is_undef(align_pit) || is_vector(align_pit))
|
|
assert(is_undef(align_tip) || is_undef(align_pit), "Can only specify one of align_tip and align_pit")
|
|
assert(is_def(n), "Must specify number of points, n")
|
|
let(
|
|
r = get_radius(r1=or, d1=od, r=r, d=d),
|
|
count = num_defined([ir,id,step]),
|
|
stepOK = is_undef(step) || (step>1 && step<n/2)
|
|
)
|
|
assert(count==1, "Must specify exactly one of ir, id, step")
|
|
assert(stepOK, n==4 ? "Parameter 'step' not allowed for 4 point stars"
|
|
: n==5 || n==6 ? str("Parameter 'step' must be 2 for ",n," point stars")
|
|
: str("Parameter 'step' must be between 2 and ",floor(n/2-1/2)," for ",n," point stars"))
|
|
let(
|
|
mat = !is_undef(_mat) ? _mat :
|
|
( realign? zrot(-180/n) : ident(4) ) * (
|
|
!is_undef(align_tip)? rot(from=RIGHT, to=point2d(align_tip)) :
|
|
!is_undef(align_pit)? rot(from=RIGHT, to=point2d(align_pit)) * zrot(180/n) :
|
|
1
|
|
),
|
|
stepr = is_undef(step)? r : r*cos(180*step/n)/cos(180*(step-1)/n),
|
|
ir = get_radius(r=ir, d=id, dflt=stepr),
|
|
offset = realign? 180/n : 0,
|
|
path1 = [for(i=[2*n:-1:1]) let(theta=180*i/n, radius=(i%2)?ir:r) radius*[cos(theta), sin(theta)]],
|
|
path = apply(mat, path1),
|
|
anchors = !is_undef(_anchs) ? _anchs :
|
|
!is_string(anchor)? [] : [
|
|
for (i = [0:1:n-1]) let(
|
|
a1 = 360 - i*360/n,
|
|
a2 = a1 - 180/n,
|
|
a3 = a1 - 360/n,
|
|
p1 = apply(mat, polar_to_xy(r,a1)),
|
|
p2 = apply(mat, polar_to_xy(ir,a2)),
|
|
p3 = apply(mat, polar_to_xy(r,a3)),
|
|
pos = (p1+p3)/2
|
|
) each [
|
|
named_anchor(str("tip",i), p1, unit(p1,BACK), 0),
|
|
named_anchor(str("pit",i), p2, unit(p2,BACK), 0),
|
|
named_anchor(str("midpt",i), pos, unit(pos,BACK), 0),
|
|
]
|
|
]
|
|
) reorient(anchor,spin, two_d=true, path=path, p=path, extent=atype=="hull", anchors=anchors);
|
|
|
|
|
|
module star(n, r, ir, d, or, od, id, step, realign=false, align_tip, align_pit, anchor=CENTER, spin=0, atype="hull") {
|
|
assert(in_list(atype, _ANCHOR_TYPES), "Anchor type must be \"hull\" or \"intersect\"");
|
|
assert(is_undef(align_tip) || is_vector(align_tip));
|
|
assert(is_undef(align_pit) || is_vector(align_pit));
|
|
assert(is_undef(align_tip) || is_undef(align_pit), "Can only specify one of align_tip and align_pit");
|
|
r = get_radius(r1=or, d1=od, r=r, d=d, dflt=undef);
|
|
stepr = is_undef(step)? r : r*cos(180*step/n)/cos(180*(step-1)/n);
|
|
ir = get_radius(r=ir, d=id, dflt=stepr);
|
|
mat = ( realign? zrot(-180/n) : ident(4) ) * (
|
|
!is_undef(align_tip)? rot(from=RIGHT, to=point2d(align_tip)) :
|
|
!is_undef(align_pit)? rot(from=RIGHT, to=point2d(align_pit)) * zrot(180/n) :
|
|
1
|
|
);
|
|
anchors = [
|
|
for (i = [0:1:n-1]) let(
|
|
a1 = 360 - i*360/n - (realign? 180/n : 0),
|
|
a2 = a1 - 180/n,
|
|
a3 = a1 - 360/n,
|
|
p1 = apply(mat, polar_to_xy(r,a1)),
|
|
p2 = apply(mat, polar_to_xy(ir,a2)),
|
|
p3 = apply(mat, polar_to_xy(r,a3)),
|
|
pos = (p1+p3)/2
|
|
) each [
|
|
named_anchor(str("tip",i), p1, unit(p1,BACK), 0),
|
|
named_anchor(str("pit",i), p2, unit(p2,BACK), 0),
|
|
named_anchor(str("midpt",i), pos, unit(pos,BACK), 0),
|
|
]
|
|
];
|
|
path = star(n=n, r=r, ir=ir, realign=realign, _mat=mat, _anchs=anchors);
|
|
attachable(anchor,spin, two_d=true, path=path, extent=atype=="hull", anchors=anchors) {
|
|
polygon(path);
|
|
children();
|
|
}
|
|
}
|
|
|
|
|
|
|
|
/// Internal Function: _path_add_jitter()
|
|
/// Topics: Paths
|
|
/// See Also: jittered_poly()
|
|
/// Usage:
|
|
/// jpath = _path_add_jitter(path, [dist], [closed=]);
|
|
/// Description:
|
|
/// Adds tiny jitter offsets to collinear points in the given path so that they
|
|
/// are no longer collinear. This is useful for preserving subdivision on long
|
|
/// straight segments, when making geometry with `polygon()`, for use with
|
|
/// `linear_exrtrude()` with a `twist()`.
|
|
/// Arguments:
|
|
/// path = The path to add jitter to.
|
|
/// dist = The amount to jitter points by. Default: 1/512 (0.00195)
|
|
/// ---
|
|
/// closed = If true, treat path like a closed polygon. Default: true
|
|
/// Example(3D):
|
|
/// d = 100; h = 75; quadsize = 5;
|
|
/// path = pentagon(d=d);
|
|
/// spath = subdivide_path(path, maxlen=quadsize, closed=true);
|
|
/// jpath = _path_add_jitter(spath, closed=true);
|
|
/// linear_extrude(height=h, twist=72, slices=h/quadsize)
|
|
/// polygon(jpath);
|
|
function _path_add_jitter(path, dist=1/512, closed=true) =
|
|
assert(is_path(path))
|
|
assert(is_finite(dist))
|
|
assert(is_bool(closed))
|
|
[
|
|
path[0],
|
|
for (i=idx(path,s=1,e=closed?-1:-2)) let(
|
|
n = line_normal([path[i-1],path[i]])
|
|
) path[i] + n * (is_collinear(select(path,i-1,i+1))? (dist * ((i%2)*2-1)) : 0),
|
|
if (!closed) last(path)
|
|
];
|
|
|
|
|
|
|
|
// Module: jittered_poly()
|
|
// Topics: Extrusions
|
|
// See Also: subdivide_path()
|
|
// Usage:
|
|
// jittered_poly(path, [dist]);
|
|
// Description:
|
|
// Creates a 2D polygon shape from the given path in such a way that any extra
|
|
// collinear points are not stripped out in the way that `polygon()` normally does.
|
|
// This is useful for refining the mesh of a `linear_extrude()` with twist.
|
|
// Arguments:
|
|
// path = The path to add jitter to.
|
|
// dist = The amount to jitter points by. Default: 1/512 (0.00195)
|
|
// Example:
|
|
// d = 100; h = 75; quadsize = 5;
|
|
// path = pentagon(d=d);
|
|
// spath = subdivide_path(path, maxlen=quadsize, closed=true);
|
|
// linear_extrude(height=h, twist=72, slices=h/quadsize)
|
|
// jittered_poly(spath);
|
|
module jittered_poly(path, dist=1/512) {
|
|
polygon(_path_add_jitter(path, dist, closed=true));
|
|
}
|
|
|
|
|
|
|
|
// Section: Curved 2D Shapes
|
|
|
|
|
|
// Function&Module: teardrop2d()
|
|
//
|
|
// Description:
|
|
// Makes a 2D teardrop shape. Useful for extruding into 3D printable holes. Uses "intersect" style anchoring.
|
|
//
|
|
// Usage: As Module
|
|
// teardrop2d(r/d=, [ang], [cap_h]);
|
|
// Usage: With Attachments
|
|
// teardrop2d(r/d=, [ang], [cap_h], ...) { attachments }
|
|
// Usage: As Function
|
|
// path = teardrop2d(r/d=, [ang], [cap_h]);
|
|
//
|
|
// Topics: Shapes (2D), Paths (2D), Path Generators, Attachable
|
|
//
|
|
// See Also: teardrop(), onion()
|
|
//
|
|
// Arguments:
|
|
// r = radius of circular part of teardrop. (Default: 1)
|
|
// ang = angle of hat walls from the Y axis. (Default: 45 degrees)
|
|
// cap_h = if given, height above center where the shape will be truncated.
|
|
// ---
|
|
// d = diameter of spherical portion of bottom. (Use instead of r)
|
|
// anchor = Translate so anchor point is at origin (0,0,0). See [anchor](attachments.scad#subsection-anchor). Default: `CENTER`
|
|
// spin = Rotate this many degrees around the Z axis after anchor. See [spin](attachments.scad#subsection-spin). Default: `0`
|
|
//
|
|
// Example(2D): Typical Shape
|
|
// teardrop2d(r=30, ang=30);
|
|
// Example(2D): Crop Cap
|
|
// teardrop2d(r=30, ang=30, cap_h=40);
|
|
// Example(2D): Close Crop
|
|
// teardrop2d(r=30, ang=30, cap_h=20);
|
|
module teardrop2d(r, ang=45, cap_h, d, anchor=CENTER, spin=0)
|
|
{
|
|
path = teardrop2d(r=r, d=d, ang=ang, cap_h=cap_h);
|
|
attachable(anchor,spin, two_d=true, path=path, extent=false) {
|
|
polygon(path);
|
|
children();
|
|
}
|
|
}
|
|
|
|
|
|
function teardrop2d(r, ang=45, cap_h, d, anchor=CENTER, spin=0) =
|
|
let(
|
|
r = get_radius(r=r, d=d, dflt=1),
|
|
ang2 = 90-ang,
|
|
prepath = zrot(90, p=circle(r=r)),
|
|
eps=1e-9,
|
|
prepath2 = [for (p=prepath) let(a=atan2(p.y,p.x)) if(a<=90-ang2+eps || a>=90+ang2-eps) p],
|
|
hyp = is_undef(cap_h)
|
|
? opp_ang_to_hyp(abs(prepath2[0].x), ang)
|
|
: adj_ang_to_hyp(cap_h-prepath2[0].y, ang),
|
|
p1 = prepath2[0] + polar_to_xy(hyp, 90+ang),
|
|
p2 = last(prepath2) + polar_to_xy(hyp, 90-ang),
|
|
path = deduplicate([p1, each prepath2, p2], closed=true)
|
|
) reorient(anchor,spin, two_d=true, path=path, p=path, extent=false);
|
|
|
|
|
|
|
|
// Function&Module: egg()
|
|
// Usage: As Module
|
|
// egg(length, r1, r2, R);
|
|
// Usage: As Function
|
|
// path = egg(length, r1|d2, r2|d2, R|D);
|
|
// Topics: Shapes (2D), Paths (2D), Path Generators, Attachable
|
|
// See Also: circle(), ellipse(), glued_circles()
|
|
// Description:
|
|
// Constructs an egg-shaped object by connecting two circles with convex arcs that are tangent to the circles.
|
|
// You specify the length of the egg, the radii of the two circles, and the desired arc radius.
|
|
// Note that because the side radius, R, is often much larger than the end radii, you may get better
|
|
// results using `$fs` and `$fa` to control the number of semgments rather than using `$fn`.
|
|
// This shape may be useful for creating a cam.
|
|
// Arguments:
|
|
// length = length of the egg
|
|
// r1 = radius of the left-hand circle
|
|
// r2 = radius of the right-hand circle
|
|
// R = radius of the joining arcs
|
|
// ---
|
|
// d1 = diameter of the left-hand circle
|
|
// d2 = diameter of the right-hand circle
|
|
// D = diameter of the joining arcs
|
|
// Extra Anchors:
|
|
// "left" = center of the left circle
|
|
// "right" = center of the right circle
|
|
// Example(2D,NoAxes): This first example shows how the egg is constructed from two circles and two joining arcs.
|
|
// $fn=100;
|
|
// color("red") stroke(egg(78,25,12, 60),closed=true);
|
|
// stroke([left(14,circle(25)),
|
|
// right(27,circle(12))]);
|
|
// Example(2D,Anim,VPD=250,VPR=[0,0,0]): Varying length between circles
|
|
// r1 = 25; r2 = 12; R = 65;
|
|
// length = floor(lookup($t, [[0,55], [0.5,90], [1,55]]));
|
|
// egg(length,r1,r2,R,$fn=180);
|
|
// color("black") text(str("length=",length), size=8, halign="center", valign="center");
|
|
// Example(2D,Anim,VPD=250,VPR=[0,0,0]): Varying tangent arc radius R
|
|
// length = 78; r1 = 25; r2 = 12;
|
|
// R = floor(lookup($t, [[0,45], [0.5,150], [1,45]]));
|
|
// egg(length,r1,r2,R,$fn=180);
|
|
// color("black") text(str("R=",R), size=8, halign="center", valign="center");
|
|
// Example(2D,Anim,VPD=250,VPR=[0,0,0]): Varying circle radius r2
|
|
// length = 78; r1 = 25; R = 65;
|
|
// r2 = floor(lookup($t, [[0,5], [0.5,30], [1,5]]));
|
|
// egg(length,r1,r2,R,$fn=180);
|
|
// color("black") text(str("r2=",r2), size=8, halign="center", valign="center");
|
|
function egg(length, r1, r2, R, d1, d2, D, anchor=CENTER, spin=0) =
|
|
let(
|
|
r1 = get_radius(r1=r1,d1=d1),
|
|
r2 = get_radius(r1=r2,d1=d2),
|
|
D = get_radius(r1=R, d1=D)
|
|
)
|
|
assert(length>0)
|
|
assert(R>length/2, "Side radius R must be larger than length/2")
|
|
assert(length>r1+r2, "Length must be longer than 2*(r1+r2)")
|
|
assert(length>2*r2, "Length must be longer than 2*r2")
|
|
assert(length>2*r1, "Length must be longer than 2*r1")
|
|
let(
|
|
c1 = [-length/2+r1,0],
|
|
c2 = [length/2-r2,0],
|
|
Rmin = (r1+r2+norm(c1-c2))/2,
|
|
Mlist = circle_circle_intersection(c1,R-r1,c2,R-r2),
|
|
arcparms = reverse([for(M=Mlist) [M, c1+r1*unit(c1-M), c2+r2*unit(c2-M)]]),
|
|
path = concat(
|
|
arc(r=r2, cp=c2, points=[[length/2,0],arcparms[0][2]],endpoint=false),
|
|
arc(r=R, cp=arcparms[0][0], points=select(arcparms[0],[2,1]),endpoint=false),
|
|
arc(r=r1, points=[arcparms[0][1], [-length/2,0], arcparms[1][1]],endpoint=false),
|
|
arc(r=R, cp=arcparms[1][0], points=select(arcparms[1],[1,2]),endpoint=false),
|
|
arc(r=r2, cp=c2, points=[arcparms[1][2], [length/2,0]],endpoint=false)
|
|
),
|
|
anchors = [named_anchor("left", c1, BACK, 0),
|
|
named_anchor("right", c2, BACK, 0)]
|
|
)
|
|
reorient(anchor, spin, two_d=true, path=path, extent=true, p=path, anchors=anchors);
|
|
|
|
module egg(length,r1,r2,R,d1,d2,D,anchor=CENTER, spin=0)
|
|
{
|
|
path = egg(length,r1,r2,R,d1,d2,D);
|
|
anchors = [named_anchor("left", [-length/2+r1,0], BACK, 0),
|
|
named_anchor("right", [length/2-r2,0], BACK, 0)];
|
|
attachable(anchor, spin, two_d=true, path=path, extent=true, anchors=anchors){
|
|
polygon(path);
|
|
children();
|
|
}
|
|
}
|
|
|
|
|
|
|
|
// Function&Module: glued_circles()
|
|
// Usage: As Module
|
|
// glued_circles(r/d=, [spread=], [tangent=], ...);
|
|
// Usage: With Attachments
|
|
// glued_circles(r/d=, [spread=], [tangent=], ...) { attachments }
|
|
// Usage: As Function
|
|
// path = glued_circles(r/d=, [spread=], [tangent=], ...);
|
|
// Topics: Shapes (2D), Paths (2D), Path Generators, Attachable
|
|
// See Also: circle(), ellipse(), egg()
|
|
// Description:
|
|
// When called as a function, returns a 2D path forming a shape of two circles joined by curved waist.
|
|
// When called as a module, creates a 2D shape of two circles joined by curved waist. Uses "hull" style anchoring.
|
|
// Arguments:
|
|
// r = The radius of the end circles.
|
|
// spread = The distance between the centers of the end circles. Default: 10
|
|
// tangent = The angle in degrees of the tangent point for the joining arcs, measured away from the Y axis. Default: 30
|
|
// ---
|
|
// d = The diameter of the end circles.
|
|
// anchor = Translate so anchor point is at origin (0,0,0). See [anchor](attachments.scad#subsection-anchor). Default: `CENTER`
|
|
// spin = Rotate this many degrees around the Z axis after anchor. See [spin](attachments.scad#subsection-spin). Default: `0`
|
|
// Examples(2D):
|
|
// glued_circles(r=15, spread=40, tangent=45);
|
|
// glued_circles(d=30, spread=30, tangent=30);
|
|
// glued_circles(d=30, spread=30, tangent=15);
|
|
// glued_circles(d=30, spread=30, tangent=-30);
|
|
// Example(2D): Called as Function
|
|
// stroke(closed=true, glued_circles(r=15, spread=40, tangent=45));
|
|
function glued_circles(r, spread=10, tangent=30, d, anchor=CENTER, spin=0) =
|
|
let(
|
|
r = get_radius(r=r, d=d, dflt=10),
|
|
r2 = (spread/2 / sin(tangent)) - r,
|
|
cp1 = [spread/2, 0],
|
|
cp2 = [0, (r+r2)*cos(tangent)],
|
|
sa1 = 90-tangent,
|
|
ea1 = 270+tangent,
|
|
lobearc = ea1-sa1,
|
|
lobesegs = ceil(segs(r)*lobearc/360),
|
|
sa2 = 270-tangent,
|
|
ea2 = 270+tangent,
|
|
subarc = ea2-sa2,
|
|
arcsegs = ceil(segs(r2)*abs(subarc)/360),
|
|
// In the tangent zero case the inner curves are missing so we need to complete the two
|
|
// outer curves. In the other case the inner curves are present and endpoint=false
|
|
// prevents point duplication.
|
|
path = tangent==0 ?
|
|
concat(arc(n=lobesegs+1, r=r, cp=-cp1, angle=[sa1,ea1]),
|
|
arc(n=lobesegs+1, r=r, cp=cp1, angle=[sa1+180,ea1+180]))
|
|
:
|
|
concat(arc(n=lobesegs, r=r, cp=-cp1, angle=[sa1,ea1], endpoint=false),
|
|
[for(theta=lerpn(ea2+180,ea2-subarc+180,arcsegs,endpoint=false)) r2*[cos(theta),sin(theta)] - cp2],
|
|
arc(n=lobesegs, r=r, cp=cp1, angle=[sa1+180,ea1+180], endpoint=false),
|
|
[for(theta=lerpn(ea2,ea2-subarc,arcsegs,endpoint=false)) r2*[cos(theta),sin(theta)] + cp2]),
|
|
maxx_idx = max_index(column(path,0)),
|
|
path2 = reverse_polygon(list_rotate(path,maxx_idx))
|
|
) reorient(anchor,spin, two_d=true, path=path2, extent=true, p=path2);
|
|
|
|
|
|
module glued_circles(r, spread=10, tangent=30, d, anchor=CENTER, spin=0) {
|
|
path = glued_circles(r=r, d=d, spread=spread, tangent=tangent);
|
|
attachable(anchor,spin, two_d=true, path=path, extent=true) {
|
|
polygon(path);
|
|
children();
|
|
}
|
|
}
|
|
|
|
|
|
|
|
function _superformula(theta,m1,m2,n1,n2=1,n3=1,a=1,b=1) =
|
|
pow(pow(abs(cos(m1*theta/4)/a),n2)+pow(abs(sin(m2*theta/4)/b),n3),-1/n1);
|
|
|
|
// Function&Module: supershape()
|
|
// Usage: As Module
|
|
// supershape(step, [m1=], [m2=], [n1=], [n2=], [n3=], [a=], [b=], <r=/d=>);
|
|
// Usage: With Attachments
|
|
// supershape(step, [m1=], [m2=], [n1=], [n2=], [n3=], [a=], [b=], <r=/d=>) { attachments }
|
|
// Usage: As Function
|
|
// path = supershape(step, [m1=], [m2=], [n1=], [n2=], [n3=], [a=], [b=], <r=/d=>);
|
|
// Topics: Shapes (2D), Paths (2D), Path Generators, Attachable
|
|
// See Also: circle(), ellipse()
|
|
// Description:
|
|
// When called as a function, returns a 2D path for the outline of the [Superformula](https://en.wikipedia.org/wiki/Superformula) shape.
|
|
// When called as a module, creates a 2D [Superformula](https://en.wikipedia.org/wiki/Superformula) shape.
|
|
// Note that the "hull" type anchoring (the default) is more intuitive for concave star-like shapes, but the anchor points do not
|
|
// necesarily lie on the line of the anchor vector, which can be confusing, especially for simpler, ellipse-like shapes.
|
|
// Arguments:
|
|
// step = The angle step size for sampling the superformula shape. Smaller steps are slower but more accurate.
|
|
// m1 = The m1 argument for the superformula. Default: 4.
|
|
// m2 = The m2 argument for the superformula. Default: m1.
|
|
// n1 = The n1 argument for the superformula. Default: 1.
|
|
// n2 = The n2 argument for the superformula. Default: n1.
|
|
// n3 = The n3 argument for the superformula. Default: n2.
|
|
// a = The a argument for the superformula. Default: 1.
|
|
// b = The b argument for the superformula. Default: a.
|
|
// r = Radius of the shape. Scale shape to fit in a circle of radius r.
|
|
// ---
|
|
// d = Diameter of the shape. Scale shape to fit in a circle of diameter d.
|
|
// anchor = Translate so anchor point is at origin (0,0,0). See [anchor](attachments.scad#subsection-anchor). Default: `CENTER`
|
|
// spin = Rotate this many degrees around the Z axis after anchor. See [spin](attachments.scad#subsection-spin). Default: `0`
|
|
// atype = Select "hull" or "intersect" style anchoring. Default: "hull".
|
|
// Example(2D):
|
|
// supershape(step=0.5,m1=16,m2=16,n1=0.5,n2=0.5,n3=16,r=50);
|
|
// Example(2D): Called as Function
|
|
// stroke(closed=true, supershape(step=0.5,m1=16,m2=16,n1=0.5,n2=0.5,n3=16,d=100));
|
|
// Examples(2D,Med):
|
|
// for(n=[2:5]) right(2.5*(n-2)) supershape(m1=4,m2=4,n1=n,a=1,b=2); // Superellipses
|
|
// m=[2,3,5,7]; for(i=[0:3]) right(2.5*i) supershape(.5,m1=m[i],n1=1);
|
|
// m=[6,8,10,12]; for(i=[0:3]) right(2.7*i) supershape(.5,m1=m[i],n1=1,b=1.5); // m should be even
|
|
// m=[1,2,3,5]; for(i=[0:3]) fwd(1.5*i) supershape(m1=m[i],n1=0.4);
|
|
// supershape(m1=5, n1=4, n2=1); right(2.5) supershape(m1=5, n1=40, n2=10);
|
|
// m=[2,3,5,7]; for(i=[0:3]) right(2.5*i) supershape(m1=m[i], n1=60, n2=55, n3=30);
|
|
// n=[0.5,0.2,0.1,0.02]; for(i=[0:3]) right(2.5*i) supershape(m1=5,n1=n[i], n2=1.7);
|
|
// supershape(m1=2, n1=1, n2=4, n3=8);
|
|
// supershape(m1=7, n1=2, n2=8, n3=4);
|
|
// supershape(m1=7, n1=3, n2=4, n3=17);
|
|
// supershape(m1=4, n1=1/2, n2=1/2, n3=4);
|
|
// supershape(m1=4, n1=4.0,n2=16, n3=1.5, a=0.9, b=9);
|
|
// for(i=[1:4]) right(3*i) supershape(m1=i, m2=3*i, n1=2);
|
|
// m=[4,6,10]; for(i=[0:2]) right(i*5) supershape(m1=m[i], n1=12, n2=8, n3=5, a=2.7);
|
|
// for(i=[-1.5:3:1.5]) right(i*1.5) supershape(m1=2,m2=10,n1=i,n2=1);
|
|
// for(i=[1:3],j=[-1,1]) translate([3.5*i,1.5*j])supershape(m1=4,m2=6,n1=i*j,n2=1);
|
|
// for(i=[1:3]) right(2.5*i)supershape(step=.5,m1=88, m2=64, n1=-i*i,n2=1,r=1);
|
|
// Examples:
|
|
// linear_extrude(height=0.3, scale=0) supershape(step=1, m1=6, n1=0.4, n2=0, n3=6);
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// linear_extrude(height=5, scale=0) supershape(step=1, b=3, m1=6, n1=3.8, n2=16, n3=10);
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function supershape(step=0.5, m1=4, m2, n1=1, n2, n3, a=1, b, r, d,anchor=CENTER, spin=0, atype="hull") =
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assert(in_list(atype, _ANCHOR_TYPES), "Anchor type must be \"hull\" or \"intersect\"")
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|
let(
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|
|
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r = get_radius(r=r, d=d, dflt=undef),
|
|
m2 = is_def(m2) ? m2 : m1,
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|
n2 = is_def(n2) ? n2 : n1,
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|
n3 = is_def(n3) ? n3 : n2,
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|
b = is_def(b) ? b : a,
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|
steps = ceil(360/step),
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|
step = 360/steps,
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|
angs = [for (i = [0:steps]) step*i],
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|
rads = [for (theta = angs) _superformula(theta=theta,m1=m1,m2=m2,n1=n1,n2=n2,n3=n3,a=a,b=b)],
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|
scale = is_def(r) ? r/max(rads) : 1,
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path = [for (i = [steps:-1:1]) let(a=angs[i]) scale*rads[i]*[cos(a), sin(a)]]
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) reorient(anchor,spin, two_d=true, path=path, p=path, extent=atype=="hull");
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|
|
|
module supershape(step=0.5,m1=4,m2=undef,n1,n2=undef,n3=undef,a=1,b=undef, r=undef, d=undef, anchor=CENTER, spin=0, atype="hull") {
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|
assert(in_list(atype, _ANCHOR_TYPES), "Anchor type must be \"hull\" or \"intersect\"");
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path = supershape(step=step,m1=m1,m2=m2,n1=n1,n2=n2,n3=n3,a=a,b=b,r=r,d=d);
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attachable(anchor,spin,extent=atype=="hull", two_d=true, path=path) {
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|
polygon(path);
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|
children();
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|
}
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|
}
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// Function&Module: reuleaux_polygon()
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// Usage: As Module
|
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// reuleaux_polygon(n, r|d, ...);
|
|
// Usage: As Function
|
|
// path = reuleaux_polygon(n, r|d, ...);
|
|
// Topics: Shapes (2D), Paths (2D), Path Generators, Attachable
|
|
// See Also: regular_ngon(), pentagon(), hexagon(), octagon()
|
|
// Description:
|
|
// Creates a 2D Reuleaux Polygon; a constant width shape that is not circular. Uses "intersect" type anchoring.
|
|
// Arguments:
|
|
// n = Number of "sides" to the Reuleaux Polygon. Must be an odd positive number. Default: 3
|
|
// r = Radius of the shape. Scale shape to fit in a circle of radius r.
|
|
// ---
|
|
// d = Diameter of the shape. Scale shape to fit in a circle of diameter d.
|
|
// anchor = Translate so anchor point is at origin (0,0,0). See [anchor](attachments.scad#subsection-anchor). Default: `CENTER`
|
|
// spin = Rotate this many degrees around the Z axis after anchor. See [spin](attachments.scad#subsection-spin). Default: `0`
|
|
// Extra Anchors:
|
|
// "tip0", "tip1", etc. = Each tip has an anchor, pointing outwards.
|
|
// Examples(2D):
|
|
// reuleaux_polygon(n=3, r=50);
|
|
// reuleaux_polygon(n=5, d=100);
|
|
// Examples(2D): Standard vector anchors are based on extents
|
|
// reuleaux_polygon(n=3, d=50) show_anchors(custom=false);
|
|
// Examples(2D): Named anchors exist for the tips
|
|
// reuleaux_polygon(n=3, d=50) show_anchors(std=false);
|
|
module reuleaux_polygon(n=3, r, d, anchor=CENTER, spin=0) {
|
|
assert(n>=3 && (n%2)==1);
|
|
r = get_radius(r=r, d=d, dflt=1);
|
|
path = reuleaux_polygon(n=n, r=r);
|
|
anchors = [
|
|
for (i = [0:1:n-1]) let(
|
|
ca = 360 - i * 360/n,
|
|
cp = polar_to_xy(r, ca)
|
|
) named_anchor(str("tip",i), cp, unit(cp,BACK), 0),
|
|
];
|
|
attachable(anchor,spin, two_d=true, path=path, extent=false, anchors=anchors) {
|
|
polygon(path);
|
|
children();
|
|
}
|
|
}
|
|
|
|
|
|
function reuleaux_polygon(n=3, r, d, anchor=CENTER, spin=0) =
|
|
assert(n>=3 && (n%2)==1)
|
|
let(
|
|
r = get_radius(r=r, d=d, dflt=1),
|
|
ssegs = max(3,ceil(segs(r)/n)),
|
|
slen = norm(polar_to_xy(r,0)-polar_to_xy(r,180-180/n)),
|
|
path = [
|
|
for (i = [0:1:n-1]) let(
|
|
ca = 180 - (i+0.5) * 360/n,
|
|
sa = ca + 180 + (90/n),
|
|
ea = ca + 180 - (90/n),
|
|
cp = polar_to_xy(r, ca)
|
|
) each arc(n=ssegs-1, r=slen, cp=cp, angle=[sa,ea], endpoint=false)
|
|
],
|
|
anchors = [
|
|
for (i = [0:1:n-1]) let(
|
|
ca = 360 - i * 360/n,
|
|
cp = polar_to_xy(r, ca)
|
|
) named_anchor(str("tip",i), cp, unit(cp,BACK), 0),
|
|
]
|
|
) reorient(anchor,spin, two_d=true, path=path, extent=false, anchors=anchors, p=path);
|
|
|
|
|
|
|
|
// Section: Text
|
|
|
|
// Module: text()
|
|
// Topics: Attachments, Text
|
|
// Usage:
|
|
// text(text, [size], [font], ...);
|
|
// Description:
|
|
// Creates a 3D text block that can be attached to other attachable objects.
|
|
// NOTE: This cannot have children attached to it.
|
|
// Arguments:
|
|
// text = The text string to instantiate as an object.
|
|
// size = The font size used to create the text block. Default: 10
|
|
// font = The name of the font used to create the text block. Default: "Helvetica"
|
|
// ---
|
|
// halign = If given, specifies the horizontal alignment of the text. `"left"`, `"center"`, or `"right"`. Overrides `anchor=`.
|
|
// valign = If given, specifies the vertical alignment of the text. `"top"`, `"center"`, `"baseline"` or `"bottom"`. Overrides `anchor=`.
|
|
// spacing = The relative spacing multiplier between characters. Default: `1.0`
|
|
// direction = The text direction. `"ltr"` for left to right. `"rtl"` for right to left. `"ttb"` for top to bottom. `"btt"` for bottom to top. Default: `"ltr"`
|
|
// language = The language the text is in. Default: `"en"`
|
|
// script = The script the text is in. Default: `"latin"`
|
|
// anchor = Translate so anchor point is at origin (0,0,0). See [anchor](attachments.scad#subsection-anchor). Default: `"baseline"`
|
|
// spin = Rotate this many degrees around the Z axis. See [spin](attachments.scad#subsection-spin). Default: `0`
|
|
// See Also: attachable()
|
|
// Extra Anchors:
|
|
// "baseline" = Anchors at the baseline of the text, at the start of the string.
|
|
// str("baseline",VECTOR) = Anchors at the baseline of the text, modified by the X and Z components of the appended vector.
|
|
// Examples(2D):
|
|
// text("Foobar", size=10);
|
|
// text("Foobar", size=12, font="Helvetica");
|
|
// text("Foobar", anchor=CENTER);
|
|
// text("Foobar", anchor=str("baseline",CENTER));
|
|
// Example: Using line_of() distributor
|
|
// txt = "This is the string.";
|
|
// line_of(spacing=[10,-5],n=len(txt))
|
|
// text(txt[$idx], size=10, anchor=CENTER);
|
|
// Example: Using arc_of() distributor
|
|
// txt = "This is the string";
|
|
// arc_of(r=50, n=len(txt), sa=0, ea=180)
|
|
// text(select(txt,-1-$idx), size=10, anchor=str("baseline",CENTER), spin=-90);
|
|
module text(text, size=10, font="Helvetica", halign, valign, spacing=1.0, direction="ltr", language="en", script="latin", anchor="baseline", spin=0) {
|
|
no_children($children);
|
|
dummy1 =
|
|
assert(is_undef(anchor) || is_vector(anchor) || is_string(anchor), str("Got: ",anchor))
|
|
assert(is_undef(spin) || is_vector(spin,3) || is_num(spin), str("Got: ",spin));
|
|
anchor = default(anchor, CENTER);
|
|
spin = default(spin, 0);
|
|
geom = _attach_geom(size=[size,size],two_d=true);
|
|
anch = !any([for (c=anchor) c=="["])? anchor :
|
|
let(
|
|
parts = str_split(str_split(str_split(anchor,"]")[0],"[")[1],","),
|
|
vec = [for (p=parts) parse_float(str_strip(p," ",start=true))]
|
|
) vec;
|
|
ha = halign!=undef? halign :
|
|
anchor=="baseline"? "left" :
|
|
anchor==anch && is_string(anchor)? "center" :
|
|
anch.x<0? "left" :
|
|
anch.x>0? "right" :
|
|
"center";
|
|
va = valign != undef? valign :
|
|
starts_with(anchor,"baseline")? "baseline" :
|
|
anchor==anch && is_string(anchor)? "center" :
|
|
anch.y<0? "bottom" :
|
|
anch.y>0? "top" :
|
|
"center";
|
|
base = anchor=="baseline"? CENTER :
|
|
anchor==anch && is_string(anchor)? CENTER :
|
|
anch.z<0? BOTTOM :
|
|
anch.z>0? TOP :
|
|
CENTER;
|
|
m = _attach_transform(base,spin,undef,geom);
|
|
multmatrix(m) {
|
|
$parent_anchor = anchor;
|
|
$parent_spin = spin;
|
|
$parent_orient = undef;
|
|
$parent_geom = geom;
|
|
$parent_size = _attach_geom_size(geom);
|
|
$attach_to = undef;
|
|
do_show = _attachment_is_shown($tags);
|
|
if (do_show) {
|
|
_color($color) {
|
|
_text(
|
|
text=text, size=size, font=font,
|
|
halign=ha, valign=va, spacing=spacing,
|
|
direction=direction, language=language,
|
|
script=script
|
|
);
|
|
}
|
|
}
|
|
}
|
|
}
|
|
|
|
|
|
// Section: Rounding 2D shapes
|
|
|
|
// Module: round2d()
|
|
// Usage:
|
|
// round2d(r) ...
|
|
// round2d(or) ...
|
|
// round2d(ir) ...
|
|
// round2d(or, ir) ...
|
|
// Description:
|
|
// Rounds arbitrary 2D objects. Giving `r` rounds all concave and convex corners. Giving just `ir`
|
|
// rounds just concave corners. Giving just `or` rounds convex corners. Giving both `ir` and `or`
|
|
// can let you round to different radii for concave and convex corners. The 2D object must not have
|
|
// any parts narrower than twice the `or` radius. Such parts will disappear.
|
|
// Arguments:
|
|
// r = Radius to round all concave and convex corners to.
|
|
// or = Radius to round only outside (convex) corners to. Use instead of `r`.
|
|
// ir = Radius to round only inside (concave) corners to. Use instead of `r`.
|
|
// Examples(2D):
|
|
// round2d(r=10) {square([40,100], center=true); square([100,40], center=true);}
|
|
// round2d(or=10) {square([40,100], center=true); square([100,40], center=true);}
|
|
// round2d(ir=10) {square([40,100], center=true); square([100,40], center=true);}
|
|
// round2d(or=16,ir=8) {square([40,100], center=true); square([100,40], center=true);}
|
|
module round2d(r, or, ir)
|
|
{
|
|
or = get_radius(r1=or, r=r, dflt=0);
|
|
ir = get_radius(r1=ir, r=r, dflt=0);
|
|
offset(or) offset(-ir-or) offset(delta=ir,chamfer=true) children();
|
|
}
|
|
|
|
|
|
// Module: shell2d()
|
|
// Usage:
|
|
// shell2d(thickness, [or], [ir], [fill], [round])
|
|
// Description:
|
|
// Creates a hollow shell from 2D children, with optional rounding.
|
|
// Arguments:
|
|
// thickness = Thickness of the shell. Positive to expand outward, negative to shrink inward, or a two-element list to do both.
|
|
// or = Radius to round corners on the outside of the shell. If given a list of 2 radii, [CONVEX,CONCAVE], specifies the radii for convex and concave corners separately. Default: 0 (no outside rounding)
|
|
// ir = Radius to round corners on the inside of the shell. If given a list of 2 radii, [CONVEX,CONCAVE], specifies the radii for convex and concave corners separately. Default: 0 (no inside rounding)
|
|
// Examples(2D):
|
|
// shell2d(10) {square([40,100], center=true); square([100,40], center=true);}
|
|
// shell2d(-10) {square([40,100], center=true); square([100,40], center=true);}
|
|
// shell2d([-10,10]) {square([40,100], center=true); square([100,40], center=true);}
|
|
// shell2d(10,or=10) {square([40,100], center=true); square([100,40], center=true);}
|
|
// shell2d(10,ir=10) {square([40,100], center=true); square([100,40], center=true);}
|
|
// shell2d(10,or=[10,0]) {square([40,100], center=true); square([100,40], center=true);}
|
|
// shell2d(10,or=[0,10]) {square([40,100], center=true); square([100,40], center=true);}
|
|
// shell2d(10,ir=[10,0]) {square([40,100], center=true); square([100,40], center=true);}
|
|
// shell2d(10,ir=[0,10]) {square([40,100], center=true); square([100,40], center=true);}
|
|
// shell2d(8,or=[16,8],ir=[16,8]) {square([40,100], center=true); square([100,40], center=true);}
|
|
module shell2d(thickness, or=0, ir=0)
|
|
{
|
|
thickness = is_num(thickness)? (
|
|
thickness<0? [thickness,0] : [0,thickness]
|
|
) : (thickness[0]>thickness[1])? (
|
|
[thickness[1],thickness[0]]
|
|
) : thickness;
|
|
orad = is_finite(or)? [or,or] : or;
|
|
irad = is_finite(ir)? [ir,ir] : ir;
|
|
difference() {
|
|
round2d(or=orad[0],ir=orad[1])
|
|
offset(delta=thickness[1])
|
|
children();
|
|
round2d(or=irad[1],ir=irad[0])
|
|
offset(delta=thickness[0])
|
|
children();
|
|
}
|
|
}
|
|
|
|
|
|
// vim: expandtab tabstop=4 shiftwidth=4 softtabstop=4 nowrap
|