I'm having trouble with the following code. It seems to respond to the escape key but it freezes really bad. I'm using pyscripter with python 2.7 and pygame.
# An example implementation of the algorithm described at # http://www.niksula.cs.hut.fi/~hkankaan/Homepages/metaballs.html # # The code contains some references to the document above, in form # ### Formula (x) # to make clear where each of the formulas is implemented (and what # it looks like in Python) # # Since Python doesn't have an in-built vector type, I used complex # numbers for coordinates (x is the real part, y is the imaginary part) # # Made by Hannu Kankaanpää. Use for whatever you wish. import math import pygame from pygame.locals import * def main(): # This is where the execution starts. # First initialize the screen. pygame.init() screen = pygame.display.set_mode((640, 480)) # Then create a couple of balls balls = [Ball(350 + 100j, size=3), Ball(20 + 200j, size=2), Ball(280 + 140j, size=4), Ball(400 + 440j, size=3)] # And a metaball system (see below for class definition) mbs = MetaballSystem(balls, goo=2.0, threshold=0.0004, screen=screen) while True: # clear screen with black screen.fill((0, 0, 0)) # move ball number 0 according to mouse position if pygame.mouse.get_focused(): balls.pos = complex(*pygame.mouse.get_pos()) # Draw the balls. # Try different methods: euler, rungeKutta2 and rungeKutta4 drawBalls(differentialMethod=rungeKutta2, metaballSystem=mbs, step=20, screen=screen) pygame.display.flip() # exit when esc is pressed for event in pygame.event.get(): if event.type == QUIT: return elif event.type == KEYDOWN: if event.key == K_ESCAPE: return def drawBalls(differentialMethod, metaballSystem, step, screen): mbs = metaballSystem balls = mbs.balls # First, track the border for all balls and store # it to pos0 and edgePos. The latter will move along the border, # pos0 stays at the initial coordinates. for ball in balls: ball.pos0 = mbs.trackTheBorder(ball.pos + 1j) ball.edgePos = ball.pos0 ball.tracking = True loopIndex = 0 while loopIndex < 200: loopIndex += 1 for ball in balls: if not ball.tracking: continue # store the old coordinates old_pos = ball.edgePos # walk along the tangent, using chosen differential method ball.edgePos = differentialMethod(ball.edgePos, step, mbs.calcTangent) # correction step towards the border ball.edgePos, tmp = mbs.stepOnceTowardsBorder(ball.edgePos) pygame.draw.line(screen, (255, 255, 255), (old_pos.real, old_pos.imag), (ball.edgePos.real, ball.edgePos.imag)) # check if we've gone a full circle or hit some other # edge tracker for ob in balls: if (ob is not ball or loopIndex > 3) and \ abs(ob.pos0 - ball.edgePos) < step: ball.tracking = False tracking = 0 for ball in balls: if ball.tracking: tracking += 1 if tracking == 0: break class Ball: """Single metaball.""" def __init__(self, pos, size): self.pos = pos self.size = size class MetaballSystem: """A class that manages the metaballs and can calculate several useful values from the system. """ def __init__(self, balls, goo, threshold, screen): self.balls = balls self.goo = goo self.threshold = threshold self.minSize = min([ball.size for ball in balls]) self.screen = screen def calcForce(self, pos): """Return the metaball field's force at point 'pos'.""" force = 0 for ball in self.balls: ### Formula (1) div = abs(ball.pos - pos)**self.goo if div != 0: # to prevent division by zero force += ball.size / div else: force += 10000 #"big number" return force def calcNormal(self, pos): """Return a normalized (magnitude = 1) normal at point 'pos'.""" np = 0j for ball in self.balls: ### Formula (3) div = abs(ball.pos - pos)**(2 + self.goo) np += -self.goo * ball.size * (ball.pos - pos) / div return np / abs(np) def calcTangent(self, pos): """Return a normalized (magnitude = 1) tangent at point 'pos'.""" np = self.calcNormal(pos) ### Formula (7) return complex(-np.imag, np.real) def stepOnceTowardsBorder(self, pos): """Step once towards the border of the metaball field, return new coordinates and force at old coordinates. """ force = self.calcForce(pos) np = self.calcNormal(pos) ### Formula (5) stepsize = (self.minSize / self.threshold)**(1 / self.goo) - \ (self.minSize / force)**(1 / self.goo) + 0.01 return (pos + np * stepsize, force) def trackTheBorder(self, pos): """Track the border of the metaball field and return new coordinates. """ force = 9999999 # loop until force is weaker than the desired threshold while force > self.threshold: pos, force = self.stepOnceTowardsBorder(pos) # show a little debug output (i.e. plot yellow pixels) sz = self.screen.get_size() if 0 <= pos.real < sz and 0 <= pos.imag < sz: self.screen.set_at((int(pos.real), int(pos.imag)), (255, 255, 0)) return pos def euler(pos, h, func): """Euler's method. The most simple way to solve differential systems numerically. """ return pos + h * func(pos) def rungeKutta2(pos, h, func): """Runge-Kutta 2 (=mid-point). This is only a little more complex than the Euler's method, but significantly better. """ return pos + h * func(pos + func(pos) * h / 2) def rungeKutta4(pos, h, func): """Runge-Kutta 4. RK4 is quite a bit more complex than RK2. RK2 with a small stepsize is often more useful than this. """ t1 = func(pos) t2 = func(pos + t1 * h / 2) t3 = func(pos + t2 * h / 2) t4 = func(pos + t3 * h) return pos + (h / 6) * (t1 + 2*t2 + 2*t3 + t4) if __name__ == '__main__': main()