#!/usr/bin/env python3 import cairo import math import random from utils import circle_fill from utils import random_color WIDTH, HEIGHT = 1000, 1000 ANGLE_RANDOM_MIN = -0.6 ANGLE_RANDOM_MAX = 0.6 # how much to shrink each consecutive circle SHRINK = 0.00004 class Branch(): def __init__(self, idx, ctx, x, y, r, ang): ctx.set_source_rgb(255, 0, 0) self.nodes = [Node(ctx, x, y, r, ang, dry=True)] ctx.set_source_rgb(0,0, 0) self.idx = idx self.ctx = ctx self.ended = False def _last_node(self): return self.nodes[-1] def place_next(self, branches): if not self.ended: last = self._last_node() next_x = last.r * math.sin(last.ang) + last.x next_y = last.r * math.cos(last.ang) + last.y next_r = last.r - SHRINK # too small? if next_r < 0.000000001: self.ended = True return False # did we hit canvas edge? if next_x + next_r > 1 or next_x - next_r < 0: self.ended = True return False if next_y + next_r > 1 or next_y - next_r < 0: self.ended = True return False last_nodes = self.nodes[-2:] # did we hit another circle? for branch in branches: for node in branch.nodes: if node not in last_nodes: #!= last and node != self.nodes[-2]: if circles_intersect(node.x, node.y, node.r, next_x, next_y, next_r): self.ended = True return False next_ang = last.ang + random.uniform(ANGLE_RANDOM_MIN, ANGLE_RANDOM_MAX) self.nodes.append(Node(self.ctx, next_x, next_y, next_r, next_ang)) return True def circles_intersect(x1, y1, r1, x2, y2, r2): distance = math.sqrt(math.pow(abs(x2 - x1), 2) + math.pow(abs(y2 - y1), 2)) combined_r = r1 + r2 return distance < combined_r class Node(): def __init__(self, ctx, x, y, r, ang, dry=False): self.x = x self.y = y self.r = r self.ang = ang if not dry: circle_fill(ctx, x, y, r) def __ne__(self, other): return self.x != other.x or self.y != other.y or self.r != other.r or self.ang != other.ang def grow_subs(ctx, subs, branches): new_subs = [] created = False for branch in subs: # create a sub branch based on length sub_branches = len(branch.nodes) // 10 if sub_branches > 1: created = True for i in range(sub_branches): for n in range(15): # attempts at growing branches start_node = random.choice(branch.nodes) # start perpendicular to our last angle start_angle = start_node.ang + random.choice([90, -90]) + random.uniform(-5, 5) start_x = start_node.r * math.sin(start_angle) + start_node.x start_y = start_node.r * math.cos(start_angle) + start_node.y start_r = start_node.r - 0.002 new_branch = Branch(i, ctx, start_x, start_y, start_r, start_angle) if new_branch.place_next(branches): break branches.append(new_branch) new_subs.append(new_branch) if not created: return while not all([branch.ended for branch in new_subs]): for branch in new_subs: branch.place_next(branches) return new_subs def main(): surface = cairo.ImageSurface(cairo.FORMAT_ARGB32, WIDTH, HEIGHT) ctx = cairo.Context(surface) ctx.scale(WIDTH, HEIGHT) # Normalizing the canvas # place seeds branches = [] #for b in range(6): # start_x = random.uniform(0.2, 0.8) # start_y = random.uniform(0.2, 0.8) start_r = 0.015 # start_angle = random.randint(0, 360) # branches.append(Branch(b, ctx, start_x, start_y, start_r, start_angle)) branches.append(Branch(0, ctx, 0.5, 0.4, start_r, 180)) branches.append(Branch(1, ctx, 0.4, 0.5, start_r, 270)) branches.append(Branch(2, ctx, 0.6, 0.5, start_r, 90)) branches.append(Branch(3, ctx, 0.5, 0.6, start_r, 0)) # grow initial branches while not all([b.ended for b in branches]): for branch in branches: branch.place_next(branches) # start branching off #subs = [] subs = branches try: for x in range(8): if subs == None: return subs = grow_subs(ctx, subs, branches) surface.write_to_png("out/hyphae.png") # Output to PNG input('next') finally: surface.write_to_png("out/hyphae.png") # Output to PNG if __name__ == '__main__': main()