2025-01-15 08:59:40 +00:00
3 changed files with 67 additions and 76 deletions
--- a/beziers.scad
+++ b/beziers.scad
@ -689,8 +689,7 @@ function path_to_bezcornerpath(path, closed, size, relsize) =
            sizevect[i], relative),
        [path[pathlen-1]]
    ]
-    )
-    flatten(roundpath);
+) flatten(roundpath);


 /// Internal function: _bez_path_corner()
@ -744,7 +743,9 @@ let(
    // bz6 is p3
    bz3 = p2 + middir * bzdist, // center control point
    bz2 = bz3 + midto12unit*(d1<d3 ? cornerlegmin : cornerlegmax),
-    bz1 = p1 - (d1<=d3 ? leglenmin : leglenmax)*p21unit,
+    bz1 = p1 - (d1<=d3 ? leglenmin :
+        leglenmax)*p21unit,
+        //norm(0.333*(bz2-p1)))*p21unit,
    bz4 = bz3 - midto12unit*(d3<d1 ? cornerlegmin : cornerlegmax),
    bz5 = p3 - (d3<=d1 ? leglenmin : leglenmax)*p23unit
 ) [p1, bz1, bz2, bz3, bz4, bz5]; // do not include last control point
--- a/rounding.scad
+++ b/rounding.scad
@ -735,16 +735,14 @@ function _rounding_offsets(edgespec,z_dir=1) =
 //   pts = [[-3.3, 1.7], [-3.7, -2.2], [3.8, -4.8], [-0.9, -2.4]];
 //   stroke(smooth_path(pts, uniform=false, relsize=0.1),width=.1);
 //   color("red")move_copies(pts)circle(r=.15,$fn=12);
-module smooth_path(path, tangents, size, relsize, method="edges", splinesteps=10, uniform, closed=false) {no_module();}
-function smooth_path(path, tangents, size, relsize, method="edges", splinesteps=10, uniform, closed) =
-is_1region(path)
-    ? smooth_path(path[0], tangents, size, relsize, method, splinesteps, uniform, default(closed,true))
-    : assert(method=="edges" || method=="corners", "method must be \"edges\" or \"corners\".")
-assert(method=="edges" || (is_undef(tangents) && is_undef(uniform)), "The tangents and uniform parameters are incompatible with method=\"corners\".")
+module smooth_path(path, tangents, size, relsize, method="edges", splinesteps=10, uniform=false, closed=false) {no_module();}
+function smooth_path(path, tangents, size, relsize, method="edges", splinesteps=10, uniform=false, closed) =
+  is_1region(path) ? smooth_path(path[0], tangents, size, relsize, method, splinesteps, uniform, default(closed,true)) :
+  assert(method=="edges" || method=="corners", "method must be \"edges\" or \"corners\".")
+  assert(method=="edges" || is_undef(tangent), "The tangents parameter is incompatible with method=\"corners\".")
  let (
-    uniform = default(uniform,false),
-    bez = method=="edges"
-        ? path_to_bezpath(path, tangents=tangents, size=size, relsize=relsize, uniform=uniform, closed=default(closed,false))
+     bez = method=="edges" ?
+        path_to_bezpath(path, tangents=tangents, size=size, relsize=relsize, uniform=uniform, closed=default(closed,false))
        : path_to_bezcornerpath(path, size=size, relsize=relsize, closed=default(closed,false)),
     smoothed = bezpath_curve(bez,splinesteps=splinesteps)
  )
--- a/shapes2d.scad
+++ b/shapes2d.scad
@ -1793,7 +1793,7 @@ module glued_circles(r, spread=10, tangent=30, d, anchor=CENTER, spin=0) {
 // Examples(2D):
 //   squircle(size=50, squareness=0.4);
 //   squircle([80,60], 0.7, $fn=64);
-// Example(3D,VPD=48,VPR=[40,0,40],NoAxes): Corner differences between the three squircle styles for squareness=0.5. Style "superellipse" is pink, "fg" is gold, "bezier" is blue.
+// Example(2D,VPD=48,VPR=[40,0,40],NoAxes): Corner differences between the three squircle styles for squareness=0.5. Style "superellipse" is pink, "fg" is gold, "bezier" is blue.
 //   color("pink") squircle(size=50, style="superellipse", squareness=0.5, $fn=256);
 //   color("yellow") up(1) squircle(size=50, style="fg", squareness=0.5, $fn=256);
 //   color("lightblue") up(2) squircle(size=50, style="bezier", squareness=0.5, $fn=256);
@ -1854,11 +1854,9 @@ function _squircle_fg(size, squareness) = [
    ) p*[cos(theta), aspect*sin(theta)]
 ];

-function squircle_radius_fg(squareness, r, angle) =
-    let(
+function squircle_radius_fg(squareness, r, angle) = let(
    s2a = abs(squareness*sin(2*angle))
-    )
-    s2a>0 ? r*sqrt(2)/s2a * sqrt(1 - sqrt(1 - s2a*s2a)) : r;
+    ) s2a>0 ? r*sqrt(2)/s2a * sqrt(1 - sqrt(1 - s2a*s2a)) : r;

 function _linearize_squareness(s) =
    // from Chamberlain Fong (2016). "Squircular Calculations". arXiv.
@ -1886,33 +1884,27 @@ function _squircle_se(size, squareness) = [
    ) [ra*x, rb*y] / r
 ];

-function squircle_radius_se(n, r, angle) =
-    let(
+function squircle_radius_se(n, r, angle) = let(
    x = cos(angle),
    y = sin(angle)
-    )
-    (abs(x)^n + abs(y)^n)^(1/n) / r;
+) (abs(x)^n + abs(y)^n)^(1/n) / r;

-function _squircle_se_exponent(squareness) =
-    let(
+function _squircle_se_exponent(squareness) = let(
    // limit squareness; error if >0.99889, limit is smaller for r>1
    s=min(0.998,squareness),
    rho = 1 + s*(sqrt(2)-1),
    x = rho / sqrt(2)
-    )
-    log(0.5) / log(x);
+) log(0.5) / log(x);


 /* Bezier squircle function */

-function _squircle_bz(size, squareness) =
-    let(
+function _squircle_bz(size, squareness) = let(
    splinesteps = $fn>=12 ? round($fn/4) : 10,
    size = is_num(size) ? [size,size] : point2d(size),
    sq = square(size, center=true),
    bez = path_to_bezcornerpath(sq, relsize=1-squareness, closed=true)
-    )
-    bezpath_curve(bez, splinesteps=splinesteps);
+) bezpath_curve(bez, splinesteps=splinesteps);