simplex wip: use gsl_vector_get for X, for abandonment

[moebius3.git] / meshscad

diff --git a/meshscad b/meshscad
index c8924b7ab6edf438137ef88cd7d9ccd6c59ef991..ad3194929243001d5942498650ceee7216fe159d 100755 (executable)
--- a/meshscad
+++ b/meshscad
@@ -1,4 +1,4 @@
-#!/usr/bin/python
+#!/usr/bin/python3
 
 from __future__ import print_function
 
@@ -8,18 +8,21 @@ signal.signal(signal.SIGINT, signal.SIG_DFL)
 from moebius import *
 from scad import *
 
-nomsize = 50;
-wire = 3.0;
+nomsize = 30;
+wire = 1.500;
 
 # number of wires
 kv = 24
 kw = 16
 
 # resolution
-nv = 80
-nw = 80
+nv = 200
+nw = 200
 ns = 4 # around tube, should be even
 
+from moedebug import *
+dbg_file(sys.stderr)
+
 nv += -nv % kv
 nw += -nw % kw
 
@@ -30,8 +33,14 @@ m = Moebius(nv, nw)
 
 def dpr(v): return '%+3f %+3f %+3f' % tuple(v)
 
-def round_wire(p, vec_surfacenormal, vec_acrosswire, sigma):
-  return r
+def points_round_wire(p, norm, acrs, sigmas):
+  for sigma in sigmas:
+    delta = norm * sin(sigma) + acrs * cos(sigma)
+    r = p + wire/nomsize * delta
+    yield r
+
+def calc_sigmas(ss):
+  return [ (s + 0.5)/ns * tau for s in ss ]
 
 def make_moebius(objname):
   print('module %s(){' % objname)
@@ -43,32 +52,45 @@ def make_moebius(objname):
     #print(' QCv,w,T',v,w,is_trav, file=sys.stderr)
     for ab in 0,1:
       p, norm, extt, trav = m.details(v + ab*(not is_trav), w + ab*is_trav)
-      for sx in 0,1:
-        sigma = sigmas[sx]
-        if is_trav: acrs = extt
-        else: acrs = trav
-        delta = norm * sin(sigma) + acrs * cos(sigma)
-        r = p + wire/nomsize * delta
-        #print(' RW,ab,sx',ab,sx,
-        #      'r=',dpr(r),
-        #      'p=',dpr(p),
-        #      'norm=',dpr(norm),
-        #      'extt=',dpr(extt),
-        #      'acrs=',dpr(acrs),
-        #      'delta=',dpr(delta),
-        #      's=','%4f' % sigma,
-        #      file=sys.stderr)
+      if is_trav: acrs = extt
+      else: acrs = trav
+      #print(' RW,ab,sx',ab,sx,
+      #      'r=',dpr(r),
+      #      'p=',dpr(p),
+      #      'norm=',dpr(norm),
+      #      'extt=',dpr(extt),
+      #      'acrs=',dpr(acrs),
+      #      'delta=',dpr(delta),
+      #      's=','%4f' % sigma,
+      #      file=sys.stderr)
+      for r in points_round_wire(p, norm, acrs, sigmas):
         yield r
 
   for v in range(0, nv):
     for w in range(0, nw+1):
+      extw = w
+      if extw > nw/2: extw = nw-w
+      # each extent wire has to go round twice to meet itself
+      # (except the middle one, if there is one, where nw/2 = nw - nw/2
+      # and it gets to be by itself
       for s in range(0, ns):
-        sigmas = [ (s + sx + 0.5)/ns * tau for sx in 0,1 ]
+        sigmas = calc_sigmas([s + sx for sx in (0,1)])
         #print('VWS',v,w,s, sigmas, file=sys.stderr)
         if not w % each_w:
-          extents[w % nw].quad([ cnr for cnr in qc(v,w,sigmas,False) ])
+          extents[extw].quad([ cnr for cnr in qc(v,w,sigmas,False) ])
         if not v % each_v and w < nw:
-          travers[v].quad([ cnr for cnr in qc(v,w,sigmas,True) ])
+          travers[v].rquad([ cnr for cnr in qc(v,w,sigmas,True) ])
+    if not v % each_v:
+      for w in 0, nw:
+        p, norm, extt, trav = m.details(v, w)
+        cnrs = points_round_wire(p, norm, extt, calc_sigmas(range(0,ns)))
+        cnrs = list(cnrs)
+        if w: cnrs.reverse()
+        for s in range(0, ns-1):
+          travers[v].triangle(cnrs[s],
+                              cnrs[s+1],
+                              cnrs[ns-1])
+
   for w in range(0, nw):
     print('// extent w=', w)
     extents[w].writeout_core(nomsize)