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g1-moves

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Reinforcement Learning
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motion-capture
humanoid-robot
unitree-g1
bvh
sim-to-real
mujoco
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g1-moves / Motion-Player-ROS /scripts /motion_player.py
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 #!/usr/bin/env python3
"""
Motion player for ROS2.
Supports two modes:
1. Playback mode (default): Plays pre-recorded motion from pickle/BVH files
2. Realtime mode (--realtime): Receives live mocap data via OSC/UDP
Usage:
ros2 run motion_player motion_player --ros-args -p motion_file:=/path/to/motion.pkl
ros2 run motion_player motion_player --realtime --ros-args -p port:=11235
"""
import os
import argparse
import rclpy
from rclpy.node import Node
from sensor_msgs.msg import JointState
from geometry_msgs.msg import TransformStamped
from visualization_msgs.msg import Marker, MarkerArray
from tf2_ros import TransformBroadcaster
import numpy as np
# Joint names in the order stored in the motion data
JOINT_NAMES = [
"left_hip_pitch_joint", "left_hip_roll_joint", "left_hip_yaw_joint",
"left_knee_joint", "left_ankle_pitch_joint", "left_ankle_roll_joint",
"right_hip_pitch_joint", "right_hip_roll_joint", "right_hip_yaw_joint",
"right_knee_joint", "right_ankle_pitch_joint", "right_ankle_roll_joint",
"waist_yaw_joint", "waist_roll_joint", "waist_pitch_joint",
"left_shoulder_pitch_joint", "left_shoulder_roll_joint", "left_shoulder_yaw_joint",
"left_elbow_joint", "left_wrist_roll_joint", "left_wrist_pitch_joint", "left_wrist_yaw_joint",
"right_shoulder_pitch_joint", "right_shoulder_roll_joint", "right_shoulder_yaw_joint",
"right_elbow_joint", "right_wrist_roll_joint", "right_wrist_pitch_joint", "right_wrist_yaw_joint",
]
class MotionPlayerNode(Node):
"""Unified ROS2 node for motion playback and real-time mocap visualization."""
def __init__(self, realtime: bool = False):
super().__init__('motion_player')
self.realtime = realtime
# Common publishers
self.joint_state_pub = self.create_publisher(JointState, 'joint_states', 10)
self.tf_broadcaster = TransformBroadcaster(self)
self.skeleton_marker_pub = self.create_publisher(MarkerArray, 'skeleton_markers', 10)
if self.realtime:
self._init_realtime()
self.timer = self.create_timer(1.0 / 100.0, self._realtime_callback)
else:
self._init_playback()
if hasattr(self, 'fps') and self.fps > 0:
self.timer = self.create_timer(1.0 / self.fps, self._playback_callback)
# -------------------------------------------------------------------------
# Playback mode initialization and callback
# -------------------------------------------------------------------------
def _init_playback(self):
"""Initialize playback mode from pickle/BVH files."""
import pickle
from movin_sdk_python import load_bvh_file
# Declare parameters for playback mode
self.declare_parameter('motion_file', '')
self.declare_parameter('bvh_file', '')
self.declare_parameter('loop', True)
self.declare_parameter('skeleton_offset_x', 1.0)
self.declare_parameter('human_height', 1.75)
motion_file = self.get_parameter('motion_file').get_parameter_value().string_value
bvh_file_param = self.get_parameter('bvh_file').get_parameter_value().string_value
self.loop = self.get_parameter('loop').get_parameter_value().bool_value
self.skeleton_offset_x = self.get_parameter('skeleton_offset_x').get_parameter_value().double_value
human_height = self.get_parameter('human_height').get_parameter_value().double_value
if not motion_file:
self.get_logger().error('No motion_file specified!')
return
# Load motion data
with open(motion_file, 'rb') as f:
self.motion_data = pickle.load(f)
self.fps = self.motion_data['fps']
self.root_pos = self.motion_data['root_pos'] # [n_frames, 3]
self.root_rot = self.motion_data['root_rot'] # [n_frames, 4] xyzw
self.dof_pos = self.motion_data['dof_pos'] # [n_frames, 29]
self.n_frames = len(self.root_pos)
self.current_frame = 0
self.get_logger().info(f'Loaded motion with {self.n_frames} frames at {self.fps} FPS')
# Load BVH data if available
self.bvh_frames = None
self.bvh_bone_names = None
self.bvh_bone_parents = None
# Use explicit bvh_file parameter, or auto-detect from motion_file
if bvh_file_param:
bvh_file = bvh_file_param
else:
bvh_file = motion_file.replace('.pkl', '.bvh')
if os.path.exists(bvh_file):
# load_bvh_file returns (frames, human_height, parents, bones)
self.bvh_frames, _, self.bvh_bone_parents, self.bvh_bone_names = load_bvh_file(
bvh_file, human_height=human_height
)
self.get_logger().info(f'Loaded BVH with {len(self.bvh_frames)} frames, {len(self.bvh_bone_names)} bones')
else:
self.get_logger().warn(f'No BVH file found at {bvh_file}')
def _playback_callback(self):
"""Timer callback for playback mode."""
if self.current_frame >= self.n_frames:
if self.loop:
self.current_frame = 0
else:
self.get_logger().info('Motion playback complete')
self.timer.cancel()
return
now = self.get_clock().now().to_msg()
# Get current frame data
root_pos = self.root_pos[self.current_frame]
root_rot_xyzw = self.root_rot[self.current_frame]
dof_pos = self.dof_pos[self.current_frame]
# Publish robot state (convert xyzw to wxyz for consistency)
root_rot_wxyz = np.array([root_rot_xyzw[3], root_rot_xyzw[0], root_rot_xyzw[1], root_rot_xyzw[2]])
self._publish_robot_state(root_pos, root_rot_wxyz, dof_pos, now)
# Publish BVH markers if available
if self.bvh_frames is not None:
# Use modulo to handle frame count mismatch between BVH and PKL
bvh_frame_idx = self.current_frame % len(self.bvh_frames)
frame_data = self.bvh_frames[bvh_frame_idx]
self._publish_skeleton_markers(frame_data, now, self.bvh_bone_names, self.bvh_bone_parents)
self.current_frame += 1
# -------------------------------------------------------------------------
# Realtime mode initialization and callback
# -------------------------------------------------------------------------
def _init_realtime(self):
"""Initialize realtime mode with mocap receiver."""
from movin_sdk_python import Retargeter, MocapReceiver
# Declare parameters for realtime mode
self.declare_parameter('port', 11235)
self.declare_parameter('robot_type', 'unitree_g1')
self.declare_parameter('human_height', 1.75)
self.declare_parameter('skeleton_offset_x', 1.0)
# Get parameters
port = self.get_parameter('port').get_parameter_value().integer_value
robot_type = self.get_parameter('robot_type').get_parameter_value().string_value
human_height = self.get_parameter('human_height').get_parameter_value().double_value
self.skeleton_offset_x = self.get_parameter('skeleton_offset_x').get_parameter_value().double_value
self.get_logger().info(f'Initializing Retargeter for {robot_type} with human_height={human_height}')
# Initialize retargeter
self.retargeter = Retargeter(
robot_type=robot_type,
human_height=human_height,
verbose=False,
)
self.required_bones = self.retargeter.get_required_bones()
# Initialize mocap receiver
self.receiver = MocapReceiver(port=port)
self.receiver.start()
self.get_logger().info(f'MocapReceiver started on port {port}')
# State tracking
self.waiting_for_data = True
self.warned_missing = 0
self.get_logger().info(f'Waiting for mocap data on port {port}...')
def _realtime_callback(self):
"""Timer callback for realtime mode - poll for mocap frames."""
# Get latest mocap frame
frame = self.receiver.get_latest_frame()
if frame is None:
return
if self.waiting_for_data:
self.waiting_for_data = False
bone_names = [b["bone_name"] for b in frame["bones"]]
self.get_logger().info(f'Receiving mocap data! {len(bone_names)} bones')
bones = frame["bones"]
# Process mocap frame
mocap_data = self.retargeter.process_mocap_frame(bones)
# Check for required bones
missing = sorted(self.required_bones.difference(mocap_data.keys()))
if missing:
if self.warned_missing < 5:
self.warned_missing += 1
self.get_logger().warn(f'Missing {len(missing)} required bones: {missing}')
return
# Filter to only required bones for retargeting
filtered_mocap_data = {k: mocap_data[k] for k in self.required_bones if k in mocap_data}
# Retarget
qpos = self.retargeter.retarget(filtered_mocap_data)
now = self.get_clock().now().to_msg()
# Extract root position and orientation
root_pos = qpos[:3]
root_rot = qpos[3:7] # (w, x, y, z) format from mujoco
dof_pos = qpos[7:]
# Publish robot state
self._publish_robot_state(root_pos, root_rot, dof_pos, now)
# Publish skeleton markers with bone hierarchy from mocap frame
bone_names = [b["bone_name"] for b in bones]
bone_parents = {b["bone_index"]: b["parent_index"] for b in bones}
self._publish_skeleton_markers(mocap_data, now, bone_names, bone_parents)
# -------------------------------------------------------------------------
# Common methods
# -------------------------------------------------------------------------
def _publish_skeleton_markers(self, frame_data: dict, stamp, bone_names, bone_parents):
"""Publish skeleton visualization as MarkerArray.
Args:
frame_data: Dictionary mapping bone_name -> [position, orientation]
Position is [x, y, z], orientation is quaternion
stamp: ROS timestamp
bone_names: List of bone names (ordered by index) or None
bone_parents: Parent indices - either np.array (BVH) or dict {idx: parent_idx} (realtime)
"""
marker_array = MarkerArray()
marker_id = 0
# Build bone positions dict
bone_positions = {}
for bone_name in frame_data.keys():
pos = np.array(frame_data[bone_name][0])
bone_positions[bone_name] = pos
# Create sphere markers for each joint
for bone_name, pos in bone_positions.items():
marker = Marker()
marker.header.stamp = stamp
marker.header.frame_id = 'world'
marker.ns = 'skeleton_joints'
marker.id = marker_id
marker.type = Marker.SPHERE
marker.action = Marker.ADD
marker.pose.position.x = float(pos[0] + self.skeleton_offset_x)
marker.pose.position.y = float(pos[1])
marker.pose.position.z = float(pos[2])
marker.pose.orientation.w = 1.0
marker.scale.x = 0.03
marker.scale.y = 0.03
marker.scale.z = 0.03
marker.color.r = 1.0
marker.color.g = 0.2
marker.color.b = 0.2
marker.color.a = 1.0
marker_array.markers.append(marker)
marker_id += 1
# Create cylinder markers for bones using parent hierarchy
if bone_names is not None and bone_parents is not None:
for joint_idx in range(1, len(bone_names)):
bone_name = bone_names[joint_idx]
# Get parent index (handle both np.array and dict)
if isinstance(bone_parents, dict):
parent_idx = bone_parents.get(joint_idx, -1)
else:
parent_idx = int(bone_parents[joint_idx])
if parent_idx < 0 or parent_idx >= len(bone_names):
continue
parent_name = bone_names[parent_idx]
if bone_name not in bone_positions or parent_name not in bone_positions:
continue
start = bone_positions[parent_name].copy()
end = bone_positions[bone_name].copy()
start[0] += self.skeleton_offset_x
end[0] += self.skeleton_offset_x
self._add_bone_marker(marker_array, marker_id, start, end, stamp)
marker_id += 1
self.skeleton_marker_pub.publish(marker_array)
def _publish_robot_state(self, root_pos, root_rot_wxyz, dof_pos, stamp):
"""Publish robot joint states and root TF.
Args:
root_pos: [x, y, z] root position
root_rot_wxyz: [w, x, y, z] root quaternion
dof_pos: joint positions array
stamp: ROS timestamp
"""
# Publish TF for pelvis (root)
t = TransformStamped()
t.header.stamp = stamp
t.header.frame_id = 'world'
t.child_frame_id = 'pelvis'
t.transform.translation.x = float(root_pos[0])
t.transform.translation.y = float(root_pos[1])
t.transform.translation.z = float(root_pos[2])
# ROS TF expects (x, y, z, w)
t.transform.rotation.x = float(root_rot_wxyz[1])
t.transform.rotation.y = float(root_rot_wxyz[2])
t.transform.rotation.z = float(root_rot_wxyz[3])
t.transform.rotation.w = float(root_rot_wxyz[0])
self.tf_broadcaster.sendTransform(t)
# Publish joint states
joint_state = JointState()
joint_state.header.stamp = stamp
joint_state.name = JOINT_NAMES
joint_state.position = dof_pos.tolist() if hasattr(dof_pos, 'tolist') else list(dof_pos)
self.joint_state_pub.publish(joint_state)
def _add_bone_marker(self, marker_array, marker_id, start, end, stamp):
"""Add a cylinder marker connecting two joints."""
center = (start + end) / 2.0
diff = end - start
length = np.linalg.norm(diff)
if length < 1e-6:
return
marker = Marker()
marker.header.stamp = stamp
marker.header.frame_id = 'world'
marker.ns = 'skeleton_bones'
marker.id = marker_id
marker.type = Marker.CYLINDER
marker.action = Marker.ADD
marker.pose.position.x = float(center[0])
marker.pose.position.y = float(center[1])
marker.pose.position.z = float(center[2])
# Calculate quaternion to orient cylinder along bone
direction = diff / length
z_axis = np.array([0.0, 0.0, 1.0])
rot_axis = np.cross(z_axis, direction)
rot_axis_norm = np.linalg.norm(rot_axis)
if rot_axis_norm < 1e-6:
if direction[2] > 0:
marker.pose.orientation.w = 1.0
else:
marker.pose.orientation.x = 1.0
marker.pose.orientation.w = 0.0
else:
rot_axis = rot_axis / rot_axis_norm
angle = np.arccos(np.clip(np.dot(z_axis, direction), -1.0, 1.0))
marker.pose.orientation.x = float(rot_axis[0] * np.sin(angle / 2))
marker.pose.orientation.y = float(rot_axis[1] * np.sin(angle / 2))
marker.pose.orientation.z = float(rot_axis[2] * np.sin(angle / 2))
marker.pose.orientation.w = float(np.cos(angle / 2))
marker.scale.x = 0.015
marker.scale.y = 0.015
marker.scale.z = float(length)
marker.color.r = 1.0
marker.color.g = 0.5
marker.color.b = 0.0
marker.color.a = 1.0
marker_array.markers.append(marker)
def destroy_node(self):
"""Clean up resources."""
if self.realtime and hasattr(self, 'receiver'):
self.get_logger().info('Stopping MocapReceiver...')
self.receiver.stop()
super().destroy_node()
def main(args=None):
# Parse --realtime argument before ROS args
parser = argparse.ArgumentParser(description='Motion player for ROS2')
parser.add_argument('--realtime', action='store_true',
help='Use live mocap instead of file playback')
parsed, ros_args = parser.parse_known_args()
rclpy.init(args=ros_args)
node = MotionPlayerNode(realtime=parsed.realtime)
try:
rclpy.spin(node)
except KeyboardInterrupt:
pass
finally:
node.destroy_node()
try:
rclpy.shutdown()
except Exception:
pass
if __name__ == '__main__':
main()