Demo/turtle/tdemo_fractalcurves.py - platform/external/python/cpython2 - Gitiles

 #!/usr/bin/python
 """      turtle-example-suite:

         tdemo_fractalCurves.py

 This program draws two fractal-curve-designs:
 (1) A hilbert curve (in a box)
 (2) A combination of Koch-curves.

 The CurvesTurtle class and the fractal-curve-
 methods are taken from the PythonCard example
 scripts for turtle-graphics.
 """
 from turtle import *
 from time import sleep, clock

 class CurvesTurtle(Pen):
     # example derived from
     # Turtle Geometry: The Computer as a Medium for Exploring Mathematics
     # by Harold Abelson and Andrea diSessa
     # p. 96-98
     def hilbert(self, size, level, parity):
         if level == 0:
             return
         # rotate and draw first subcurve with opposite parity to big curve
         self.left(parity * 90)
         self.hilbert(size, level - 1, -parity)
         # interface to and draw second subcurve with same parity as big curve
         self.forward(size)
         self.right(parity * 90)
         self.hilbert(size, level - 1, parity)
         # third subcurve
         self.forward(size)
         self.hilbert(size, level - 1, parity)
         # fourth subcurve
         self.right(parity * 90)
         self.forward(size)
         self.hilbert(size, level - 1, -parity)
         # a final turn is needed to make the turtle
         # end up facing outward from the large square
         self.left(parity * 90)

     # Visual Modeling with Logo: A Structural Approach to Seeing
     # by James Clayson
     # Koch curve, after Helge von Koch who introduced this geometric figure in 1904
     # p. 146
     def fractalgon(self, n, rad, lev, dir):
         import math

         # if dir = 1 turn outward
         # if dir = -1 turn inward
         edge = 2 * rad * math.sin(math.pi / n)
         self.pu()
         self.fd(rad)
         self.pd()
         self.rt(180 - (90 * (n - 2) / n))
         for i in range(n):
             self.fractal(edge, lev, dir)
             self.rt(360 / n)
         self.lt(180 - (90 * (n - 2) / n))
         self.pu()
         self.bk(rad)
         self.pd()

     # p. 146
     def fractal(self, dist, depth, dir):
         if depth < 1:
             self.fd(dist)
             return
         self.fractal(dist / 3, depth - 1, dir)
         self.lt(60 * dir)
         self.fractal(dist / 3, depth - 1, dir)
         self.rt(120 * dir)
         self.fractal(dist / 3, depth - 1, dir)
         self.lt(60 * dir)
         self.fractal(dist / 3, depth - 1, dir)

 def main():
     ft = CurvesTurtle()

     ft.reset()
     ft.speed(0)
     ft.ht()
     ft.tracer(1,0)
     ft.pu()

     size = 6
     ft.setpos(-33*size, -32*size)
     ft.pd()

     ta=clock()
     ft.fillcolor("red")
     ft.fill(True)
     ft.fd(size)

     ft.hilbert(size, 6, 1)

     # frame
     ft.fd(size)
     for i in range(3):
         ft.lt(90)
         ft.fd(size*(64+i%2))
     ft.pu()
     for i in range(2):
         ft.fd(size)
         ft.rt(90)
     ft.pd()
     for i in range(4):
         ft.fd(size*(66+i%2))
         ft.rt(90)
     ft.fill(False)
     tb=clock()
     res =  "Hilbert: %.2fsec. " % (tb-ta)

     sleep(3)

     ft.reset()
     ft.speed(0)
     ft.ht()
     ft.tracer(1,0)

     ta=clock()
     ft.color("black", "blue")
     ft.fill(True)
     ft.fractalgon(3, 250, 4, 1)
     ft.fill(True)
     ft.color("red")
     ft.fractalgon(3, 200, 4, -1)
     ft.fill(False)
     tb=clock()
     res +=  "Koch: %.2fsec." % (tb-ta)
     return res

 if __name__  == '__main__':
     msg = main()
     print msg
     mainloop()
	#!/usr/bin/python
	""" turtle-example-suite:

	tdemo_fractalCurves.py

	This program draws two fractal-curve-designs:
	(1) A hilbert curve (in a box)
	(2) A combination of Koch-curves.

	The CurvesTurtle class and the fractal-curve-
	methods are taken from the PythonCard example
	scripts for turtle-graphics.
	"""
	from turtle import *
	from time import sleep, clock

	class CurvesTurtle(Pen):
	# example derived from
	# Turtle Geometry: The Computer as a Medium for Exploring Mathematics
	# by Harold Abelson and Andrea diSessa
	# p. 96-98
	def hilbert(self, size, level, parity):
	if level == 0:
	return
	# rotate and draw first subcurve with opposite parity to big curve
	self.left(parity * 90)
	self.hilbert(size, level - 1, -parity)
	# interface to and draw second subcurve with same parity as big curve
	self.forward(size)
	self.right(parity * 90)
	self.hilbert(size, level - 1, parity)
	# third subcurve
	self.forward(size)
	self.hilbert(size, level - 1, parity)
	# fourth subcurve
	self.right(parity * 90)
	self.forward(size)
	self.hilbert(size, level - 1, -parity)
	# a final turn is needed to make the turtle
	# end up facing outward from the large square
	self.left(parity * 90)

	# Visual Modeling with Logo: A Structural Approach to Seeing
	# by James Clayson
	# Koch curve, after Helge von Koch who introduced this geometric figure in 1904
	# p. 146
	def fractalgon(self, n, rad, lev, dir):
	import math

	# if dir = 1 turn outward
	# if dir = -1 turn inward
	edge = 2 * rad * math.sin(math.pi / n)
	self.pu()
	self.fd(rad)
	self.pd()
	self.rt(180 - (90 * (n - 2) / n))
	for i in range(n):
	self.fractal(edge, lev, dir)
	self.rt(360 / n)
	self.lt(180 - (90 * (n - 2) / n))
	self.pu()
	self.bk(rad)
	self.pd()

	# p. 146
	def fractal(self, dist, depth, dir):
	if depth < 1:
	self.fd(dist)
	return
	self.fractal(dist / 3, depth - 1, dir)
	self.lt(60 * dir)
	self.fractal(dist / 3, depth - 1, dir)
	self.rt(120 * dir)
	self.fractal(dist / 3, depth - 1, dir)
	self.lt(60 * dir)
	self.fractal(dist / 3, depth - 1, dir)

	def main():
	ft = CurvesTurtle()

	ft.reset()
	ft.speed(0)
	ft.ht()
	ft.tracer(1,0)
	ft.pu()

	size = 6
	ft.setpos(-33size, -32size)
	ft.pd()

	ta=clock()
	ft.fillcolor("red")
	ft.fill(True)
	ft.fd(size)

	ft.hilbert(size, 6, 1)

	# frame
	ft.fd(size)
	for i in range(3):
	ft.lt(90)
	ft.fd(size*(64+i%2))
	ft.pu()
	for i in range(2):
	ft.fd(size)
	ft.rt(90)
	ft.pd()
	for i in range(4):
	ft.fd(size*(66+i%2))
	ft.rt(90)
	ft.fill(False)
	tb=clock()
	res = "Hilbert: %.2fsec. " % (tb-ta)

	sleep(3)

	ft.reset()
	ft.speed(0)
	ft.ht()
	ft.tracer(1,0)

	ta=clock()
	ft.color("black", "blue")
	ft.fill(True)
	ft.fractalgon(3, 250, 4, 1)
	ft.fill(True)
	ft.color("red")
	ft.fractalgon(3, 200, 4, -1)
	ft.fill(False)
	tb=clock()
	res += "Koch: %.2fsec." % (tb-ta)
	return res

	if __name__ == '__main__':
	msg = main()
	print msg
	mainloop()