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https://github.com/jhasse/poly2tri.git
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added polydecomp
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@ -4,6 +4,7 @@
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from math import pi as PI
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from gl cimport *
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include "polydecomp.pxi"
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cdef extern from 'math.h':
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double cos(double)
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150
python/framework/polydecomp.pxi
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150
python/framework/polydecomp.pxi
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@ -0,0 +1,150 @@
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##
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## Ported from PolyDeomp by Mark Bayazit
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## http://mnbayazit.com/406/credit
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##
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from sys import float_info
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def makeCCW(list poly):
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cdef int br = 0
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# find bottom right point
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for i from 1 <= i < len(poly):
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if poly[i][1] < poly[br][1] or (poly[i][1] == poly[br][1] and poly[i][0] > poly[br][0]):
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br = i
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# reverse poly if clockwise
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if not left(at(poly, br - 1), at(poly, br), at(poly, br + 1)):
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poly.reverse()
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cpdef list decompose_poly(list poly, list polys):
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cdef list upperInt = [], lowerInt = [], p = [], closestVert = []
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cdef float upperDist, lowerDist, d, closestDist
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cdef int upper_index, lower_index, closest_index
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cdef list lower_poly = [], upper_poly = []
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for i from 0 <= i < len(poly):
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if is_reflex(poly, i):
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upperDist = lowerDist = float_info.max
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for j from 0 <= j < len(poly):
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if left(at(poly, i - 1), at(poly, i), at(poly, j)) and rightOn(at(poly, i - 1), at(poly, i), at(poly, j - 1)):
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# if line intersects with an edge
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# find the point of intersection
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p = intersection(at(poly, i - 1), at(poly, i), at(poly, j), at(poly, j - 1))
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if right(at(poly, i + 1), at(poly, i), p):
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# make sure it's inside the poly
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d = sqdist(poly[i], p)
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if d < lowerDist:
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# keep only the closest intersection
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lowerDist = d
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lowerInt = p
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lower_index = j
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if left(at(poly, i + 1), at(poly, i), at(poly, j + 1)) and rightOn(at(poly, i + 1), at(poly, i), at(poly, j)):
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p = intersection(at(poly, i + 1), at(poly, i), at(poly, j), at(poly, j + 1))
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if left(at(poly, i - 1), at(poly, i), p):
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d = sqdist(poly[i], p)
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if d < upperDist:
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upperDist = d
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upperInt = p
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upper_index = j
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# if there are no vertices to connect to, choose a point in the middle
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if lower_index == (upper_index + 1) % len(poly):
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p[0] = (lowerInt[0] + upperInt[0]) / 2
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p[1] = (lowerInt[1] + upperInt[1]) / 2
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if i < upper_index:
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lower_poly.extend(poly[i:upper_index+1])
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lower_poly.append(p)
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upper_poly.append(p)
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if lower_index != 0:
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upper_poly.extend(poly[lower_index:])
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upper_poly.extend(poly[:i+1])
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else:
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if i != 0:
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lower_poly.extend(poly[i:])
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lower_poly.extend(poly[:upper_index+1])
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lower_poly.append(p)
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upper_poly.append(p)
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upper_poly.extend(poly[lower_index:i+1])
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else:
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# connect to the closest point within the triangle
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if lower_index > upper_index:
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upper_index += len(poly)
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closestDist = float_info.max
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for j from lower_index <= j <= upper_index:
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if leftOn(at(poly, i - 1), at(poly, i), at(poly, j)) and rightOn(at(poly, i + 1), at(poly, i), at(poly, j)):
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d = sqdist(at(poly, i), at(poly, j))
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if d < closestDist:
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closestDist = d
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closestVert = at(poly, j)
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closest_index = j % len(poly)
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if i < closest_index:
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lower_poly.extend(poly[i:closest_index+1])
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if closest_index != 0:
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upper_poly.extend(poly[closest_index:])
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upper_poly.extend(poly[:i+1])
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else:
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if i != 0:
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lower_poly.extend(poly[i:])
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lower_poly.extend(poly[:closest_index+1])
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upper_poly.extend(poly[closest_index:i+1])
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# solve smallest poly first
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if len(lower_poly) < len(upper_poly):
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decompose_poly(lower_poly, polys)
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decompose_poly(upper_poly, polys)
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else:
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decompose_poly(upper_poly, polys)
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decompose_poly(lower_poly, polys)
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return
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polys.append(poly)
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cdef list intersection(list p1, list p2, list q1, list q2):
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cdef list i = []
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cdef float a1, b1, c1, a2, b2, c2, det
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a1 = p2[1] - p1[1]
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b1 = p1[0] - p2[0]
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c1 = a1 * p1[0] + b1 * p1[1]
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a2 = q2[1] - q1[1]
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b2 = q1[0] - q2[0]
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c2 = a2 * q1[0] + b2 * q1[1]
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det = a1 * b2 - a2 * b1
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if not eq(det, 0):
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# lines are not parallel
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i.append((b2 * c1 - b1 * c2) / det)
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i.append((a1 * c2 - a2 * c1) / det)
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return i
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cdef bool eq(float a, float b):
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return abs(a - b) <= 1e-8
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cdef list at(list v, int i):
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return v[i%len(v)]
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cdef float area(list a, list b, list c):
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return (((b[0] - a[0])*(c[1] - a[1]))-((c[0] - a[0])*(b[1] - a[1])))
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cdef bool left(list a, list b, list c):
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return area(a, b, c) > 0
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cdef bool leftOn(list a, list b, list c):
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return area(a, b, c) >= 0
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cdef bool right(list a, list b, list c):
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return area(a, b, c) < 0
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cdef bool rightOn(list a, list b, list c):
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return area(a, b, c) <= 0
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cdef float sqdist(list a, list b):
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cdef float dx = b[0] - a[0]
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cdef float dy = b[1] - a[1]
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return dx * dx + dy * dy
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cdef bool is_reflex(list poly, int i):
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return right(at(poly, i - 1), at(poly, i), at(poly, i + 1))
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@ -1,5 +1,5 @@
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#!/usr/bin/env python2.6
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from framework import Game, draw_polygon, reset_zoom, draw_line
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from framework import Game, draw_polygon, reset_zoom, draw_line, decompose_poly, makeCCW
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from seidel import Triangulator
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@ -7,11 +7,26 @@ class Poly2Tri(Game):
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screen_size = 800.0, 600.0
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dude = [[174.50415,494.59368],[215.21844,478.87939],[207.36129,458.87939],[203.07558,441.02225],[203.07558,418.1651],
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[210.93272,394.59367],[224.50415,373.1651],[241.64701,358.1651],[257.36129,354.59367],[275.93272,356.73653],
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[293.07558,359.59367],[309.50415,377.45082],[322.36129,398.1651],[331.64701,421.73653],[335.21844,437.45082],
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[356.64701,428.52225],[356.1113,428.34367],[356.1113,428.34367],[368.78987,419.59368],[349.50415,384.59367],
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[323.78987,359.59367],[290.93272,343.87939],[267.36129,341.02225],[264.50415,331.02225],[264.50415,321.02225],
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[268.78987,306.02225],[285.93272,286.02225],[295.21844,270.30796],[303.78987,254.59367],[306.64701,213.87939],
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[320,202.36218],[265,202.36218],[286.64701,217.45082],[293.78987,241.02225],[285,257.36218],[270.93272,271.73653],
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[254.50415,266.02225],[250.93272,248.1651],[256.64701,233.1651],[256.64701,221.02225],[245.93272,215.30796],
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[238.78987,216.73653],[233.78987,232.45082],[232.36129,249.59367],[243.07558,257.09367],[242.89701,270.30796],
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[235.93272,279.95082],[222.36129,293.1651],[205.21844,300.6651],[185,297.36218],[170,242.36218],[175,327.36218],
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[185,322.36218],[195,317.36218],[230.75415,301.02225],[235.39701,312.45082],[240.57558,323.52225],
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[243.61129,330.48653],[245.21844,335.12939],[245.03987,344.4151],[229.86129,349.4151],[209.14701,362.09367],
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[192.89701,377.80796],[177.18272,402.27225],[172.36129,413.87939],[169.14701,430.48653],[168.61129,458.52225],
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[168.61129,492.80796]]
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def __init__(self):
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super(Poly2Tri, self).__init__(*self.screen_size)
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# Load point set
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file_name = "../data/star.dat"
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file_name = "../data/dude.dat"
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self.points = self.load_points(file_name)
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# Triangulate
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@ -25,19 +40,32 @@ class Poly2Tri(Game):
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self.edges = seidel.edge_list
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print "time (ms) = %f , num triangles = %d" % (dt, len(self.triangles))
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for p in self.dude:
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p[0] -= 75
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makeCCW(self.dude)
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self.dude_poly = []
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t1 = self.time
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decompose_poly(self.dude, self.dude_poly)
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dt = (self.time - t1) * 1000.0
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print "time (ms) = %f , num polies = %d" % (dt, len(self.dude_poly))
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self.main_loop()
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def update(self):
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pass
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def render(self):
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reset_zoom(2.1, (400, 100), self.screen_size)
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reset_zoom(2.1, (300, 450), self.screen_size)
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red = 255, 0, 0
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yellow = 255, 255, 0
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green = 0, 255, 0
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for t in self.triangles:
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draw_polygon(t, red)
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for p in self.dude_poly:
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draw_polygon(p, red)
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'''
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for t in self.trapezoids:
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verts = self.trapezoids[t].vertices()
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