Datasets:

Berkeley-Humanoids
/

Lite-Motion-Tracking-Dataset

	"""Shared helpers for the LAFAN1 → Lite retargeting pipeline.

	Conventions:
	- Quaternions are scalar-first WXYZ, unit-norm, ``w >= 0``. The only non-WXYZ
	appearance is the LAFAN1 CSV row, converted exactly once in
	:func:`load_lafan_csv`.
	- The Lite ``joint_pos`` column order is whatever MuJoCo emits from the MJCF
	(:func:`lite_joint_names`); we never hardcode it.
	"""

	import re
	from pathlib import Path

	import mujoco
	import numpy as np

	# ── Constants ─────────────────────────────────────────────────────────────────

	FPS: int = 30
	LAFAN_REPO_ID: str = "lvhaidong/LAFAN1_Retargeting_Dataset"
	LITE_DATASET_REPO_ID: str = "Berkeley-Humanoids/Lite-Motion-Tracking-Dataset"
	LITE_TASK_NAME: str = "track_lafan1"

	# End-effector body names — Lite (matches the MJCF) and the G1 URDF after MuJoCo
	# import (the ``*_rubber_hand`` link is fixed-jointed and fuses into
	# ``*_wrist_yaw_link``, which is the last named body in each arm chain).
	LITE_FOOT_BODIES: tuple[str, str] = ("left_foot", "right_foot")
	LITE_HAND_BODIES: tuple[str, str] = ("left_hand", "right_hand")
	G1_FOOT_BODIES: tuple[str, str] = ("left_ankle_roll_link", "right_ankle_roll_link")
	G1_HAND_BODIES: tuple[str, str] = ("left_wrist_yaw_link", "right_wrist_yaw_link")

	LAFAN_G1_URDF_RELPATH: str = "robot_description/g1/g1_29dof_rev_1_0.urdf"

	# Authoritative LAFAN1 G1 CSV joint order. Every CSV row is
	# ``[base_x, base_y, base_z, base_qx, base_qy, base_qz, base_qw,
	# *G1_LAFAN_JOINT_NAMES]`` at 30 FPS.
	G1_LAFAN_JOINT_NAMES: tuple[str, ...] = (
	"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",
	)

	# G1 joint → (Lite joint, sign, offset_rad). Step-1 retargeting applies
	# ``lite_q[t] = sign * g1_q[t] + offset`` per joint.
	#
	# Decisions baked into this table:
	# - Legs: chain order and axes match; sign=+1, offset=0.
	# - Waist: chain order DIFFERS (G1 yaw→roll→pitch vs Lite yaw→pitch→roll),
	# but axes match by name, so we map by name and accept the small
	# rotation-order approximation when multiple waist joints are non-zero.
	# - Shoulders + elbows: chain order matches; offsets bring G1's arms-down
	# rest pose to Lite's T-pose rest (±π/2 on shoulder_roll and elbow).
	# - Wrists: chain order DIFFERS (G1 roll→pitch→yaw vs Lite yaw→roll→pitch)
	# but the physical 3-DoF wrist is the same, so we map by *position in
	# the chain* (G1 wrist_roll → Lite wrist_yaw, etc.). Sign of the first
	# wrist DoF is -1 because the URDFs picked opposite positive directions.
	G1_TO_LITE: dict[str, tuple[str, int, float]] = {
	# Legs (12)
	"left_hip_pitch_joint": ("left_hip_pitch", +1, 0.0),
	"left_hip_roll_joint": ("left_hip_roll", +1, 0.0),
	"left_hip_yaw_joint": ("left_hip_yaw", +1, 0.0),
	"left_knee_joint": ("left_knee_pitch", +1, 0.0),
	"left_ankle_pitch_joint": ("left_ankle_pitch", +1, 0.0),
	"left_ankle_roll_joint": ("left_ankle_roll", +1, 0.0),
	"right_hip_pitch_joint": ("right_hip_pitch", +1, 0.0),
	"right_hip_roll_joint": ("right_hip_roll", +1, 0.0),
	"right_hip_yaw_joint": ("right_hip_yaw", +1, 0.0),
	"right_knee_joint": ("right_knee_pitch", +1, 0.0),
	"right_ankle_pitch_joint": ("right_ankle_pitch", +1, 0.0),
	"right_ankle_roll_joint": ("right_ankle_roll", +1, 0.0),
	# Waist (3)
	"waist_yaw_joint": ("waist_yaw", +1, 0.0),
	"waist_roll_joint": ("waist_roll", +1, 0.0),
	"waist_pitch_joint": ("waist_pitch", +1, 0.0),
	# Arms (14) — left
	"left_shoulder_pitch_joint": ("left_shoulder_pitch", +1, 0.0),
	"left_shoulder_roll_joint": ("left_shoulder_roll", +1, -1.5708),
	"left_shoulder_yaw_joint": ("left_shoulder_yaw", +1, 0.0),
	"left_elbow_joint": ("left_elbow_pitch", +1, -1.5708),
	"left_wrist_roll_joint": ("left_wrist_yaw", -1, 0.0),
	"left_wrist_pitch_joint": ("left_wrist_roll", +1, 0.0),
	"left_wrist_yaw_joint": ("left_wrist_pitch", +1, 0.0),
	# Arms (14) — right
	"right_shoulder_pitch_joint":("right_shoulder_pitch",+1, 0.0),
	"right_shoulder_roll_joint": ("right_shoulder_roll", +1, +1.5708),
	"right_shoulder_yaw_joint": ("right_shoulder_yaw", +1, 0.0),
	"right_elbow_joint": ("right_elbow_pitch", +1, -1.5708),
	"right_wrist_roll_joint": ("right_wrist_yaw", -1, 0.0),
	"right_wrist_pitch_joint": ("right_wrist_roll", +1, 0.0),
	"right_wrist_yaw_joint": ("right_wrist_pitch", +1, 0.0),
	}


	# ── Model loaders ─────────────────────────────────────────────────────────────


	def load_lite_model() -> mujoco.MjModel:
	"""Load the Berkeley Lite humanoid MJCF via the Berkeley-Humanoids package."""
	from robot_descriptions import load_asset

	return mujoco.MjModel.from_xml_path(str(load_asset("robots/lite/mjcf/lite.xml")))


	def load_g1_model(lafan_root: Path) -> mujoco.MjModel:
	"""Load the Unitree G1 URDF bundled in the downloaded LAFAN1 dataset.

	The URDF declares ``<compiler meshdir="meshes"/>`` and also references
	meshes as ``meshes/foo.STL`` — MuJoCo would concatenate to
	``meshes/meshes/foo.STL``. We rewrite meshdir to ``"."`` and supply the
	mesh bytes through the ``assets`` dict so nothing touches the filesystem
	a second time.
	"""
	urdf = Path(lafan_root) / LAFAN_G1_URDF_RELPATH
	if not urdf.exists():
	raise FileNotFoundError(
	f"G1 URDF not found at {urdf}. Run scripts/download_lafan.py first."
	)
	text = re.sub(r'meshdir="[^"]*"', 'meshdir="."', urdf.read_text())
	assets = {f"meshes/{p.name}": p.read_bytes() for p in (urdf.parent / "meshes").glob("*.STL")}
	return mujoco.MjModel.from_xml_string(text, assets=assets)


	def joint_qpos_addr(model: mujoco.MjModel, joint_name: str) -> int:
	"""Index into ``data.qpos`` for a 1-DoF joint by name."""
	jid = mujoco.mj_name2id(model, mujoco.mjtObj.mjOBJ_JOINT, joint_name)
	if jid < 0:
	raise KeyError(f"Joint {joint_name!r} not found in model")
	return int(model.jnt_qposadr[jid])


	def body_id(model: mujoco.MjModel, body_name: str) -> int:
	"""Body id for ``body_name``, raising if absent."""
	bid = mujoco.mj_name2id(model, mujoco.mjtObj.mjOBJ_BODY, body_name)
	if bid < 0:
	raise KeyError(f"Body {body_name!r} not found in model")
	return int(bid)


	def lite_joint_names(model: mujoco.MjModel) -> tuple[str, ...]:
	"""All hinge joint names in the Lite model in MuJoCo's depth-first order.

	Skips the free joint at index 0 if present. The result is the single
	source of truth for the LeRobotDataset ``joint_pos`` column order.
	"""
	names: list[str] = []
	for jid in range(model.njnt):
	if model.jnt_type[jid] == mujoco.mjtJoint.mjJNT_FREE:
	continue
	name = mujoco.mj_id2name(model, mujoco.mjtObj.mjOBJ_JOINT, jid)
	if name is None:
	raise RuntimeError(f"Lite joint id {jid} has no name")
	names.append(name)
	return tuple(names)


	# ── LAFAN1 CSV I/O ────────────────────────────────────────────────────────────


	def load_lafan_csv(path: Path) -> dict[str, np.ndarray]:
	"""Read one LAFAN1 G1 CSV into base pose + joint positions.

	On-disk format: headerless, 30 FPS, ``[base_xyz(3), base_quat_xyzw(4),
	joint_pos(29)]`` per row. Converts XYZW → WXYZ and flips quaternion sign
	so ``w >= 0``.

	Returns:
	Dict with ``base_pos`` ``(T, 3)``, ``base_quat_wxyz`` ``(T, 4)``,
	``g1_joint_pos`` ``(T, 29)`` — all float32. Joint columns follow
	:data:`G1_LAFAN_JOINT_NAMES`.
	"""
	raw = np.loadtxt(path, delimiter=",", dtype=np.float32)
	expected_cols = 7 + len(G1_LAFAN_JOINT_NAMES)
	if raw.ndim != 2 or raw.shape[1] != expected_cols:
	raise ValueError(
	f"{path}: expected {expected_cols} columns, got shape {raw.shape}"
	)
	base_quat = np.empty((raw.shape[0], 4), dtype=np.float32)
	base_quat[:, 0] = raw[:, 6]
	base_quat[:, 1:4] = raw[:, 3:6]
	base_quat /= np.linalg.norm(base_quat, axis=1, keepdims=True)
	base_quat[base_quat[:, 0] < 0] *= -1.0
	return {
	"base_pos": raw[:, 0:3],
	"base_quat_wxyz": base_quat,
	"g1_joint_pos": raw[:, 7:],
	}


	# ── Derivatives ───────────────────────────────────────────────────────────────


	def finite_diff(x: np.ndarray, fps: int) -> np.ndarray:
	"""Central finite difference along axis 0."""
	return np.gradient(x, 1.0 / fps, axis=0).astype(x.dtype, copy=False)


	def angular_velocity_from_quat(q_wxyz: np.ndarray, fps: int) -> np.ndarray:
	"""World-frame angular velocity (rad/s) from a sequence of WXYZ quaternions.

	Uses the central stencil ``omega = axis_angle(q[t+1] * q[t-1]^-1) / 2dt``;
	endpoints are repeated to keep length T.
	"""
	dt = 1.0 / fps
	rel = _quat_mul(q_wxyz[2:], _quat_conj(q_wxyz[:-2]))
	omega_mid = _axis_angle_from_quat(rel) / (2.0 * dt)
	omega = np.empty((q_wxyz.shape[0], 3), dtype=q_wxyz.dtype)
	omega[1:-1] = omega_mid
	omega[0] = omega_mid[0]
	omega[-1] = omega_mid[-1]
	return omega


	def _quat_mul(a: np.ndarray, b: np.ndarray) -> np.ndarray:
	aw, ax, ay, az = a[..., 0], a[..., 1], a[..., 2], a[..., 3]
	bw, bx, by, bz = b[..., 0], b[..., 1], b[..., 2], b[..., 3]
	out = np.empty_like(a)
	out[..., 0] = aw * bw - ax * bx - ay * by - az * bz
	out[..., 1] = aw * bx + ax * bw + ay * bz - az * by
	out[..., 2] = aw * by - ax * bz + ay * bw + az * bx
	out[..., 3] = aw * bz + ax * by - ay * bx + az * bw
	return out


	def _quat_conj(q: np.ndarray) -> np.ndarray:
	out = q.copy()
	out[..., 1:] *= -1.0
	return out


	def _axis_angle_from_quat(q: np.ndarray) -> np.ndarray:
	"""WXYZ quaternion → rotation vector ``axis * angle``, shape ``(..., 3)``."""
	w = np.clip(q[..., 0], -1.0, 1.0)
	xyz = q[..., 1:]
	sin_half = np.linalg.norm(xyz, axis=-1)
	angle = 2.0 * np.arctan2(sin_half, w)
	safe = sin_half > 1e-8
	axis = np.zeros_like(xyz)
	axis[safe] = xyz[safe] / sin_half[safe, None]
	return axis * angle[..., None]


	# ── LeRobotDataset feature schema ─────────────────────────────────────────────


	def dataset_features(joint_count: int) -> dict:
	"""LeRobotDataset feature schema for the retargeted Lite motion dataset.

	Six flat fields, scalar-first WXYZ for the base orientation, no ``action``
	(this is a kinematic reference).
	"""
	return {
	"base_pos": {"dtype": "float32", "shape": (3,), "names": ["x", "y", "z"]},
	"base_quat": {"dtype": "float32", "shape": (4,), "names": ["w", "x", "y", "z"]},
	"base_lin_vel": {"dtype": "float32", "shape": (3,), "names": ["vx", "vy", "vz"]},
	"base_ang_vel": {"dtype": "float32", "shape": (3,), "names": ["wx", "wy", "wz"]},
	"joint_pos": {"dtype": "float32", "shape": (joint_count,), "names": None},
	"joint_vel": {"dtype": "float32", "shape": (joint_count,), "names": None},
	}