def Hull2D (P, m, H): #print m, H lines = [] n = len (P) CHs = [] num = n/m a = 0 while a < n: b = min (a+m, n) l = P[a:b] ids = [] for p in l: ids.append (p.hilight ()) ch = Graham (l) #ch.hide () for p in P[a:b]: p.unhilight (ids.pop ()) CHs.append (ch) a = b i0 = 0 # encontrando o ponto mais a direita p0 = CHs[0].pts for ch in CHs: for p in ch.to_list (): if p.x > p0.x: p0 = p elif p.x == p0.x: if p.x > p0.x: p0 = p fecho = [ p0 ] for ch in CHs: ch.hide () #control.sleep (2) for k in range (0, H): Q = [] for ch in CHs: ch.plot () p = ch.pts initial = 1 while 1: direction = area2 (fecho[-1], p, p.next) if direction < 0: p = p.next initial = 0 elif direction == 0 \ and dist2 (fecho[-1], p) \ < dist2 (fecho[-1], p.next): p = p.next initial = 0 elif initial: p = p.next else: Q.append (p) p.hilight () control.sleep () ch.pts = p.prev ch.hide () break control.sleep () p = Q[0] for q in Q[1:]: direction = area2 (fecho[-1], p, q) if direction < 0: p = q elif direction == 0: if (dist2 (fecho[-1], p) < dist2 (fecho[-1], q)): p = q for q in Q: q.unhilight () lines.append (fecho[-1].lineto (p, 'green')) fecho.append (p) if p == p0: #for ch in CHs: ch.hide () #print 'fecho =',`fecho` fecho.pop () for i in lines: control.plot_delete (i) poly = Polygon (fecho) poly.plot () return poly #for ch in CHs: ch.hide () for i in lines: control.plot_delete (i) return None
def Diameter (l): """Algoritmo Diametro para encontrar o par de pontos mais distantes Ele consiste de: - determinar o fecho convexo dos pontos passados - determinar o conjunto de pares antipodas do fecho convexo - determinar o par antipoda cujos pontos estao a uma distancia maxima """ if len (l) < 2: return None if len (l) == 2: ret = Segment (l[0], l[1]) ret.extra_info = 'distancia: %.2f'%math.sqrt (dist2 (l[0], l[1])) return ret ch = Graham (l) ch.hide () ch.plot (config.COLOR_ALT4) control.sleep () pairs = antipodes (ch) cores = (config.COLOR_ALT1,) #print `pairs` i=0 for p,q in pairs: p.hilight (cores[i]) q.hilight (cores[i]) p.lineto (q, cores[i]) i = (i+1) % len (cores) control.sleep () farthest = dist2 (pairs[0][0], pairs[0][1]) a = pairs[0][0] b = pairs[0][1] hia = a.hilight () hib = b.hilight () id = a.lineto (b) for i in range (1, len (pairs)): dist = dist2 (pairs[i][0], pairs[i][1]) if dist > farthest: control.freeze_update () a.unhilight (hia) b.unhilight (hib) control.plot_delete (id) farthest = dist a = pairs[i][0] b = pairs[i][1] hia = a.hilight () hib = b.hilight () id = a.lineto (b) control.thaw_update () ret = Segment (a, b) ret.extra_info = 'distancia: %.2f'%math.sqrt (farthest) return ret
def Diameter(l):
"""Algoritmo Diametro para encontrar o par de pontos mais distantes
Ele consiste de:
- determinar o fecho convexo dos pontos passados
- determinar o conjunto de pares antipodas do fecho convexo
- determinar o par antipoda cujos pontos estao a uma distancia maxima
"""
if len(l) < 2: return None
if len(l) == 2:
ret = Segment(l[0], l[1])
ret.extra_info = 'distancia: %.2f' % math.sqrt(dist2(l[0], l[1]))
return ret
ch = Graham(l)
ch.hide()
ch.plot(config.COLOR_ALT4)
control.sleep()
pairs = antipodes(ch)
cores = (config.COLOR_ALT1, )
#print `pairs`
i = 0
for p, q in pairs:
p.hilight(cores[i])
q.hilight(cores[i])
p.lineto(q, cores[i])
i = (i + 1) % len(cores)
control.sleep()
farthest = dist2(pairs[0][0], pairs[0][1])
a = pairs[0][0]
b = pairs[0][1]
hia = a.hilight()
hib = b.hilight()
id = a.lineto(b)
for i in range(1, len(pairs)):
dist = dist2(pairs[i][0], pairs[i][1])
if dist > farthest:
control.freeze_update()
a.unhilight(hia)
b.unhilight(hib)
control.plot_delete(id)
farthest = dist
a = pairs[i][0]
b = pairs[i][1]
hia = a.hilight()
hib = b.hilight()
id = a.lineto(b)
control.thaw_update()
ret = Segment(a, b)
ret.extra_info = 'distancia: %.2f' % math.sqrt(farthest)
return ret
def Hull2D (P, m, H): #print m, H lines = [] n = len (P) CHs = [] num = n/m a = 0 while a < n: b = min (a+m, n) l = P[a:b] ids = [] for p in l: ids.append (p.hilight ()) ch = Graham (l) #ch.hide () for p in P[a:b]: p.unhilight (ids.pop ()) CHs.append (ch) a = b i0 = 0 # encontrando o ponto mais a direita p0 = CHs[0].pts for ch in CHs: for p in ch.to_list (): if p.x > p0.x: p0 = p elif p.x == p0.x: if p.x > p0.x: p0 = p fecho = [ p0 ] for ch in CHs: ch.hide () #control.sleep (2) for k in range (0, H): Q = [] for ch in CHs: ch.plot () p = ch.pts initial = 1 while 1: direction = area2 (fecho[-1], p, p.next) if direction < 0: p = p.next initial = 0 elif direction == 0 \ and dist2 (fecho[-1], p) \ < dist2 (fecho[-1], p.next): p = p.next initial = 0 elif initial: p = p.next else: Q.append (p) p.hilight () control.sleep () ch.pts = p.prev ch.hide () break control.sleep () p = Q[0] for q in Q[1:]: direction = area2 (fecho[-1], p, q) if direction < 0: p = q elif direction == 0: if (dist2 (fecho[-1], p) < dist2 (fecho[-1], q)): p = q for q in Q: q.unhilight () lines.append (fecho[-1].lineto (p, 'green')) fecho.append (p) if p == p0: #for ch in CHs: ch.hide () #print 'fecho =',`fecho` fecho.pop () for i in lines: control.plot_delete (i) poly = Polygon (fecho) poly.plot () return poly #for ch in CHs: ch.hide () for i in lines: control.plot_delete (i) return None