mirror of
https://github.com/BelfrySCAD/BOSL2.git
synced 2024-12-29 16:29:40 +00:00
Removed range(), rangex(). Added count().
This commit is contained in:
parent
a4c099e670
commit
8bd3ef8a74
13 changed files with 75 additions and 170 deletions
92
arrays.scad
92
arrays.scad
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@ -209,7 +209,7 @@ function list_tail(list, from=1) =
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// If given a string, explodes it into a list of single letters.
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// Arguments:
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// l = The value to expand.
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// See Also: scalar_vec3(), force_list(), range(), rangex()
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// See Also: scalar_vec3(), force_list(), rangex()
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// Example:
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// l1 = list([3:2:9]); // Returns: [3,5,7,9]
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// l2 = list([3,4,5]); // Returns: [3,4,5]
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@ -396,7 +396,7 @@ function list_decreasing(list) =
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// Usage:
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// list = repeat(val, n);
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// Topics: List Handling
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// See Also: range(), rangex()
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// See Also: count(), lerpn()
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// Description:
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// Generates a list or array of `n` copies of the given value `val`.
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// If the count `n` is given as a list of counts, then this creates a
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@ -416,88 +416,20 @@ function repeat(val, n, i=0) =
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[for (j=[1:1:n[i]]) repeat(val, n, i+1)];
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// Function: range()
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// Function: count()
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// Usage:
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// list = range(n, <s=>, <e=>);
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// list = range(n, <s=>, <step=>);
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// list = range(e=, <step=>);
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// list = range(s=, e=, <step=>);
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// Topics: List Handling
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// list = count(n,<s>,<step>);
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// Description:
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// Returns a list, counting up from starting value `s`, by `step` increments,
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// until either `n` values are in the list, or it reaches the end value `e`.
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// If both `n` and `e` are given, returns `n` values evenly spread from `s`
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// to `e`, and `step` is ignored.
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// Creates a list of `n` numbers, starting at `s`, incrementing by `step` each time.
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// Arguments:
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// n = Desired number of values in returned list, if given.
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// ---
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// s = Starting value. Default: 0
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// e = Ending value to stop at, if given.
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// step = Amount to increment each value. Default: 1
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// See Also: repeat(), rangex()
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// n = The length of the list of numbers to create.
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// s = The starting value of the list of numbers.
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// step = The amount to increment successive numbers in the list.
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// Example:
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// a = range(4); // Returns [0,1,2,3]
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// b = range(n=4, step=2); // Returns [0,2,4,6]
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// c = range(n=4, s=3, step=3); // Returns [3,6,9,12]
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// d = range(n=5, s=0, e=10); // Returns [0, 2.5, 5, 7.5, 10]
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// e = range(e=3); // Returns [0,1,2,3]
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// f = range(e=7, step=2); // Returns [0,2,4,6]
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// g = range(s=3, e=5); // Returns [3,4,5]
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// h = range(s=3, e=8, step=2); // Returns [3,5,7]
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// i = range(s=4, e=8.3, step=2); // Returns [4,6,8]
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function range(n, s=0, e, step) =
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assert( is_undef(n) || is_finite(n), "Parameter `n` must be a number.")
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assert( is_undef(n) || is_undef(e) || is_undef(step), "At most 2 of n, e, and step can be given.")
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let( step = (n!=undef && e!=undef)? (e-s)/(n-1) : default(step,1) )
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is_undef(e)
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? assert( is_consistent([s, step]), "Incompatible data.")
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[for (i=[0:1:n-1]) s+step*i]
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: assert( is_vector([s,step,e]), "Start `s`, step `step` and end `e` must be numbers.")
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[for (v=[s:step:e]) v] ;
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// Function: rangex()
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// Usage:
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// list = rangex(n, <s=>, <e=>);
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// list = rangex(n, <s=>, <step=>);
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// list = rangex(e=, <step=>);
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// list = rangex(s=, e=, <step=>);
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// Topics: List Handling
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// Description:
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// Returns a list, counting up from starting value `s`, by `step` increments, until
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// either `n` values are in the list, or it reaches the value just before the end value `e`.
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// If both `n` and `e` are given, returns `n` values evenly spread from `s` to the value
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// just before `e`, and `step` is ignored.
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// Arguments:
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// n = Desired number of values in returned list, if given.
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// ---
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// s = Starting value. Default: 0
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// e = Ending value to stop at, if given.
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// step = Amount to increment each value. Default: 1
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// See Also: repeat(), range()
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// Example:
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// a = rangex(4); // Returns [0,1,2,3]
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// b = rangex(5,e=1); // Returns [0, 0.2, 0.4, 0.6, 0.8]
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// c = rangex(n=4, step=2); // Returns [0,2,4,6]
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// d = rangex(n=4, step=0.25); // Returns [0, 0.25, 0.5, 0.75]
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// e = rangex(n=4, s=3, step=3); // Returns [3,6,9,12]
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// f = rangex(n=5, s=0, e=10); // Returns [0, 2, 4, 6, 8]
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// g = rangex(e=3); // Returns [0,1,2]
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// h = rangex(e=7, step=2); // Returns [0,2,4,6]
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// i = rangex(s=3, e=5); // Returns [3,4]
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// j = rangex(s=3, e=8, step=2); // Returns [3,5,7]
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// k = rangex(s=2, e=8, step=2); // Returns [2,4,6]
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// l = rangex(s=2, e=8.1, step=2); // Returns [2,4,6,8]
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function rangex(n, s=0, e, step) =
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assert( is_undef(n) || is_finite(n), "Parameter `n` must be a number.")
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assert( is_undef(n) || is_undef(e) || is_undef(step), "At most 2 of n, e, and step can be given.")
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let( step = (n!=undef && e!=undef)? (e-s)/n : default(step,1) )
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is_undef(e)
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? assert( is_consistent([s, step]), "Incompatible data.")
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[for (i=[0:1:n-1]) s+step*i]
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: assert( is_vector([s,step,e]), "Start `s`, step `step` and end `e` must be numbers.")
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let(steps=floor((e-s)/step+0.5))
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[for (i=[0:1:steps-1]) s+step*i];
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// nl1 = count(5); // Returns: [0,1,2,3,4]
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// nl2 = count(5,3); // Returns: [3,4,5,6,7]
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// nl3 = count(4,3,2); // Returns: [3,5,7,9]
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function count(n,s=0,step=1) = [for (i=[0:1:n-1]) s+i*step];
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55
beziers.scad
55
beziers.scad
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@ -437,10 +437,8 @@ function bezier_curvature(curve, u) =
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// move_copies(bezier_curve(bez, 8)) sphere(r=1.5, $fn=12);
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// trace_bezier(bez, N=len(bez)-1);
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function bezier_curve(curve,n,endpoint=true) =
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[
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each bezier_points(curve, rangex(endpoint?n-1:n,0,1)),
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if (endpoint) last(curve)
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];
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bezier_points(curve, lerpn(0,1,n,endpoint));
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// Function: bezier_segment_closest_point()
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// Usage:
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@ -509,7 +507,7 @@ function bezier_segment_closest_point(curve, pt, max_err=0.01, u=0, end_u=1) =
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function bezier_segment_length(curve, start_u=0, end_u=1, max_deflect=0.01) =
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let(
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segs = len(curve) * 2,
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uvals = [for (i=[0:1:segs]) lerp(start_u, end_u, i/segs)],
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uvals = lerpn(start_u, end_u, segs),
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path = bezier_points(curve,uvals),
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defl = max([
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for (i=idx(path,e=-3)) let(
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@ -693,7 +691,7 @@ function bezier_path_length(path, N=3, max_deflect=0.001) =
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// Function: bezier_path()
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// Usage:
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// path = bezier_path(bezier, <splinesteps>, <N>)
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// path = bezier_path(bezier, <splinesteps>, <N>, <endpoint>)
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// Topics: Bezier Paths
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// See Also: bezier_points(), bezier_curve()
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// Description:
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@ -702,6 +700,7 @@ function bezier_path_length(path, N=3, max_deflect=0.001) =
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// bezier = A bezier path to approximate.
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// splinesteps = Number of straight lines to split each bezier segment into. default=16
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// N = The degree of the bezier curves. Cubic beziers have N=3. Default: 3
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// endpoint = If true, include the very last point of the bezier path. Default: true
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// Example(2D):
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// bez = [
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// [0,0], [-5,30],
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@ -711,18 +710,19 @@ function bezier_path_length(path, N=3, max_deflect=0.001) =
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// ];
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// trace_path(bez, size=1, N=3, showpts=true);
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// trace_path(bezier_path(bez, N=3), size=3);
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function bezier_path(bezier, splinesteps=16, N=3) =
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function bezier_path(bezier, splinesteps=16, N=3, endpoint=true) =
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assert(is_path(bezier))
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assert(is_int(N))
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assert(is_int(splinesteps))
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assert(len(bezier)%N == 1, str("A degree ",N," bezier path shound have a multiple of ",N," points in it, plus 1."))
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assert(len(bezier)%N == 1, str("A degree ",N," bezier path should have a multiple of ",N," points in it, plus 1."))
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let(
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segs = (len(bezier)-1)/N
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) deduplicate([
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for (seg = [0:1:segs-1], i = [0:1:splinesteps-1])
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bezier_path_point(bezier, seg, i/splinesteps, N=N),
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bezier_path_point(bezier, segs-1, 1, N=N)
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]);
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segs = (len(bezier)-1) / N,
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step = 1 / splinesteps
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) [
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for (seg = [0:1:segs-1])
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each bezier_points(select(bezier, seg*N, (seg+1)*N), [0:step:1-step/2]),
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if (endpoint) bezier_path_point(bezier, segs-1, 1, N=N)
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];
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@ -861,19 +861,18 @@ function bezier_close_to_axis(bezier, axis="X", N=3) =
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assert(is_int(N))
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assert(len(bezier)%N == 1, str("A degree ",N," bezier path shound have a multiple of ",N," points in it, plus 1."))
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let(
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bezend = len(bezier)-1,
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sp = bezier[0],
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ep = bezier[bezend]
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ep = last(bezier)
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) (axis=="X")? concat(
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[for (i=[0:1:N-1]) lerp([sp.x,0], sp, i/N)],
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bezier,
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[for (i=[1:1:N]) lerp(ep, [ep.x,0], i/N)],
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[for (i=[1:1:N]) lerp([ep.x,0], [sp.x,0], i/N)]
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lerpn([sp.x,0], sp, N, false),
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list_head(bezier),
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lerpn(ep, [ep.x,0], N, false),
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lerpn([ep.x,0], [sp.x,0], N+1)
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) : (axis=="Y")? concat(
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[for (i=[0:1:N-1]) lerp([0,sp.y], sp, i/N)],
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bezier,
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[for (i=[1:1:N]) lerp(ep, [0,ep.y], i/N)],
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[for (i=[1:1:N]) lerp([0,ep.y], [0,sp.y], i/N)]
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lerpn([0,sp.y], sp, N, false),
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list_head(bezier),
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lerpn(ep, [0,ep.y], N, false),
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lerpn([0,ep.y], [0,sp.y], N+1)
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) : (
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assert(in_list(axis, ["X","Y"]))
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);
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@ -907,10 +906,10 @@ function bezier_offset(offset, bezier, N=3) =
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backbez = reverse([ for (pt = bezier) pt+offset ]),
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bezend = len(bezier)-1
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) concat(
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bezier,
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[for (i=[1:1:N-1]) lerp(bezier[bezend], backbez[0], i/N)],
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backbez,
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[for (i=[1:1:N]) lerp(backbez[bezend], bezier[0], i/N)]
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list_head(bezier),
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lerpn(bezier[bezend], backbez[0], N, false),
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list_head(backbez),
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lerpn(backbez[bezend], bezier[0], N+1)
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);
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@ -158,7 +158,7 @@ function _hull_collinear(points) =
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// %polyhedron(points=pts, faces=faces);
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function hull3d_faces(points) =
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assert(is_path(points,3),"Invalid input to hull3d_faces")
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len(points) < 3 ? range(len(points))
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len(points) < 3 ? count(len(points))
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: let ( // start with a single non-collinear triangle
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tri = noncollinear_triple(points, error=false)
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)
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@ -494,7 +494,7 @@ function rand_int(minval, maxval, N, seed=undef) =
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function gaussian_rands(mean, stddev, N=1, seed=undef) =
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assert( is_finite(mean+stddev+N) && (is_undef(seed) || is_finite(seed) ), "Input must be finite numbers.")
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let(nums = is_undef(seed)? rands(0,1,N*2) : rands(0,1,N*2,seed))
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[for (i = range(N)) mean + stddev*sqrt(-2*ln(nums[i*2]))*cos(360*nums[i*2+1])];
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[for (i = count(N)) mean + stddev*sqrt(-2*ln(nums[i*2]))*cos(360*nums[i*2+1])];
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// Function: log_rands()
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15
paths.scad
15
paths.scad
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@ -1240,18 +1240,15 @@ module path_spread(path, n, spacing, sp=undef, rotate_children=true, closed=fals
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length = path_length(path,closed);
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distances =
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is_def(sp)? ( // Start point given
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is_def(n) && is_def(spacing)? range(s=sp, step=spacing, n=n) :
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is_def(n)? range(s=sp, e=length, n=n) :
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range(s=sp, step=spacing, e=length)
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)
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: is_def(n) && is_undef(spacing)? ( // N alone given
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closed ? rangex(s=0, e=length, n=n)
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: range(s=0, e=length, n=n)
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is_def(n) && is_def(spacing)? count(n,sp,spacing) :
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is_def(n)? lerpn(sp, length, n) :
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list([sp:spacing:length])
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)
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: is_def(n) && is_undef(spacing)? lerpn(0,length,n,!closed) // N alone given
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: ( // No start point and spacing is given, N maybe given
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let(
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n = is_def(n)? n : floor(length/spacing)+(closed?0:1),
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ptlist = range(s=0,step=spacing,n=n),
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ptlist = count(n,0,spacing),
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listcenter = mean(ptlist)
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) closed?
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sort([for(entry=ptlist) posmod(entry-listcenter,length)]) :
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@ -1607,7 +1604,7 @@ function resample_path(path, N, spacing, closed=false) =
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// path_cut to return the endpoint (which might fail due to rounding)
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// Add last point later
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N = is_def(N) ? N-(closed?0:1) : round(length/spacing),
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distlist = rangex(N,e=length),
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distlist = lerpn(0,length,N,false),
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cuts = path_cut_points(path, distlist, closed=closed)
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)
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[ each subindex(cuts,0),
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@ -438,7 +438,7 @@ function linear_sweep(region, height=1, center, twist=0, scale=1, slices, maxseg
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path = is_undef(maxseg)? p : [
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for (seg=pair(p,true)) each
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let(steps=ceil(norm(seg.y-seg.x)/maxseg))
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lerp(seg.x, seg.y, [0:1/steps:1-EPSILON])
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lerpn(seg.x, seg.y, steps, false)
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]
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)
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rot(twist, p=scale([scale,scale],p=path))
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@ -451,7 +451,7 @@ function linear_sweep(region, height=1, center, twist=0, scale=1, slices, maxseg
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path = is_undef(maxseg)? p : [
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for (seg=pair(p,true)) each
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let(steps=ceil(norm(seg.y-seg.x)/maxseg))
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lerp(seg.x, seg.y, [0:1/steps:1-EPSILON])
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lerpn(seg.x, seg.y, steps, false)
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],
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verts = [
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for (i=[0:1:slices]) let(
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@ -194,7 +194,7 @@ include <structs.scad>
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// square = [[0,0],[1,0],[1,1],[0,1]];
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// spiral = flatten(repeat(concat(square,reverse(square)),5)); // Squares repeat 10 times, forward and backward
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// squareind = [for(i=[0:9]) each [i,i,i,i]]; // Index of the square for each point
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// z = range(40)*.2+squareind;
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// z = count(40)*.2+squareind;
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// path3d = hstack(spiral,z); // 3D spiral
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// rounding = squareind/20;
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// // Setting k=1 means curvature won't be continuous, but curves are as round as possible
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@ -899,7 +899,7 @@ function _make_offset_polyhedron(path,offsets, offset_type, flip_faces, quality,
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vertexcount=0, vertices=[], faces=[] )=
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offsetind==len(offsets)? (
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let(
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bottom = range(n=len(path),s=vertexcount),
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bottom = count(len(path),vertexcount),
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oriented_bottom = !flip_faces? bottom : reverse(bottom)
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) [vertices, concat(faces,[oriented_bottom])]
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) : (
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@ -1956,7 +1956,7 @@ function bezier_patch_degenerate(patch, splinesteps=16, reverse=false) =
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bot_degen = last(patch)[0] == last(last(patch)),
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left_degen = patch[0][0] == last(patch)[0],
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right_degen = last(patch[0]) == last(last(patch)),
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samplepts = range(splinesteps+1)/splinesteps
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samplepts = count(splinesteps+1)/splinesteps
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)
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top_degen && bot_degen && left_degen && right_degen ? // fully degenerate case
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[repeat([patch[0][0]],4), EMPTY_VNF] :
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@ -1990,13 +1990,13 @@ function bezier_patch_degenerate(patch, splinesteps=16, reverse=false) =
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// at this point top_degen is true // only top is degenerate
|
||||
let(
|
||||
full_degen = patch[1][0] == last(patch[1]),
|
||||
rowmax = full_degen ? range(splinesteps+1) :
|
||||
rowmax = full_degen ? count(splinesteps+1) :
|
||||
[for(j=[0:splinesteps]) j<=splinesteps/2 ? 2*j : splinesteps],
|
||||
vbb=echo("single degenerate case"),
|
||||
bpatch = [for(i=[0:1:len(patch[0])-1]) bezier_points(subindex(patch,i), samplepts)],
|
||||
pts = [
|
||||
[bpatch[0][0]],
|
||||
for(j=[1:splinesteps]) bezier_points(subindex(bpatch,j), range(rowmax[j]+1)/rowmax[j])
|
||||
for(j=[1:splinesteps]) bezier_points(subindex(bpatch,j), count(rowmax[j]+1)/rowmax[j])
|
||||
],
|
||||
vnf = vnf_tri_array(pts, reverse=reverse)
|
||||
) [
|
||||
|
|
|
@ -1085,7 +1085,7 @@ function _ISO_thread_tolerance(diameter, pitch, internal=false, tolerance=undef)
|
|||
],
|
||||
|
||||
rangepts = [0.99, 1.4, 2.8, 5.6, 11.2, 22.4, 45, 90, 180, 300],
|
||||
d_ind = floor(lookup(diameter,hstack(rangepts,range(len(rangepts))))),
|
||||
d_ind = floor(lookup(diameter,hstack(rangepts,count(len(rangepts))))),
|
||||
avgd = sqrt(rangepts[d_ind]* rangepts[d_ind+1]),
|
||||
|
||||
T_d2_6 = 90*pow(P, 0.4)*pow(avgd,0.1),
|
||||
|
|
|
@ -595,7 +595,7 @@ function subdivide_long_segments(path, maxlen, closed=false) =
|
|||
[
|
||||
for (p=pair(path,closed)) let(
|
||||
steps = ceil(norm(p[1]-p[0])/maxlen)
|
||||
) each lerp(p[0],p[1],[0:1/steps:1-EPSILON]),
|
||||
) each lerpn(p[0], p[1], steps, false),
|
||||
if (!closed) last(path)
|
||||
];
|
||||
|
||||
|
@ -620,7 +620,7 @@ function slice_profiles(profiles,slices,closed=false) =
|
|||
let(
|
||||
count = is_num(slices) ? repeat(slices,len(profiles)-(closed?0:1)) : slices,
|
||||
slicelist = [for (i=[0:len(profiles)-(closed?1:2)])
|
||||
each [for(j = [0:count[i]]) lerp(profiles[i],select(profiles,i+1),j/(count[i]+1))]
|
||||
each lerpn(profiles[i], select(profiles,i+1), count[i]+1, false)
|
||||
]
|
||||
)
|
||||
concat(slicelist, closed?[]:[profiles[len(profiles)-1]]);
|
||||
|
@ -894,7 +894,7 @@ function associate_vertices(polygons, split, curpoly=0) =
|
|||
str("Split ",cursplit," at polygon ",curpoly," has invalid vertices. Must be in [0:",polylen-1,"]"))
|
||||
len(cursplit)==0 ? associate_vertices(polygons,split,curpoly+1) :
|
||||
let(
|
||||
splitindex = sort(concat(range(polylen), cursplit)),
|
||||
splitindex = sort(concat(count(polylen), cursplit)),
|
||||
newpoly = [for(i=[0:len(polygons)-1]) i<=curpoly ? select(polygons[i],splitindex) : polygons[i]]
|
||||
)
|
||||
associate_vertices(newpoly, split, curpoly+1);
|
||||
|
|
|
@ -335,7 +335,7 @@ function _str_find_last(str,pattern,sindex) =
|
|||
(sindex >=0 ? sindex : undef);
|
||||
|
||||
function _str_find_all(str,pattern) =
|
||||
pattern == "" ? range(len(str)) :
|
||||
pattern == "" ? count(len(str)) :
|
||||
[for(i=[0:1:len(str)-len(pattern)]) if (_str_cmp(str,i,pattern)) i];
|
||||
|
||||
|
||||
|
|
|
@ -133,36 +133,13 @@ module test_repeat() {
|
|||
test_repeat();
|
||||
|
||||
|
||||
module test_range() {
|
||||
assert(range(4) == [0,1,2,3]);
|
||||
assert(range(n=4, step=2) == [0,2,4,6]);
|
||||
assert(range(n=4, s=3, step=3) == [3,6,9,12]);
|
||||
assert(range(e=3) == [0,1,2,3]);
|
||||
assert(range(e=6, step=2) == [0,2,4,6]);
|
||||
assert(range(s=3, e=5) == [3,4,5]);
|
||||
assert(range(s=3, e=8, step=2) == [3,5,7]);
|
||||
assert(range(s=4, e=8, step=2) == [4,6,8]);
|
||||
assert(range(e=4, n=3) == [0,2,4]);
|
||||
assert(range(n=4, s=[3,4], step=[2,3]) == [[3,4], [5,7], [7,10], [9,13]]);
|
||||
module test_count() {
|
||||
assert_equal(count(5), [0,1,2,3,4]);
|
||||
assert_equal(count(5,3), [3,4,5,6,7]);
|
||||
assert_equal(count(4,3,2), [3,5,7,9]);
|
||||
assert_equal(count(5,0,0.25), [0, 0.25, 0.5, 0.75, 1.0]);
|
||||
}
|
||||
test_range();
|
||||
|
||||
|
||||
module test_rangex() {
|
||||
assert_equal(rangex(4), [0,1,2,3]);
|
||||
assert_approx(rangex(5,e=1), [0, 0.2, 0.4, 0.6, 0.8]);
|
||||
assert_equal(rangex(n=4, step=2), [0,2,4,6]);
|
||||
assert_approx(rangex(n=4, step=0.25), [0,0.25,0.5,0.75]);
|
||||
assert_equal(rangex(n=4, s=3, step=3), [3,6,9,12]);
|
||||
assert_equal(rangex(e=3), [0,1,2]);
|
||||
assert_equal(rangex(e=6, step=2), [0,2,4]);
|
||||
assert_equal(rangex(s=3, e=5), [3,4]);
|
||||
assert_equal(rangex(s=3, e=8, step=2), [3,5,7]);
|
||||
assert_equal(rangex(s=4, e=8, step=2), [4,6]);
|
||||
assert_equal(rangex(e=6, n=3), [0,2,4]);
|
||||
assert_equal(rangex(n=4, s=[3,4], step=[2,3]), [[3,4], [5,7], [7,10], [9,13]]);
|
||||
}
|
||||
test_rangex();
|
||||
test_count();
|
||||
|
||||
|
||||
module test_reverse() {
|
||||
|
@ -322,7 +299,7 @@ test_enumerate();
|
|||
|
||||
|
||||
module test_shuffle() {
|
||||
nums1 = [for (i=range(100)) i];
|
||||
nums1 = count(100);
|
||||
nums2 = shuffle(nums1,33);
|
||||
nums3 = shuffle(nums2,99);
|
||||
assert(sort(nums2)==nums1);
|
||||
|
|
|
@ -481,7 +481,7 @@ module test_circle_3points() {
|
|||
radii = rands(10,100,count,seed_value=390);
|
||||
angles = rands(0,360,count,seed_value=699);
|
||||
// 2D tests.
|
||||
for(i = range(count)) {
|
||||
for(i = count(count)) {
|
||||
cp = select(coords,i,i+1);
|
||||
r = radii[i];
|
||||
angs = sort(select(angles,i,i+2));
|
||||
|
@ -506,7 +506,7 @@ module test_circle_3points() {
|
|||
assert(approx(res[2], UP));
|
||||
}
|
||||
}
|
||||
for(i = range(count)) {
|
||||
for(i = count(count)) {
|
||||
cp = select(coords,i,i+1);
|
||||
r = radii[i];
|
||||
angs = sort(select(angles,i,i+2));
|
||||
|
@ -532,7 +532,7 @@ module test_circle_3points() {
|
|||
}
|
||||
}
|
||||
// 3D tests.
|
||||
for(i = range(count)) {
|
||||
for(i = count(count)) {
|
||||
cp = select(coords,i,i+2);
|
||||
r = radii[i];
|
||||
nrm = unit(select(coords,i+10,i+12));
|
||||
|
@ -559,7 +559,7 @@ module test_circle_3points() {
|
|||
assert(approx(res[2], n));
|
||||
}
|
||||
}
|
||||
for(i = range(count)) {
|
||||
for(i = count(count)) {
|
||||
cp = select(coords,i,i+2);
|
||||
r = radii[i];
|
||||
nrm = unit(select(coords,i+10,i+12));
|
||||
|
@ -987,8 +987,8 @@ module test_pointlist_bounds() {
|
|||
|
||||
|
||||
module test_closest_point() {
|
||||
ptlist = [for (i=range(100)) rands(-100,100,2,seed_value=8463)];
|
||||
testpts = [for (i=range(100)) rands(-100,100,2,seed_value=6834)];
|
||||
ptlist = [for (i=count(100)) rands(-100,100,2,seed_value=8463)];
|
||||
testpts = [for (i=count(100)) rands(-100,100,2,seed_value=6834)];
|
||||
for (pt = testpts) {
|
||||
pidx = closest_point(pt,ptlist);
|
||||
dists = [for (p=ptlist) norm(pt-p)];
|
||||
|
@ -1000,8 +1000,8 @@ module test_closest_point() {
|
|||
|
||||
|
||||
module test_furthest_point() {
|
||||
ptlist = [for (i=range(100)) rands(-100,100,2,seed_value=8463)];
|
||||
testpts = [for (i=range(100)) rands(-100,100,2,seed_value=6834)];
|
||||
ptlist = [for (i=count(100)) rands(-100,100,2,seed_value=8463)];
|
||||
testpts = [for (i=count(100)) rands(-100,100,2,seed_value=6834)];
|
||||
for (pt = testpts) {
|
||||
pidx = furthest_point(pt,ptlist);
|
||||
dists = [for (p=ptlist) norm(pt-p)];
|
||||
|
|
|
@ -1133,7 +1133,7 @@ module test_real_roots(){
|
|||
// Wilkinson polynomial is a nasty test:
|
||||
assert_approx(
|
||||
sort(real_roots(poly_mult([[1,-1],[1,-2],[1,-3],[1,-4],[1,-5],[1,-6],[1,-7],[1,-8],[1,-9],[1,-10]]))),
|
||||
range(n=10,s=1));
|
||||
count(10,1));
|
||||
assert_equal(real_roots([3]), []);
|
||||
assert_equal(real_roots(poly_mult([[1,-2,5],[12,-24,24],[-2, -12, -20],[1,-10,50]])),[]);
|
||||
assert_equal(real_roots(poly_mult([[1,-2,5],[12,-24,24],[-2, -12, -20],[1,-10,50],[1,0,0]])),[0,0]);
|
||||
|
|
Loading…
Reference in a new issue