Move helper functions / modules to their own file

These are not explicitly tied to Gridfinity.

generic-helpers.scad

@@ -0,0 +1,170 @@
+/**
+ * @file generic-helpers.scad
+ * @brief Generic Helper Functions. Not gridfinity specific.
+ */
+
+function clp(x,a,b) = min(max(x,a),b);
+
+module rounded_rectangle(length, width, height, rad) {
+    linear_extrude(height)
+    offset(rad)
+    offset(-rad)
+    square([length,width], center = true);
+}
+
+module rounded_square(length, height, rad) {
+    rounded_rectangle(length, length, height, rad);
+}
+
+module copy_mirror(vec=[0,1,0]) {
+    children();
+    if (vec != [0,0,0])
+    mirror(vec)
+    children();
+}
+
+module pattern_linear(x = 1, y = 1, sx = 0, sy = 0) {
+    yy = sy <= 0 ? sx : sy;
+    translate([-(x-1)*sx/2,-(y-1)*yy/2,0])
+    for (i = [1:ceil(x)])
+    for (j = [1:ceil(y)])
+    translate([(i-1)*sx,(j-1)*yy,0])
+    children();
+}
+
+module pattern_circular(n=2) {
+    for (i = [1:n])
+    rotate(i*360/n)
+    children();
+}
+
+/**
+ * @brief Unity (no change) affine transformation matrix.
+ * @details For use with multmatrix transforms.
+ */
+unity_matrix = [
+    [1, 0, 0, 0],
+    [0, 1, 0, 0],
+    [0, 0, 1, 0],
+    [0, 0, 0, 1]
+];
+
+/**
+ * @brief Get the magnitude of a 2d or 3d vector
+ * @param vector A 2d or 3d vectorm
+ * @returns Magnitude of the vector.
+ */
+ function vector_magnitude(vector) =
+    sqrt(vector.x^2 + vector.y^2 + (len(vector) == 3 ? vector.z^2 : 0));
+
+/**
+ * @brief Convert a 2d or 3d vector into a unit vector
+ * @returns The unit vector.  Where total magnitude is 1.
+ */
+function vector_as_unit(vector) = vector / vector_magnitude(vector);
+
+/**
+ * @brief Convert a 2d vector into an angle.
+ * @details Just a wrapper around atan2.
+ * @param A 2d vectorm
+ * @returns Angle of the vector.
+ */
+function atanv(vector) = atan2(vector.y, vector.x);
+
+/**
+ * @brief Affine transformation matrix for 2d rotation on the X,Y plane.
+ * @param angle The angle to rotate things by
+ * @returns an Affine transformation matrix for use with `multmatrix()`
+ */
+function affine_rotation(angle) = [
+    [cos(angle), 0, sin(angle), 0],
+    [0, 1, 0, 0],
+    [-sin(angle), 0, cos(angle), 0],
+    [0, 0, 0, 1]
+];
+
+
+/**
+ * @brief Affine transformation matrix for 2d translation on the X,Y plane.
+ * @param vector 2d Vector to translate by.
+ * @returns an Affine transformation matrix for use with `multmatrix()`
+ */
+function affine_translation(vector) = [
+    [1, 0, 0, vector.y],
+    [0, 1, 0, 0],
+    [0, 0, 1, vector.x],
+    [0, 0, 0, 1]
+];
+
+/**
+ * @brief Create a rectangle with rounded corners by sweeping a 2d object along a path.
+ *        Centered on origin.
+ */
+module sweep_rounded(width=10, length=10) {
+    half_width = width/2;
+    half_length = length/2;
+    path_points = [
+        [-half_width, half_length],  //Start
+        [half_width, half_length], // Over
+        [half_width, -half_length], //Down
+        [-half_width, -half_length], // Back over
+        [-half_width, half_length]  // Up to start
+    ];
+    path_vectors = [
+        path_points[1] - path_points[0],
+        path_points[2] - path_points[1],
+        path_points[3] - path_points[2],
+        path_points[4] - path_points[3],
+    ];
+    // These contain the translations, but not the rotations
+    // OpenSCAD requires this hacky for loop to get accumulate to work!
+    first_translation = affine_translation(path_points[0]);
+    affine_translations = concat([first_translation], [
+        for (i = 0, a = first_translation;
+            i < len(path_vectors);
+            a=a * affine_translation(path_vectors[i]), i=i+1)
+        a * affine_translation(path_vectors[i])
+    ]);
+
+    // Affine matrix to rotate around X axis
+    rot_x = 90;
+    x_matrix = [
+        [1, 0, 0, 0],
+        [0, cos(rot_x), -sin(rot_x), 0],
+        [0, sin(rot_x), cos(rot_x), 0],
+        [0, 0, 0, 1]
+    ];
+
+    // Affine matrix to rotate around Z axis
+    z_rot = 90;
+    z_matrix = [
+        [cos(z_rot), -sin(z_rot), 0, 0],
+        [sin(z_rot), cos(z_rot), 0, 0],
+        [0, 0, 1, 0],
+        [0, 0, 0, 1]
+    ];
+
+    // Bring extrusion to the xy plane
+    affine_matrix = z_matrix * x_matrix;
+
+    walls = [
+        for (i = [0 : len(path_vectors) - 1])
+        affine_matrix * affine_translations[i]
+        * affine_rotation(atanv(path_vectors[i]))
+    ];
+
+    union()
+    {
+        for (i = [0 : len(walls) - 1]){
+            multmatrix(walls[i])
+            linear_extrude(vector_magnitude(path_vectors[i]))
+            children();
+
+            // Rounded Corners
+            multmatrix(walls[i]
+                *x_matrix*x_matrix*x_matrix *z_matrix*z_matrix*z_matrix*z_matrix)
+            rotate_extrude(angle = 90, convexity = 4)
+            children();
+        }
+    }
+}

gridfinity-rebuilt-utility.scad

@@ -5,6 +5,7 @@
  */
 
 include <standard.scad>
+use <generic-helpers.scad>
 
 // ===== User Modules ===== //
 
@@ -621,171 +622,3 @@ module profile_cutter_tab(h, tab, ang) {
         polygon([[0,h],[tab,h],[0,h-tab*tan(ang)]]);
 
 }
-
-// ==== Utilities =====
-
-function clp(x,a,b) = min(max(x,a),b);
-
-module rounded_rectangle(length, width, height, rad) {
-    linear_extrude(height)
-    offset(rad)
-    offset(-rad)
-    square([length,width], center = true);
-}
-
-module rounded_square(length, height, rad) {
-    rounded_rectangle(length, length, height, rad);
-}
-
-module copy_mirror(vec=[0,1,0]) {
-    children();
-    if (vec != [0,0,0])
-    mirror(vec)
-    children();
-}
-
-module pattern_linear(x = 1, y = 1, sx = 0, sy = 0) {
-    yy = sy <= 0 ? sx : sy;
-    translate([-(x-1)*sx/2,-(y-1)*yy/2,0])
-    for (i = [1:ceil(x)])
-    for (j = [1:ceil(y)])
-    translate([(i-1)*sx,(j-1)*yy,0])
-    children();
-}
-
-module pattern_circular(n=2) {
-    for (i = [1:n])
-    rotate(i*360/n)
-    children();
-}
-
-/**
- * @brief Unity (no change) affine transformation matrix.
- * @details For use with multmatrix transforms.
- */
-unity_matrix = [
-    [1, 0, 0, 0],
-    [0, 1, 0, 0],
-    [0, 0, 1, 0],
-    [0, 0, 0, 1]
-];
-
-/**
- * @brief Get the magnitude of a 2d or 3d vector
- * @param vector A 2d or 3d vectorm
- * @returns Magnitude of the vector.
- */
- function vector_magnitude(vector) =
-    sqrt(vector.x^2 + vector.y^2 + (len(vector) == 3 ? vector.z^2 : 0));
-
-/**
- * @brief Convert a 2d or 3d vector into a unit vector
- * @returns The unit vector.  Where total magnitude is 1.
- */
-function vector_as_unit(vector) = vector / vector_magnitude(vector);
-
-/**
- * @brief Convert a 2d vector into an angle.
- * @details Just a wrapper around atan2.
- * @param A 2d vectorm
- * @returns Angle of the vector.
- */
-function atanv(vector) = atan2(vector.y, vector.x);
-
-/**
- * @brief Affine transformation matrix for 2d rotation on the X,Y plane.
- * @param angle The angle to rotate things by
- * @returns an Affine transformation matrix for use with `multmatrix()`
- */
-function affine_rotation(angle) = [
-    [cos(angle), 0, sin(angle), 0],
-    [0, 1, 0, 0],
-    [-sin(angle), 0, cos(angle), 0],
-    [0, 0, 0, 1]
-];
-
-
-/**
- * @brief Affine transformation matrix for 2d translation on the X,Y plane.
- * @param vector 2d Vector to translate by.
- * @returns an Affine transformation matrix for use with `multmatrix()`
- */
-function affine_translation(vector) = [
-    [1, 0, 0, vector.y],
-    [0, 1, 0, 0],
-    [0, 0, 1, vector.x],
-    [0, 0, 0, 1]
-];
-
-/**
- * @brief Create a rectangle with rounded corners by sweeping a 2d object along a path.
- *        Centered on origin.
- */
-module sweep_rounded(width=10, length=10) {
-    half_width = width/2;
-    half_length = length/2;
-    path_points = [
-        [-half_width, half_length],  //Start
-        [half_width, half_length], // Over
-        [half_width, -half_length], //Down
-        [-half_width, -half_length], // Back over
-        [-half_width, half_length]  // Up to start
-    ];
-    path_vectors = [
-        path_points[1] - path_points[0],
-        path_points[2] - path_points[1],
-        path_points[3] - path_points[2],
-        path_points[4] - path_points[3],
-    ];
-    // These contain the translations, but not the rotations
-    // OpenSCAD requires this hacky for loop to get accumulate to work!
-    first_translation = affine_translation(path_points[0]);
-    affine_translations = concat([first_translation], [
-        for (i = 0, a = first_translation;
-            i < len(path_vectors);
-            a=a * affine_translation(path_vectors[i]), i=i+1)
-        a * affine_translation(path_vectors[i])
-    ]);
-    
-    // Affine matrix to rotate around X axis
-    rot_x = 90;
-    x_matrix = [
-        [1, 0, 0, 0],
-        [0, cos(rot_x), -sin(rot_x), 0],
-        [0, sin(rot_x), cos(rot_x), 0],
-        [0, 0, 0, 1]
-    ];
-    
-    // Affine matrix to rotate around Z axis
-    z_rot = 90;
-    z_matrix = [
-        [cos(z_rot), -sin(z_rot), 0, 0],
-        [sin(z_rot), cos(z_rot), 0, 0],
-        [0, 0, 1, 0],
-        [0, 0, 0, 1]
-    ];
-
-    // Bring extrusion to the xy plane
-    affine_matrix = z_matrix * x_matrix;
-    
-    walls = [
-        for (i = [0 : len(path_vectors) - 1])
-        affine_matrix * affine_translations[i]
-        * affine_rotation(atanv(path_vectors[i]))
-    ];
-    
-    union()
-    {
-        for (i = [0 : len(walls) - 1]){
-            multmatrix(walls[i])
-            linear_extrude(vector_magnitude(path_vectors[i]))
-            children();
-            
-            // Rounded Corners
-            multmatrix(walls[i]
-                *x_matrix*x_matrix*x_matrix *z_matrix*z_matrix*z_matrix*z_matrix)
-            rotate_extrude(angle = 90, convexity = 4)
-            children();
-        }
-    }
-}