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eval_real.py
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eval_real.py
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"""
Usage:
(umi): python scripts_real/eval_real_umi.py -i data/outputs/2023.10.26/02.25.30_train_diffusion_unet_timm_umi/checkpoints/latest.ckpt -o data_local/cup_test_data
================ Human in control ==============
Robot movement:
Move your SpaceMouse to move the robot EEF (locked in xy plane).
Press SpaceMouse right button to unlock z axis.
Press SpaceMouse left button to enable rotation axes.
Recording control:
Click the opencv window (make sure it's in focus).
Press "C" to start evaluation (hand control over to policy).
Press "Q" to exit program.
================ Policy in control ==============
Make sure you can hit the robot hardware emergency-stop button quickly!
Recording control:
Press "S" to stop evaluation and gain control back.
"""
# %%
import os
import pathlib
import time
from multiprocessing.managers import SharedMemoryManager
import av
import click
import cv2
import yaml
import dill
import hydra
import numpy as np
import scipy.spatial.transform as st
import torch
from omegaconf import OmegaConf
import json
from diffusion_policy.common.replay_buffer import ReplayBuffer
from diffusion_policy.common.cv2_util import (
get_image_transform
)
from umi.common.cv_util import (
parse_fisheye_intrinsics,
FisheyeRectConverter
)
from diffusion_policy.common.pytorch_util import dict_apply
from diffusion_policy.workspace.base_workspace import BaseWorkspace
from umi.common.precise_sleep import precise_wait
from umi.real_world.bimanual_umi_env import BimanualUmiEnv
from umi.real_world.keystroke_counter import (
KeystrokeCounter, Key, KeyCode
)
from umi.real_world.real_inference_util import (get_real_obs_dict,
get_real_obs_resolution,
get_real_umi_obs_dict,
get_real_umi_action)
from umi.real_world.spacemouse_shared_memory import Spacemouse
from umi.common.pose_util import pose_to_mat, mat_to_pose
OmegaConf.register_new_resolver("eval", eval, replace=True)
def solve_table_collision(ee_pose, gripper_width, height_threshold):
finger_thickness = 25.5 / 1000
keypoints = list()
for dx in [-1, 1]:
for dy in [-1, 1]:
keypoints.append((dx * gripper_width / 2, dy * finger_thickness / 2, 0))
keypoints = np.asarray(keypoints)
rot_mat = st.Rotation.from_rotvec(ee_pose[3:6]).as_matrix()
transformed_keypoints = np.transpose(rot_mat @ np.transpose(keypoints)) + ee_pose[:3]
delta = max(height_threshold - np.min(transformed_keypoints[:, 2]), 0)
ee_pose[2] += delta
def solve_sphere_collision(ee_poses, robots_config):
num_robot = len(robots_config)
this_that_mat = np.identity(4)
this_that_mat[:3, 3] = np.array([0, 0.89, 0]) # TODO: very hacky now!!!!
for this_robot_idx in range(num_robot):
for that_robot_idx in range(this_robot_idx + 1, num_robot):
this_ee_mat = pose_to_mat(ee_poses[this_robot_idx][:6])
this_sphere_mat_local = np.identity(4)
this_sphere_mat_local[:3, 3] = np.asarray(robots_config[this_robot_idx]['sphere_center'])
this_sphere_mat_global = this_ee_mat @ this_sphere_mat_local
this_sphere_center = this_sphere_mat_global[:3, 3]
that_ee_mat = pose_to_mat(ee_poses[that_robot_idx][:6])
that_sphere_mat_local = np.identity(4)
that_sphere_mat_local[:3, 3] = np.asarray(robots_config[that_robot_idx]['sphere_center'])
that_sphere_mat_global = this_that_mat @ that_ee_mat @ that_sphere_mat_local
that_sphere_center = that_sphere_mat_global[:3, 3]
distance = np.linalg.norm(that_sphere_center - this_sphere_center)
threshold = robots_config[this_robot_idx]['sphere_radius'] + robots_config[that_robot_idx]['sphere_radius']
# print(that_sphere_center, this_sphere_center)
if distance < threshold:
print('avoid collision between two arms')
half_delta = (threshold - distance) / 2
normal = (that_sphere_center - this_sphere_center) / distance
this_sphere_mat_global[:3, 3] -= half_delta * normal
that_sphere_mat_global[:3, 3] += half_delta * normal
ee_poses[this_robot_idx][:6] = mat_to_pose(this_sphere_mat_global @ np.linalg.inv(this_sphere_mat_local))
ee_poses[that_robot_idx][:6] = mat_to_pose(np.linalg.inv(this_that_mat) @ that_sphere_mat_global @ np.linalg.inv(that_sphere_mat_local))
@click.command()
@click.option('--input', '-i', required=True, help='Path to checkpoint')
@click.option('--output', '-o', required=True, help='Directory to save recording')
@click.option('--robot_config', '-rc', required=True, help='Path to robot_config yaml file')
@click.option('--match_dataset', '-m', default=None, help='Dataset used to overlay and adjust initial condition')
@click.option('--match_episode', '-me', default=None, type=int, help='Match specific episode from the match dataset')
@click.option('--match_camera', '-mc', default=0, type=int)
@click.option('--camera_reorder', '-cr', default='0')
@click.option('--vis_camera_idx', default=0, type=int, help="Which RealSense camera to visualize.")
@click.option('--init_joints', '-j', is_flag=True, default=False, help="Whether to initialize robot joint configuration in the beginning.")
@click.option('--steps_per_inference', '-si', default=6, type=int, help="Action horizon for inference.")
@click.option('--max_duration', '-md', default=2000000, help='Max duration for each epoch in seconds.')
@click.option('--frequency', '-f', default=10, type=float, help="Control frequency in Hz.")
@click.option('--command_latency', '-cl', default=0.01, type=float, help="Latency between receiving SapceMouse command to executing on Robot in Sec.")
@click.option('-nm', '--no_mirror', is_flag=True, default=False)
@click.option('-sf', '--sim_fov', type=float, default=None)
@click.option('-ci', '--camera_intrinsics', type=str, default=None)
@click.option('--mirror_swap', is_flag=True, default=False)
def main(input, output, robot_config,
match_dataset, match_episode, match_camera,
camera_reorder,
vis_camera_idx, init_joints,
steps_per_inference, max_duration,
frequency, command_latency,
no_mirror, sim_fov, camera_intrinsics, mirror_swap):
max_gripper_width = 0.09
gripper_speed = 0.2
# load robot config file
robot_config_data = yaml.safe_load(open(os.path.expanduser(robot_config), 'r'))
# load left-right robot relative transform
tx_left_right = np.array(robot_config_data['tx_left_right'])
tx_robot1_robot0 = tx_left_right
robots_config = robot_config_data['robots']
grippers_config = robot_config_data['grippers']
# load checkpoint
ckpt_path = input
if not ckpt_path.endswith('.ckpt'):
ckpt_path = os.path.join(ckpt_path, 'checkpoints', 'latest.ckpt')
payload = torch.load(open(ckpt_path, 'rb'), map_location='cpu', pickle_module=dill)
cfg = payload['cfg']
print("model_name:", cfg.policy.obs_encoder.model_name)
print("dataset_path:", cfg.task.dataset.dataset_path)
# setup experiment
dt = 1/frequency
obs_res = get_real_obs_resolution(cfg.task.shape_meta)
# load fisheye converter
fisheye_converter = None
if sim_fov is not None:
assert camera_intrinsics is not None
opencv_intr_dict = parse_fisheye_intrinsics(
json.load(open(camera_intrinsics, 'r')))
fisheye_converter = FisheyeRectConverter(
**opencv_intr_dict,
out_size=obs_res,
out_fov=sim_fov
)
print("steps_per_inference:", steps_per_inference)
with SharedMemoryManager() as shm_manager:
with Spacemouse(shm_manager=shm_manager) as sm, \
KeystrokeCounter() as key_counter, \
BimanualUmiEnv(
output_dir=output,
robots_config=robots_config,
grippers_config=grippers_config,
frequency=frequency,
obs_image_resolution=obs_res,
obs_float32=True,
camera_reorder=[int(x) for x in camera_reorder],
init_joints=init_joints,
enable_multi_cam_vis=True,
# latency
camera_obs_latency=0.17,
# obs
camera_obs_horizon=cfg.task.shape_meta.obs.camera0_rgb.horizon,
robot_obs_horizon=cfg.task.shape_meta.obs.robot0_eef_pos.horizon,
gripper_obs_horizon=cfg.task.shape_meta.obs.robot0_gripper_width.horizon,
no_mirror=no_mirror,
fisheye_converter=fisheye_converter,
mirror_swap=mirror_swap,
# action
max_pos_speed=2.0,
max_rot_speed=6.0,
shm_manager=shm_manager) as env:
cv2.setNumThreads(2)
print("Waiting for camera")
time.sleep(1.0)
# load match_dataset
episode_first_frame_map = dict()
match_replay_buffer = None
if match_dataset is not None:
match_dir = pathlib.Path(match_dataset)
match_zarr_path = match_dir.joinpath('replay_buffer.zarr')
match_replay_buffer = ReplayBuffer.create_from_path(str(match_zarr_path), mode='r')
match_video_dir = match_dir.joinpath('videos')
for vid_dir in match_video_dir.glob("*/"):
episode_idx = int(vid_dir.stem)
match_video_path = vid_dir.joinpath(f'{match_camera}.mp4')
if match_video_path.exists():
img = None
with av.open(str(match_video_path)) as container:
stream = container.streams.video[0]
for frame in container.decode(stream):
img = frame.to_ndarray(format='rgb24')
break
episode_first_frame_map[episode_idx] = img
print(f"Loaded initial frame for {len(episode_first_frame_map)} episodes")
# creating model
# have to be done after fork to prevent
# duplicating CUDA context with ffmpeg nvenc
cls = hydra.utils.get_class(cfg._target_)
workspace = cls(cfg)
workspace: BaseWorkspace
workspace.load_payload(payload, exclude_keys=None, include_keys=None)
policy = workspace.model
if cfg.training.use_ema:
policy = workspace.ema_model
policy.num_inference_steps = 16 # DDIM inference iterations
obs_pose_rep = cfg.task.pose_repr.obs_pose_repr
action_pose_repr = cfg.task.pose_repr.action_pose_repr
print('obs_pose_rep', obs_pose_rep)
print('action_pose_repr', action_pose_repr)
device = torch.device('cuda')
policy.eval().to(device)
print("Warming up policy inference")
obs = env.get_obs()
episode_start_pose = list()
for robot_id in range(len(robots_config)):
pose = np.concatenate([
obs[f'robot{robot_id}_eef_pos'],
obs[f'robot{robot_id}_eef_rot_axis_angle']
], axis=-1)[-1]
episode_start_pose.append(pose)
with torch.no_grad():
policy.reset()
obs_dict_np = get_real_umi_obs_dict(
env_obs=obs, shape_meta=cfg.task.shape_meta,
obs_pose_repr=obs_pose_rep,
tx_robot1_robot0=tx_robot1_robot0,
episode_start_pose=episode_start_pose)
obs_dict = dict_apply(obs_dict_np,
lambda x: torch.from_numpy(x).unsqueeze(0).to(device))
result = policy.predict_action(obs_dict)
action = result['action_pred'][0].detach().to('cpu').numpy()
assert action.shape[-1] == 10 * len(robots_config)
action = get_real_umi_action(action, obs, action_pose_repr)
assert action.shape[-1] == 7 * len(robots_config)
del result
print('Ready!')
while True:
# ========= human control loop ==========
print("Human in control!")
robot_states = env.get_robot_state()
target_pose = np.stack([rs['TargetTCPPose'] for rs in robot_states])
gripper_states = env.get_gripper_state()
gripper_target_pos = np.asarray([gs['gripper_position'] for gs in gripper_states])
control_robot_idx_list = [0]
t_start = time.monotonic()
iter_idx = 0
while True:
# calculate timing
t_cycle_end = t_start + (iter_idx + 1) * dt
t_sample = t_cycle_end - command_latency
t_command_target = t_cycle_end + dt
# pump obs
obs = env.get_obs()
# visualize
episode_id = env.replay_buffer.n_episodes
vis_img = obs[f'camera{match_camera}_rgb'][-1]
match_episode_id = episode_id
if match_episode is not None:
match_episode_id = match_episode
if match_episode_id in episode_first_frame_map:
match_img = episode_first_frame_map[match_episode_id]
ih, iw, _ = match_img.shape
oh, ow, _ = vis_img.shape
tf = get_image_transform(
input_res=(iw, ih),
output_res=(ow, oh),
bgr_to_rgb=False)
match_img = tf(match_img).astype(np.float32) / 255
vis_img = (vis_img + match_img) / 2
obs_left_img = obs['camera0_rgb'][-1]
obs_right_img = obs['camera0_rgb'][-1]
vis_img = np.concatenate([obs_left_img, obs_right_img, vis_img], axis=1)
text = f'Episode: {episode_id}'
cv2.putText(
vis_img,
text,
(10,20),
fontFace=cv2.FONT_HERSHEY_SIMPLEX,
fontScale=0.5,
lineType=cv2.LINE_AA,
thickness=3,
color=(0,0,0)
)
cv2.putText(
vis_img,
text,
(10,20),
fontFace=cv2.FONT_HERSHEY_SIMPLEX,
fontScale=0.5,
thickness=1,
color=(255,255,255)
)
cv2.imshow('default', vis_img[...,::-1])
_ = cv2.pollKey()
press_events = key_counter.get_press_events()
start_policy = False
for key_stroke in press_events:
if key_stroke == KeyCode(char='q'):
# Exit program
env.end_episode()
exit(0)
elif key_stroke == KeyCode(char='c'):
# Exit human control loop
# hand control over to the policy
start_policy = True
elif key_stroke == KeyCode(char='e'):
# Next episode
if match_episode is not None:
match_episode = min(match_episode + 1, env.replay_buffer.n_episodes-1)
elif key_stroke == KeyCode(char='w'):
# Prev episode
if match_episode is not None:
match_episode = max(match_episode - 1, 0)
elif key_stroke == KeyCode(char='m'):
# move the robot
duration = 3.0
ep = match_replay_buffer.get_episode(match_episode_id)
for robot_idx in range(1):
pos = ep[f'robot{robot_idx}_eef_pos'][0]
rot = ep[f'robot{robot_idx}_eef_rot_axis_angle'][0]
grip = ep[f'robot{robot_idx}_gripper_width'][0]
pose = np.concatenate([pos, rot])
env.robots[robot_idx].servoL(pose, duration=duration)
env.grippers[robot_idx].schedule_waypoint(grip, target_time=time.time() + duration)
target_pose[robot_idx] = pose
gripper_target_pos[robot_idx] = grip
time.sleep(duration)
elif key_stroke == Key.backspace:
if click.confirm('Are you sure to drop an episode?'):
env.drop_episode()
key_counter.clear()
elif key_stroke == KeyCode(char='a'):
control_robot_idx_list = list(range(target_pose.shape[0]))
elif key_stroke == KeyCode(char='1'):
control_robot_idx_list = [0]
elif key_stroke == KeyCode(char='2'):
control_robot_idx_list = [1]
if start_policy:
break
precise_wait(t_sample)
# get teleop command
sm_state = sm.get_motion_state_transformed()
# print(sm_state)
dpos = sm_state[:3] * (0.5 / frequency)
drot_xyz = sm_state[3:] * (1.5 / frequency)
drot = st.Rotation.from_euler('xyz', drot_xyz)
for robot_idx in control_robot_idx_list:
target_pose[robot_idx, :3] += dpos
target_pose[robot_idx, 3:] = (drot * st.Rotation.from_rotvec(
target_pose[robot_idx, 3:])).as_rotvec()
dpos = 0
if sm.is_button_pressed(0):
# close gripper
dpos = -gripper_speed / frequency
if sm.is_button_pressed(1):
dpos = gripper_speed / frequency
for robot_idx in control_robot_idx_list:
gripper_target_pos[robot_idx] = np.clip(gripper_target_pos[robot_idx] + dpos, 0, max_gripper_width)
# solve collision with table
for robot_idx in control_robot_idx_list:
solve_table_collision(
ee_pose=target_pose[robot_idx],
gripper_width=gripper_target_pos[robot_idx],
height_threshold=robots_config[robot_idx]['height_threshold'])
# solve collison between two robots
solve_sphere_collision(
ee_poses=target_pose,
robots_config=robots_config
)
action = np.zeros((7 * target_pose.shape[0],))
for robot_idx in range(target_pose.shape[0]):
action[7 * robot_idx + 0: 7 * robot_idx + 6] = target_pose[robot_idx]
action[7 * robot_idx + 6] = gripper_target_pos[robot_idx]
# execute teleop command
env.exec_actions(
actions=[action],
timestamps=[t_command_target-time.monotonic()+time.time()],
compensate_latency=False)
precise_wait(t_cycle_end)
iter_idx += 1
# ========== policy control loop ==============
try:
# start episode
policy.reset()
start_delay = 1.0
eval_t_start = time.time() + start_delay
t_start = time.monotonic() + start_delay
env.start_episode(eval_t_start)
# get current pose
obs = env.get_obs()
episode_start_pose = list()
for robot_id in range(len(robots_config)):
pose = np.concatenate([
obs[f'robot{robot_id}_eef_pos'],
obs[f'robot{robot_id}_eef_rot_axis_angle']
], axis=-1)[-1]
episode_start_pose.append(pose)
# wait for 1/30 sec to get the closest frame actually
# reduces overall latency
frame_latency = 1/60
precise_wait(eval_t_start - frame_latency, time_func=time.time)
print("Started!")
iter_idx = 0
perv_target_pose = None
while True:
# calculate timing
t_cycle_end = t_start + (iter_idx + steps_per_inference) * dt
# get obs
obs = env.get_obs()
obs_timestamps = obs['timestamp']
print(f'Obs latency {time.time() - obs_timestamps[-1]}')
# run inference
with torch.no_grad():
s = time.time()
obs_dict_np = get_real_umi_obs_dict(
env_obs=obs, shape_meta=cfg.task.shape_meta,
obs_pose_repr=obs_pose_rep,
tx_robot1_robot0=tx_robot1_robot0,
episode_start_pose=episode_start_pose)
obs_dict = dict_apply(obs_dict_np,
lambda x: torch.from_numpy(x).unsqueeze(0).to(device))
result = policy.predict_action(obs_dict)
raw_action = result['action_pred'][0].detach().to('cpu').numpy()
action = get_real_umi_action(raw_action, obs, action_pose_repr)
print('Inference latency:', time.time() - s)
# convert policy action to env actions
this_target_poses = action
assert this_target_poses.shape[1] == len(robots_config) * 7
for target_pose in this_target_poses:
for robot_idx in range(len(robots_config)):
solve_table_collision(
ee_pose=target_pose[robot_idx * 7: robot_idx * 7 + 6],
gripper_width=target_pose[robot_idx * 7 + 6],
height_threshold=robots_config[robot_idx]['height_threshold']
)
# solve collison between two robots
solve_sphere_collision(
ee_poses=target_pose.reshape([len(robots_config), -1]),
robots_config=robots_config
)
# deal with timing
# the same step actions are always the target for
action_timestamps = (np.arange(len(action), dtype=np.float64)
) * dt + obs_timestamps[-1]
print(dt)
action_exec_latency = 0.01
curr_time = time.time()
is_new = action_timestamps > (curr_time + action_exec_latency)
if np.sum(is_new) == 0:
# exceeded time budget, still do something
this_target_poses = this_target_poses[[-1]]
# schedule on next available step
next_step_idx = int(np.ceil((curr_time - eval_t_start) / dt))
action_timestamp = eval_t_start + (next_step_idx) * dt
print('Over budget', action_timestamp - curr_time)
action_timestamps = np.array([action_timestamp])
else:
this_target_poses = this_target_poses[is_new]
action_timestamps = action_timestamps[is_new]
# execute actions
env.exec_actions(
actions=this_target_poses,
timestamps=action_timestamps,
compensate_latency=True
)
print(f"Submitted {len(this_target_poses)} steps of actions.")
# visualize
episode_id = env.replay_buffer.n_episodes
obs_left_img = obs['camera0_rgb'][-1]
obs_right_img = obs['camera0_rgb'][-1]
vis_img = np.concatenate([obs_left_img, obs_right_img], axis=1)
text = 'Episode: {}, Time: {:.1f}'.format(
episode_id, time.monotonic() - t_start
)
cv2.putText(
vis_img,
text,
(10,20),
fontFace=cv2.FONT_HERSHEY_SIMPLEX,
fontScale=0.5,
thickness=1,
color=(255,255,255)
)
cv2.imshow('default', vis_img[...,::-1])
_ = cv2.pollKey()
press_events = key_counter.get_press_events()
stop_episode = False
for key_stroke in press_events:
if key_stroke == KeyCode(char='s'):
# Stop episode
# Hand control back to human
print('Stopped.')
stop_episode = True
t_since_start = time.time() - eval_t_start
if t_since_start > max_duration:
print("Max Duration reached.")
stop_episode = True
if stop_episode:
env.end_episode()
break
# wait for execution
precise_wait(t_cycle_end - frame_latency)
iter_idx += steps_per_inference
except KeyboardInterrupt:
print("Interrupted!")
# stop robot.
env.end_episode()
print("Stopped.")
# %%
if __name__ == '__main__':
main()