def radii(q, initial_radius, range1, maximum1, Circles, cols1, w1, width, height): valid = True yaxis = math.floor(q / cols1) xaxis = math.floor(q - yaxis * cols1) w_use = w1 x = np.random.randint(math.floor(xaxis * w_use), math.floor((xaxis + 1) * w_use)) y = np.random.randint(math.floor(yaxis * w_use), math.floor((yaxis + 1) * w_use)) #if the randomly selected point in the void grid is too close to borders, it will be deleted. m = initial_radius min_boundary = [x, y, (width - x), (height - y)] min_b = np.amin(min_boundary) if min_b < m: valid = None #in the reseaching sphere area with 'mindis' radius min_around = [] if valid is True: for j in range(len(Circles)): if ((x - range1) < Circles[j].x < (x + range1)) or ((y - range1) < Circles[j].y < (y + range1)): k = _distance2d.dist(x, y, Circles[j].x, Circles[j].y) - Circles[j].r if (k < m): valid = None break else: min_around.append(k) #generate particles if valid is True: if not min_around: min_a = 0 else: min_a = np.amin(min_around) if min_a <= min_b: if min_a <= maximum1: Circles.append(_Circle.Circle(x, y, min_a, width, height)) return min_a else: Circles.append(_Circle.Circle(x, y, maximum1, width, height)) return maximum1 elif min_a > min_b: if min_b <= maximum1: Circles.append(_Circle.Circle(x, y, min_b, width, height)) return min_b else: Circles.append(_Circle.Circle(x, y, maximum1, width, height)) return maximum1 else: return False
def point_poisson(): global occupation_poisson while len(active) > 0: check = np.random.randint(0, len(active)) found = None for n in range(k): s = _random_vector_function.random_vector_function( r, math.floor(r * 2)) sample = [] for i in range(0, len(s)): sample.append(s[i] + active[check][i]) gcol = math.floor(sample[0] / w) grow = math.floor(sample[1] / w) ggrid = gcol + grow * cols if gcol > -1 and grow > -1 and gcol < cols and grow < rows: ok = True #check distance between selected point and points in the around grids nums = [-1, 0, 1] num1s = [-1, 0, 1] for num in nums: for num1 in num1s: if 0 <= gcol + num1 < cols and 0 <= grow + num < rows: index = (gcol + num1) + (grow + num) * cols if grid[index] is None: pass else: d = _distance2d.dist(grid[index][0], grid[index][1], sample[0], sample[1]) if d < r: ok = None if ok is True: found = True grid[gcol + grow * cols] = sample active.append(sample) break if found is None: del active[check:(check + 1)] for i in range(len(grid)): if grid[i] is None: pass else: if (grid[i][0] < width - roundRadius[0]) and ( grid[i][0] > roundRadius[0]) and ( grid[i][1] < height - roundRadius[0]) and ( grid[i][1] > roundRadius[0]): Circles.append( _Circle.Circle(grid[i][0], grid[i][1], roundRadius[0], width, height)) occupation_poisson = occupation_poisson + 1 # enlarge the particles _generateParticle.generateCircles_p(ranges[0], (maximums[0] - 2), Circles) print('poisson disk sampling', occupation_poisson)