Cosmetics

common.scad

@@ -205,7 +205,8 @@ function is_func(x) = version_num()>20210000 && is_function(x);
 // Description:
 //   Tests whether input is a list of entries which all have the same list structure
 //   and are filled with finite numerical data.  You can optionally specify a required 
-//   list structure with the pattern argument.  It returns `true` for the empty list.
+//   list structure with the pattern argument.  
+//   It returns `true` for the empty list regardless the value of the `pattern`.
 // Arguments:
 //   list = list to check
 //   pattern = optional pattern required to match
@@ -293,7 +294,7 @@ function default(v,dflt=undef) = is_undef(v)? dflt : v;
 //   v = The list whose items are being checked.
 //   recursive = If true, sublists are checked recursively for defined values.  The first sublist that has a defined item is returned.
 // Examples:
-//   val = first_defined([undef,7,undef,true]);  // Returns: 1
+//   val = first_defined([undef,7,undef,true]);  // Returns: 7
 function first_defined(v,recursive=false,_i=0) =
     _i<len(v) && (
         is_undef(v[_i]) || (
@@ -605,15 +606,15 @@ function segs(r) =
 
 
 // Module: no_children()
-// Topics: Error Checking
 // Usage:
 //   no_children($children);
+// Topics: Error Checking
+// See Also: no_function(), no_module()
 // Description:
 //   Assert that the calling module does not support children.  Prints an error message to this effect and fails if children are present,
 //   as indicated by its argument.
 // Arguments:
 //   $children = number of children the module has.  
-// See Also: no_function(), no_module()
 // Example:
 //   module foo() {
 //       no_children($children);
@@ -676,7 +677,7 @@ function _valstr(x) =
 //   expected = The value that was expected.
 //   info = Extra info to print out to make the error clearer.
 // Example:
-//   assert_approx(1/3, 0.333333333333333, str("numer=",1,", demon=",3));
+//   assert_approx(1/3, 0.333333333333333, str("number=",1,", demon=",3));
 module assert_approx(got, expected, info) {
     no_children($children);
     if (!approx(got, expected)) {

paths.scad

@@ -454,120 +454,120 @@ function path_torsion(path, closed=false) =
 //   path2 = path_chamfer_and_rounding(path, closed=true, chamfer=chamfs, rounding=rs);
 //   stroke(path2, closed=true);
 function path_chamfer_and_rounding(path, closed, chamfer, rounding) =
-	let (
-		path = deduplicate(path,closed=true),
-		lp = len(path),
-		chamfer = is_undef(chamfer)? repeat(0,lp) :
-			is_vector(chamfer)? list_pad(chamfer,lp,0) :
-			is_num(chamfer)? repeat(chamfer,lp) :
-			assert(false, "Bad chamfer value."),
-		rounding = is_undef(rounding)? repeat(0,lp) :
-			is_vector(rounding)? list_pad(rounding,lp,0) :
-			is_num(rounding)? repeat(rounding,lp) :
-			assert(false, "Bad rounding value."),
-		corner_paths = [
-			for (i=(closed? [0:1:lp-1] : [1:1:lp-2])) let(
-				p1 = select(path,i-1),
-				p2 = select(path,i),
-				p3 = select(path,i+1)
-			)
-			chamfer[i]  > 0? _corner_chamfer_path(p1, p2, p3, side=chamfer[i]) :
-			rounding[i] > 0? _corner_roundover_path(p1, p2, p3, r=rounding[i]) :
-			[p2]
-		],
-		out = [
-			if (!closed) path[0],
-			for (i=(closed? [0:1:lp-1] : [1:1:lp-2])) let(
-				p1 = select(path,i-1),
-				p2 = select(path,i),
-				crn1 = select(corner_paths,i-1),
-				crn2 = corner_paths[i],
-				l1 = norm(last(crn1)-p1),
-				l2 = norm(crn2[0]-p2),
-				needed = l1 + l2,
-				seglen = norm(p2-p1),
-				check = assert(seglen >= needed, str("Path segment ",i," is too short to fulfill rounding/chamfering for the adjacent corners."))
-			) each crn2,
-			if (!closed) last(path)
-		]
-	) deduplicate(out);
+  let (
+    path = deduplicate(path,closed=true),
+    lp = len(path),
+    chamfer = is_undef(chamfer)? repeat(0,lp) :
+      is_vector(chamfer)? list_pad(chamfer,lp,0) :
+      is_num(chamfer)? repeat(chamfer,lp) :
+      assert(false, "Bad chamfer value."),
+    rounding = is_undef(rounding)? repeat(0,lp) :
+      is_vector(rounding)? list_pad(rounding,lp,0) :
+      is_num(rounding)? repeat(rounding,lp) :
+      assert(false, "Bad rounding value."),
+    corner_paths = [
+      for (i=(closed? [0:1:lp-1] : [1:1:lp-2])) let(
+        p1 = select(path,i-1),
+        p2 = select(path,i),
+        p3 = select(path,i+1)
+      )
+      chamfer[i]  > 0? _corner_chamfer_path(p1, p2, p3, side=chamfer[i]) :
+      rounding[i] > 0? _corner_roundover_path(p1, p2, p3, r=rounding[i]) :
+      [p2]
+    ],
+    out = [
+      if (!closed) path[0],
+      for (i=(closed? [0:1:lp-1] : [1:1:lp-2])) let(
+        p1 = select(path,i-1),
+        p2 = select(path,i),
+        crn1 = select(corner_paths,i-1),
+        crn2 = corner_paths[i],
+        l1 = norm(last(crn1)-p1),
+        l2 = norm(crn2[0]-p2),
+        needed = l1 + l2,
+        seglen = norm(p2-p1),
+        check = assert(seglen >= needed, str("Path segment ",i," is too short to fulfill rounding/chamfering for the adjacent corners."))
+      ) each crn2,
+      if (!closed) last(path)
+    ]
+  ) deduplicate(out);
 
 
 function _corner_chamfer_path(p1, p2, p3, dist1, dist2, side, angle) = 
-	let(
-		v1 = unit(p1 - p2),
-		v2 = unit(p3 - p2),
-		n = vector_axis(v1,v2),
-		ang = vector_angle(v1,v2),
-		path = (is_num(dist1) && is_undef(dist2) && is_undef(side))? (
-			// dist1 & optional angle
-			assert(dist1 > 0)
-			let(angle = default(angle,(180-ang)/2))
-			assert(is_num(angle))
-			assert(angle > 0 && angle < 180)
-			let(
-				pta = p2 + dist1*v1,
-				a3 = 180 - angle - ang
-			) assert(a3>0, "Angle too extreme.")
-			let(
-				side = sin(angle) * dist1/sin(a3),
-				ptb = p2 + side*v2
-			) [pta, ptb]
-		) : (is_undef(dist1) && is_num(dist2) && is_undef(side))? (
-			// dist2 & optional angle
-			assert(dist2 > 0)
-			let(angle = default(angle,(180-ang)/2))
-			assert(is_num(angle))
-			assert(angle > 0 && angle < 180)
-			let(
-				ptb = p2 + dist2*v2,
-				a3 = 180 - angle - ang
-			) assert(a3>0, "Angle too extreme.")
-			let(
-				side = sin(angle) * dist2/sin(a3),
-				pta = p2 + side*v1
-			) [pta, ptb]
-		) : (is_undef(dist1) && is_undef(dist2) && is_num(side))? (
-			// side & optional angle
-			assert(side > 0)
-			let(angle = default(angle,(180-ang)/2))
-			assert(is_num(angle))
-			assert(angle > 0 && angle < 180)
-			let(
-				a3 = 180 - angle - ang
-			) assert(a3>0, "Angle too extreme.")
-			let(
-				dist1 = sin(a3) * side/sin(ang),
-				dist2 = sin(angle) * side/sin(ang),
-				pta = p2 + dist1*v1,
-				ptb = p2 + dist2*v2
-			) [pta, ptb]
-		) : (is_num(dist1) && is_num(dist2) && is_undef(side) && is_undef(side))? (
-			// dist1 & dist2
-			assert(dist1 > 0)
-			assert(dist2 > 0)
-			let(
-				pta = p2 + dist1*v1,
-				ptb = p2 + dist2*v2
-			) [pta, ptb]
-		) : (
-			assert(false,"Bad arguments.")
-		)
-	) path;
+  let(
+    v1 = unit(p1 - p2),
+    v2 = unit(p3 - p2),
+    n = vector_axis(v1,v2),
+    ang = vector_angle(v1,v2),
+    path = (is_num(dist1) && is_undef(dist2) && is_undef(side))? (
+      // dist1 & optional angle
+      assert(dist1 > 0)
+      let(angle = default(angle,(180-ang)/2))
+      assert(is_num(angle))
+      assert(angle > 0 && angle < 180)
+      let(
+        pta = p2 + dist1*v1,
+        a3 = 180 - angle - ang
+      ) assert(a3>0, "Angle too extreme.")
+      let(
+        side = sin(angle) * dist1/sin(a3),
+        ptb = p2 + side*v2
+      ) [pta, ptb]
+    ) : (is_undef(dist1) && is_num(dist2) && is_undef(side))? (
+      // dist2 & optional angle
+      assert(dist2 > 0)
+      let(angle = default(angle,(180-ang)/2))
+      assert(is_num(angle))
+      assert(angle > 0 && angle < 180)
+      let(
+        ptb = p2 + dist2*v2,
+        a3 = 180 - angle - ang
+      ) assert(a3>0, "Angle too extreme.")
+      let(
+        side = sin(angle) * dist2/sin(a3),
+        pta = p2 + side*v1
+      ) [pta, ptb]
+    ) : (is_undef(dist1) && is_undef(dist2) && is_num(side))? (
+      // side & optional angle
+      assert(side > 0)
+      let(angle = default(angle,(180-ang)/2))
+      assert(is_num(angle))
+      assert(angle > 0 && angle < 180)
+      let(
+        a3 = 180 - angle - ang
+      ) assert(a3>0, "Angle too extreme.")
+      let(
+        dist1 = sin(a3) * side/sin(ang),
+        dist2 = sin(angle) * side/sin(ang),
+        pta = p2 + dist1*v1,
+        ptb = p2 + dist2*v2
+      ) [pta, ptb]
+    ) : (is_num(dist1) && is_num(dist2) && is_undef(side) && is_undef(side))? (
+      // dist1 & dist2
+      assert(dist1 > 0)
+      assert(dist2 > 0)
+      let(
+        pta = p2 + dist1*v1,
+        ptb = p2 + dist2*v2
+      ) [pta, ptb]
+    ) : (
+      assert(false,"Bad arguments.")
+    )
+  ) path;
 
 
 function _corner_roundover_path(p1, p2, p3, r, d) = 
-	let(
-		r = get_radius(r=r,d=d,dflt=undef),
-		res = circle_2tangents(p1, p2, p3, r=r, tangents=true),
-		cp = res[0],
-		n = res[1],
-		tp1 = res[2],
-		ang = res[4]+res[5],
-		steps = floor(segs(r)*ang/360+0.5),
-		step = ang / steps,
-		path = [for (i=[0:1:steps]) move(cp, p=rot(a=-i*step, v=n, p=tp1-cp))]
-	) path;
+  let(
+    r = get_radius(r=r,d=d,dflt=undef),
+    res = circle_2tangents(p1, p2, p3, r=r, tangents=true),
+    cp = res[0],
+    n = res[1],
+    tp1 = res[2],
+    ang = res[4]+res[5],
+    steps = floor(segs(r)*ang/360+0.5),
+    step = ang / steps,
+    path = [for (i=[0:1:steps]) move(cp, p=rot(a=-i*step, v=n, p=tp1-cp))]
+  ) path;