def run_demo(self):
config = parse_config(os.path.join(gibson2.assets_path, 'example_configs/turtlebot_demo.yaml'))
s = Simulator(mode='gui', image_width=700, image_height=700)
scene = BuildingScene('Rs_interactive', is_interactive=True)
s.import_scene(scene)
turtlebot = Turtlebot(config)
s.import_robot(turtlebot)
for i in range(10000):
turtlebot.apply_action([0.1,0.5])
s.step()
s.disconnect()
def test_turtlebot_position():
s = Simulator(mode='headless')
scene = StadiumScene()
s.import_scene(scene)
turtlebot = Turtlebot(config)
s.import_robot(turtlebot)
turtlebot.set_position([0, 0, 5])
nbody = p.getNumBodies()
pos = turtlebot.get_position()
s.disconnect()
assert nbody == 5
assert np.allclose(pos, np.array([0, 0, 5]))
def test_import_box():
s = Simulator(mode='headless')
scene = StadiumScene()
s.import_scene(scene)
print(s.objects)
# wall = [pos, dim]
wall = [[[0, 7, 1.01], [10, 0.2, 1]], [[0, -7, 1.01], [6.89, 0.1, 1]],
[[7, -1.5, 1.01], [0.1, 5.5, 1]], [[-7, -1, 1.01], [0.1, 6, 1]],
[[-8.55, 5, 1.01], [1.44, 0.1, 1]], [[8.55, 4, 1.01], [1.44, 0.1, 1]]]
obstacles = [[[-0.5, 2, 1.01], [3.5, 0.1, 1]], [[4.5, -1, 1.01], [1.5, 0.1, 1]],
[[-4, -2, 1.01], [0.1, 2, 1]], [[2.5, -4, 1.01], [1.5, 0.1, 1]]]
for i in range(len(wall)):
curr = wall[i]
obj = BoxShape(curr[0], curr[1])
s.import_object(obj)
for i in range(len(obstacles)):
curr = obstacles[i]
obj = BoxShape(curr[0], curr[1])
s.import_object(obj)
config = parse_config(os.path.join(gibson2.root_path, '../test/test.yaml'))
turtlebot1 = Turtlebot(config)
turtlebot2 = Turtlebot(config)
s.import_robot(turtlebot1)
s.import_robot(turtlebot2)
turtlebot1.set_position([6., -6., 0.])
turtlebot2.set_position([-3., 4., 0.])
for i in range(100):
s.step()
s.disconnect()
def load(self):
if self.config['scene'] == 'stadium':
scene = StadiumScene()
elif self.config['scene'] == 'building':
scene = BuildingScene(self.config['model_id'])
self.simulator.import_scene(scene)
if self.config['robot'] == 'Turtlebot':
robot = Turtlebot(self.config)
elif self.config['robot'] == 'Husky':
robot = Husky(self.config)
elif self.config['robot'] == 'Ant':
robot = Ant(self.config)
elif self.config['robot'] == 'Humanoid':
robot = Humanoid(self.config)
elif self.config['robot'] == 'JR2':
robot = JR2(self.config)
elif self.config['robot'] == 'JR2_Kinova':
robot = JR2_Kinova(self.config)
else:
raise Exception('unknown robot type: {}'.format(
self.config['robot']))
self.scene = scene
self.robots = [robot]
for robot in self.robots:
self.simulator.import_robot(robot)
def benchmark(render_to_tensor=False, resolution=512):
config = parse_config('../configs/turtlebot_demo.yaml')
s = Simulator(mode='headless', image_width=resolution, image_height=resolution, render_to_tensor=render_to_tensor)
scene = BuildingScene('Rs',
build_graph=True,
pybullet_load_texture=True)
s.import_scene(scene)
turtlebot = Turtlebot(config)
s.import_robot(turtlebot)
n_frame = 500
start = time.time()
for i in range(n_frame):
turtlebot.apply_action([0.1,0.1])
s.step()
rgb = s.renderer.render_robot_cameras(modes=('rgb'))
physics_render_elapsed = time.time() - start
print("physics simulation + rendering rgb, resolution {}, render_to_tensor {}: {} fps".format(resolution,
render_to_tensor,
n_frame/physics_render_elapsed))
start = time.time()
for i in range(n_frame):
rgb = s.renderer.render_robot_cameras(modes=('rgb'))
render_elapsed = time.time() - start
print("Rendering rgb, resolution {}, render_to_tensor {}: {} fps".format(resolution, render_to_tensor,
n_frame/render_elapsed))
start = time.time()
for i in range(n_frame):
rgb = s.renderer.render_robot_cameras(modes=('3d'))
render_elapsed = time.time() - start
print("Rendering 3d, resolution {}, render_to_tensor {}: {} fps".format(resolution, render_to_tensor,
n_frame / render_elapsed))
start = time.time()
for i in range(n_frame):
rgb = s.renderer.render_robot_cameras(modes=('normal'))
render_elapsed = time.time() - start
print("Rendering normal, resolution {}, render_to_tensor {}: {} fps".format(resolution, render_to_tensor,
n_frame / render_elapsed))
s.disconnect()
def test_turtlebot():
s = Simulator(mode='headless')
scene = StadiumScene()
s.import_scene(scene)
turtlebot = Turtlebot(config)
s.import_robot(turtlebot)
nbody = p.getNumBodies()
s.disconnect()
assert nbody == 5
def load(self):
"""
Load the scene and robot
"""
if self.config['scene'] == 'empty':
scene = EmptyScene()
elif self.config['scene'] == 'stadium':
scene = StadiumScene()
elif self.config['scene'] == 'building':
scene = BuildingScene(
self.config['model_id'],
waypoint_resolution=self.config.get('waypoint_resolution',
0.2),
num_waypoints=self.config.get('num_waypoints', 10),
build_graph=self.config.get('build_graph', False),
trav_map_resolution=self.config.get('trav_map_resolution',
0.1),
trav_map_erosion=self.config.get('trav_map_erosion', 2),
is_interactive=self.config.get('is_interactive', False),
pybullet_load_texture=self.config.get('pybullet_load_texture',
False),
)
self.simulator.import_scene(scene,
load_texture=self.config.get(
'load_texture', True))
if self.config['robot'] == 'Turtlebot':
robot = Turtlebot(self.config)
elif self.config['robot'] == 'Husky':
robot = Husky(self.config)
elif self.config['robot'] == 'Ant':
robot = Ant(self.config)
elif self.config['robot'] == 'Humanoid':
robot = Humanoid(self.config)
elif self.config['robot'] == 'JR2':
robot = JR2(self.config)
elif self.config['robot'] == 'JR2_Kinova':
robot = JR2_Kinova(self.config)
elif self.config['robot'] == 'Freight':
robot = Freight(self.config)
elif self.config['robot'] == 'Fetch':
robot = Fetch(self.config)
elif self.config['robot'] == 'Locobot':
robot = Locobot(self.config)
elif self.config['robot'] == 'DexHandRobot':
robot = DexHandRobot(self.config)
else:
raise Exception('unknown robot type: {}'.format(
self.config['robot']))
self.scene = scene
self.robots = [robot]
for robot in self.robots:
self.simulator.import_robot(robot)
def main():
config = parse_config('../configs/turtlebot_demo.yaml')
s = Simulator(mode='gui', image_width=512, image_height=512)
scene = BuildingScene('Rs', build_graph=True, pybullet_load_texture=True)
s.import_scene(scene)
turtlebot = Turtlebot(config)
s.import_robot(turtlebot)
for _ in range(10):
obj = YCBObject('003_cracker_box')
s.import_object(obj)
obj.set_position_orientation(np.random.uniform(low=0, high=2, size=3),
[0, 0, 0, 1])
for i in range(10000):
with Profiler('Simulator step'):
turtlebot.apply_action([0.1, 0.1])
s.step()
rgb = s.renderer.render_robot_cameras(modes=('rgb'))
s.disconnect()
def show_action_sensor_space():
s = Simulator(mode='headless')
scene = StadiumScene()
s.import_scene(scene)
turtlebot = Turtlebot(config)
s.import_robot(turtlebot)
turtlebot.set_position([0, 1, 0.5])
ant = Ant(config)
s.import_robot(ant)
ant.set_position([0, 2, 0.5])
h = Humanoid(config)
s.import_robot(h)
h.set_position([0, 3, 2])
jr = JR2(config)
s.import_robot(jr)
jr.set_position([0, 4, 0.5])
jr2 = JR2_Kinova(config)
s.import_robot(jr2)
jr2.set_position([0, 5, 0.5])
husky = Husky(config)
s.import_robot(husky)
husky.set_position([0, 6, 0.5])
quad = Quadrotor(config)
s.import_robot(quad)
quad.set_position([0, 7, 0.5])
for robot in s.robots:
print(type(robot), len(robot.ordered_joints), robot.calc_state().shape)
for i in range(100):
s.step()
s.disconnect()
def load(self):
"""
Load the scene and robot
"""
if self.config['scene'] == 'stadium':
scene = StadiumScene()
elif self.config['scene'] == 'building':
scene = BuildingScene(
self.config['model_id'],
build_graph=self.config.get('build_graph', False),
trav_map_erosion=self.config.get('trav_map_erosion', 2),
should_load_replaced_objects=self.config.get(
'should_load_replaced_objects', False))
# scene: class_id = 0
# robot: class_id = 1
# objects: class_id > 1
self.simulator.import_scene(scene,
load_texture=self.config.get(
'load_texture', True),
class_id=0)
if self.config['robot'] == 'Turtlebot':
robot = Turtlebot(self.config)
elif self.config['robot'] == 'Husky':
robot = Husky(self.config)
elif self.config['robot'] == 'Ant':
robot = Ant(self.config)
elif self.config['robot'] == 'Humanoid':
robot = Humanoid(self.config)
elif self.config['robot'] == 'JR2':
robot = JR2(self.config)
elif self.config['robot'] == 'JR2_Kinova':
robot = JR2_Kinova(self.config)
elif self.config['robot'] == 'Freight':
robot = Freight(self.config)
elif self.config['robot'] == 'Fetch':
robot = Fetch(self.config)
else:
raise Exception('unknown robot type: {}'.format(
self.config['robot']))
self.scene = scene
self.robots = [robot]
for robot in self.robots:
self.simulator.import_robot(robot, class_id=1)
def main():
p.connect(p.GUI)
p.setGravity(0, 0, -9.8)
p.setTimeStep(1. / 240.)
floor = os.path.join(pybullet_data.getDataPath(), "mjcf/ground_plane.xml")
p.loadMJCF(floor)
robots = []
config = parse_config('../configs/fetch_p2p_nav.yaml')
fetch = Fetch(config)
robots.append(fetch)
config = parse_config('../configs/jr_p2p_nav.yaml')
jr = JR2_Kinova(config)
robots.append(jr)
config = parse_config('../configs/locobot_p2p_nav.yaml')
locobot = Locobot(config)
robots.append(locobot)
config = parse_config('../configs/turtlebot_p2p_nav.yaml')
turtlebot = Turtlebot(config)
robots.append(turtlebot)
positions = [[0, 0, 0], [1, 0, 0], [0, 1, 0], [1, 1, 0]]
for robot, position in zip(robots, positions):
robot.load()
robot.set_position(position)
robot.robot_specific_reset()
robot.keep_still()
for _ in range(2400): # keep still for 10 seconds
p.stepSimulation()
time.sleep(1. / 240.)
for _ in range(2400): # move with small random actions for 10 seconds
for robot, position in zip(robots, positions):
action = np.random.uniform(-1, 1, robot.action_dim)
robot.apply_action(action)
p.stepSimulation()
time.sleep(1. / 240.0)
p.disconnect()
def __init__(self,
config_file,
model_id=None,
mode='headless',
action_timestep=1 / 10.0,
physics_timestep=1 / 240.0,
device_idx=0,
render_to_tensor=False,
automatic_reset=False,
collision_reward_weight=0.0,
track='static'):
super(NavigateRandomEnvSim2Real,
self).__init__(config_file,
model_id=model_id,
mode=mode,
action_timestep=action_timestep,
physics_timestep=physics_timestep,
automatic_reset=automatic_reset,
random_height=False,
device_idx=device_idx,
render_to_tensor=render_to_tensor)
self.collision_reward_weight = collision_reward_weight
assert track in ['static', 'interactive', 'dynamic'], 'unknown track'
self.track = track
if self.track == 'interactive':
self.interactive_objects_num_dups = 2
self.interactive_objects = self.load_interactive_objects()
# does not penalize collision with these interactive objects
self.collision_ignore_body_b_ids |= set(
[obj.body_id for obj in self.interactive_objects])
elif self.track == 'dynamic':
self.num_dynamic_objects = 1
self.dynamic_objects = []
self.dynamic_objects_last_actions = []
for _ in range(self.num_dynamic_objects):
robot = Turtlebot(self.config)
self.simulator.import_robot(robot)
self.dynamic_objects.append(robot)
self.dynamic_objects_last_actions.append(
robot.action_space.sample())
# dynamic objects will repeat their actions for 10 action timesteps
self.dynamic_objects_action_repeat = 10
def rollout(traj, headless=False):
SCENE, traj_id, instr_id, instr, starting_coords = traj
# instr = "Keep going and don't stop"
# starting_coords = [0, 0, 0]
seq = tok.encode_sentence(instr)
tokens = tok.split_sentence(instr)
seq_lengths = [np.argmax(seq == padding_idx, axis=0)]
seq = torch.from_numpy(np.expand_dims(seq, 0)).cuda()
# seq_lengths[seq_lengths == 0] = seq.shape[1] # Full length
ctx, h_t, c_t, ctx_mask = encoder(seq, seq_lengths)
question = h_t
pre_feat = torch.zeros(batch_size, opts.img_feat_input_dim).cuda()
pre_ctx_attend = torch.zeros(batch_size, opts.rnn_hidden_size).cuda()
# Gibson stuff
# 72 fov for 600, 60 for 480
# mode = gui for debug, headless for run
s = Simulator(mode='gui', resolution=640, fov=75, panorama=True)
scene = BuildingScene(SCENE)
# scene = StadiumScene()
ids = s.import_scene(scene)
robot = Turtlebot(config)
ped_id = s.import_robot(robot)
heading_feat_tensor = torch.Tensor(heading_elevation_feat()).view([im_per_ob, 128]).cuda()
s.step()
robot.set_position(starting_coords)
def apply_action(bot: robot, action_idx: int, depth_ok: list, headless=False) -> bool:
print(action_idx)
# action_idx is expected to be 0-13, TODO: make nicer...
if action_idx == 0 or action_idx > 12 or not depth_ok[action_idx - 1]:
print("STOP")
return True
action_idx -= 1
#if action_idx < 3 or (action_idx < 12 and action_idx > 9):
bot.turn_right(0.5235988 * action_idx)
s.step()
if(not headless):
time.sleep(0.2)
bot.move_forward(0.5)
return False
# else:
# if action_idx < 7:
# bot.turn_left(1.57)
# else:
# bot.turn_right(1.57)
bot_is_running = True
while bot_is_running:
s.step()
gib_out = s.renderer.render_robot_cameras(modes=('rgb', '3d'))
rgb = gib_out[::2]
depth = np.array(gib_out[1::2])
processed_rgb = list(map(transform_img, rgb))
batch_obs = np.concatenate(processed_rgb)
imgnet_input = torch.Tensor(batch_obs).cuda()
imgnet_output = torch.zeros([im_per_ob, 2048]).cuda()
# depth processing and filtering
# depth: [36, ]
depth *= depth
depth = depth[:, :, :, :3].sum(axis=3)
depth = np.sqrt(depth)
# filter out 0 distances that are presumably from infinity dist
depth[depth < 0.0001] = 10
# TODO: generalize to non-horizontal moves
depth_ok = depth[12:24, 200:440, 160:480].min(axis=2).min(axis=1)
fig=plt.figure(figsize=(8, 2))
for n, i in enumerate([0, 3, 6, 9]):
fig.add_subplot(1, 4, n + 1)
plt.imshow(depth[12 + i])
plt.show()
# depth_ok *= depth_ok > 1
print(depth_ok)
depth_ok = depth_ok > 0.8
print(depth_ok)
# Each observation has 36 inputs
# We pass rgb images through frozen embedder
for i in range(im_per_ob // B_S):
def hook_fn(m, last_input, o):
imgnet_output[i*B_S:(i+1)*B_S, :] = \
o.detach().squeeze(2).squeeze(2)
imgnet_input[B_S * i : B_S * (i + 1)]
# imgnet_output[B_S * i : B_S * (i + 1)] = resnet(minibatch).detach()
imgnet_output = torch.cat([imgnet_output, heading_feat_tensor], 1)
pano_img_feat = imgnet_output.view([1, im_per_ob, 2176])
navigable_feat = torch.zeros([1, 16, 2176]).cuda()
navigable_feat[0, 1:13] = imgnet_output[12:24] * torch.Tensor(depth_ok).cuda().view(12, 1)
# TODO: make nicer as stated above
navigable_index = [list(map(int, depth_ok))]
print(navigable_index)
# NB: depth_ok replaces navigable_index
h_t, c_t, pre_ctx_attend, img_attn, ctx_attn, logit, value, navigable_mask = model(
pano_img_feat, navigable_feat, pre_feat, question, h_t, c_t, ctx,
pre_ctx_attend, navigable_index, ctx_mask)
print("ATTN")
print(ctx_attn[0])
print(img_attn[0])
plt.bar(range(len(tokens)), ctx_attn.detach().cpu()[0][:len(tokens)])
plt.xticks(range(len(tokens)), tokens)
plt.show()
plt.bar(range(16), img_attn.detach().cpu()[0])
plt.show()
print("NMASK")
print(navigable_mask)
logit.data.masked_fill_((navigable_mask == 0).data, -float('inf'))
m = torch.Tensor([[False] + list(map(lambda b: not b, navigable_index[0])) + [False, False, False]], dtype=bool).cuda()
logit.data.masked_fill_(m, -float('inf'))
action = _select_action(logit, [False])
ended = apply_action(robot, action[0], depth_ok)
bot_is_running = not ended or not headless
if not headless:
time.sleep(.3)
import yaml
from gibson2.core.physics.robot_locomotors import Turtlebot
from gibson2.core.simulator import Simulator
from gibson2.core.physics.scene import BuildingScene, StadiumScene
from gibson2.utils.utils import parse_config
import pytest
import pybullet as p
import numpy as np
from gibson2.core.render.profiler import Profiler
config = parse_config('../configs/turtlebot_p2p_nav.yaml')
s = Simulator(mode='gui', resolution=512, render_to_tensor=False)
scene = BuildingScene('Bolton')
s.import_scene(scene)
turtlebot = Turtlebot(config)
s.import_robot(turtlebot)
p.resetBasePositionAndOrientation(scene.ground_plane_mjcf[0],
posObj=[0, 0, -10],
ornObj=[0, 0, 0, 1])
for i in range(2000):
with Profiler('simulator step'):
turtlebot.apply_action([0.1, 0.1])
s.step()
rgb = s.renderer.render_robot_cameras(modes=('rgb'))
s.disconnect()
def test_import_building_viewing():
s = Simulator(mode='headless')
scene = BuildingScene('Ohoopee')
s.import_scene(scene)
assert s.objects == list(range(2))
turtlebot1 = Turtlebot(config)
turtlebot2 = Turtlebot(config)
turtlebot3 = Turtlebot(config)
s.import_robot(turtlebot1)
s.import_robot(turtlebot2)
s.import_robot(turtlebot3)
turtlebot1.set_position([0.5, 0, 0.5])
turtlebot2.set_position([0, 0, 0.5])
turtlebot3.set_position([-0.5, 0, 0.5])
for i in range(10):
s.step()
#turtlebot1.apply_action(np.random.randint(4))
#turtlebot2.apply_action(np.random.randint(4))
#turtlebot3.apply_action(np.random.randint(4))
s.disconnect()
def test_multiagent():
s = Simulator(mode='headless')
scene = StadiumScene()
s.import_scene(scene)
turtlebot1 = Turtlebot(config)
turtlebot2 = Turtlebot(config)
turtlebot3 = Turtlebot(config)
s.import_robot(turtlebot1)
s.import_robot(turtlebot2)
s.import_robot(turtlebot3)
turtlebot1.set_position([1, 0, 0.5])
turtlebot2.set_position([0, 0, 0.5])
turtlebot3.set_position([-1, 0, 0.5])
nbody = p.getNumBodies()
for i in range(100):
#turtlebot1.apply_action(1)
#turtlebot2.apply_action(1)
#turtlebot3.apply_action(1)
s.step()
s.disconnect()
assert nbody == 7