def check_problem():
movie = Movie()
f = 1
def aff(x, y):
return P(x, y)
stone = Polygon([
aff(0.09897029702970297, 0.27443716679360247),
aff(0.11047372429550648, 0.2750952018278751),
aff(0.10981568926123382, 0.2865955826351866),
aff(0.09831530845392232, 0.285940594059406)
])
center = aff(0.08183068719268435, 0.28569424117242365)
radius = 0.0164719687883 * f
step = 0.000823598439415 * f
stones = PolygonSet()
stones.add(stone)
allowable = stones.open_direction_for_circle(center, radius, step)
l = [(stone, "red"), (Circle(center, radius), "green"),
(allowable, "black")]
movie.background(l)
movie.just_draw()
exit(0)
def check_open_directions_for_circle_avoiding_segment2():
radius = 0.25
step = 0.15
center = P(0.5, 0.5)
circ = Circle(center, radius)
p = P(0.12661771955, 0.59179988647)
q = P(0.22661771955, 0.79179988647)
seg = S(p, q)
directions = GRegion.open_directions_for_circle_avoiding_segment(
circ, seg, step)
shift = seg.dir.perp().resize(radius)
box = Polygon([p - shift, p + shift, q + shift, q - shift])
l = [
(Circle(center, step), "lightgreen"),
(box, "lightgrey"),
# (Circle(p, radius), "lightgrey"),
# (Circle(q, radius), "lightgrey"),
(directions, "black"),
(seg, "red"),
(Circle(center, 0.004), "red")
]
movie = Movie()
movie.background(l)
movie.just_draw()
exit(0)
def check_open_directions_for_circle_avoiding_segment3():
placements = []
radius = 0.25
step = 0.15
center = P(0.5, 0.5)
circ = Circle(center, radius)
for i in range(1000):
p = P.polar(0.37, i / 1000 * 2 * np.pi) + P(0.43, 0.38)
q = p + P(0.1, 0.2)
seg = S(p, q)
directions = GRegion.open_directions_for_circle_avoiding_segment(
circ, seg, step)
if len(directions.regions) > 1:
shift = seg.dir.perp().resize(radius)
print(seg.p.x, seg.p.y, seg.q.x, seg.q.y)
box = Polygon([p - shift, p + shift, q + shift, q - shift])
l = [(Circle(center, step), "lightgreen"), (box, "lightgrey"),
(Circle(p, radius), "lightgrey"),
(Circle(q, radius), "lightgrey"), (directions, "black"),
(seg, "red"), (Circle(center, 0.004), "red")]
placements.append(l)
movie = Movie()
movie.background(l)
movie.just_draw()
break
exit(0)
def draw_gap(file_name):
cfg = configuration.Configuration(file_name=file_name)
gap, a, b = max_backwards(cfg.path.points)
path = cfg.path.points
movie = Movie()
movie.background([(cfg, "black")])
movie.background([(circle.Circle(path[a], cfg.cheerio_radius / 2), "green")])
movie.background([(circle.Circle(path[b], cfg.cheerio_radius / 2), "green")])
movie.just_draw()
exit(0)
def run_movie(cfg: configuration.Configuration, runner: run.Runner, only_plot=False,
only_save=False):
"""Create the video."""
movie = Movie()
movie.background([(cfg, "black")]) # draws the cubes
cheerios, result = run.Run(runner).run() # runs the algorithm/analysis specified by runner
# returns a list of points (class p) specifying the location of the load over time and a
# boolean variable describing whether the run was successful
print(result)
if only_plot or only_save:
movie.background([(MotionPath(cheerios), "green")]) # draws the simulated load path
if only_save:
movie.save_figure(cfg.file_name + "_image")
else:
movie.just_draw() # plotting without saving
else:
# Creating a video of the simulated load moving through the cube maze
to_draw = []
# create list of tuples(Circle,str), one for each frame to be drawn in the animation
for cheerio in cheerios:
to_draw.append([(circle.Circle(cheerio, cfg.cheerio_radius), "green")])
movie.run_animation(to_draw, 0) # drawing the load
def boxes(cfg, box_size_in_cheerio_radii=6, draw=True):
if draw:
movie = Movie()
movie.background([(cfg, "black")])
size = box_size_in_cheerio_radii * cfg.cheerio_radius
index = 0
path = cfg.path.points
result = []
while index < len(path) and path[index].x < 1 - size:
p = path[index]
box = rectangle.Rectangle(p.x, p.y - size / 2, p.x + size, p.y + size / 2)
good = 0
times = 10
for i in range(times):
cfg.start = p
cfg.reset_runseed()
r, sim_res = run.Run(run.SimulationRunner(cfg), containing_box=box).run()
if sim_res:
good += 1
if draw:
if sim_res:
color = "green"
else:
color = "black"
movie.background([(MotionPath(r), color)])
r, ant_res = run.Run(run.AntRunner(cfg, index), containing_box=box).run()
if draw:
if ant_res:
color = "green"
else:
color = "black"
movie.background([(MotionPath(r), "blue")])
box.add_text('{:.0f}%,{:.0f}%'.format(box_density(cfg, box) * 100, good / times * 100))
movie.background([(box, color)])
result.append((box_density(cfg, box), ant_res, good / times))
while index < len(path) and path[index].x < box.qx:
index += 1
if draw:
movie.save_figure(cfg.file_name + "_boxes")
movie.close()
# movie.just_draw()
return result
def remote_sensing1(cfg: configuration.Configuration, draw=False):
if draw:
movie = Movie()
movie.background([(cfg, "black")])
else:
movie = None
path = cfg.path.points
index = 0
last = 0
count = 0
count_good = 0
while index < len(path):
if path[index].x - path[last].x > cfg.cheerio_radius * 6:
res = where_did_it_go(cfg, movie, index)
if isinstance(res, bool):
count += 1
if res:
count_good += 1
last = index
index += 1
if draw:
movie.just_draw()
print(cfg.file_name, count, count_good)
return count, count_good
def read_heat_map(file_name, display=True):
stones, cheerio, nest, path = init_stones(file_name)
movie = Movie()
movie.background([(s, "green") for s in stones])
h = HeatMap()
if not file_name:
file_name = "tmp"
h.read_map("data/" + file_name + "_heatmap.txt")
movie.background(h.to_draw())
movie.background([(path, "red")])
movie.save_figure("data/" + file_name + "_heatmap")
if display:
movie.just_draw()
else:
movie.close()
def draw_distribution(sigma):
direction = P(0.3, 0)
stones = PolygonSet()
stones.add(Polygon.square(P(0.6, 0.6), 0.2, 0.1))
stones.add(Polygon.square(P(0.3, 0.6), 0.2, 0.1))
stones.add(Polygon.square(P(0.7, 0.4), 0.2, 0.1))
cheerio = P(0.5, 0.5)
g = stones.open_direction_for_circle(cheerio, 0, 1)
movie = Movie()
movie.background([(s, "red") for s in stones])
movie.background([(S(cheerio, direction + cheerio), "blue")])
movie.background([(g, "black")])
points = []
for i in range(300):
rand_dir = g.rand_point_normal(direction, sigma)
# rand_dir = direction.rotate(np.random.normal(scale=sigma) * np.pi)
points.append(cheerio + rand_dir)
movie.background([(Circle(p, 0.0015), "blue") for p in points])
movie.just_draw()
exit()
def just_draw_cfg(cfg: configuration.Configuration):
print(cfg)
movie = Movie()
movie.background([(cfg, "black")])
movie.just_draw()
exit(0)
