# Copyright (c) 2022-2026, The Isaac Lab Project Developers (https://github.com/isaac-sim/IsaacLab/blob/main/CONTRIBUTORS.md). # All rights reserved. # # SPDX-License-Identifier: BSD-3-Clause """ Script to record demonstrations with Isaac Lab environments using human teleoperation. This script allows users to record demonstrations operated by human teleoperation for a specified task. The recorded demonstrations are stored as episodes in a hdf5 file. Users can specify the task, teleoperation device, dataset directory, and environment stepping rate through command-line arguments. required arguments: --task Name of the task. optional arguments: -h, --help Show this help message and exit --teleop_device Device for interacting with environment. (default: keyboard) --dataset_file File path to export recorded demos. (default: "./datasets/dataset.hdf5") --step_hz Environment stepping rate in Hz. (default: 30) --num_demos Number of demonstrations to record. (default: 0) --num_success_steps Number of continuous steps with task success for concluding a demo as successful. (default: 10) """ """Launch Isaac Sim Simulator first.""" # Standard library imports import argparse import contextlib # Isaac Lab AppLauncher from isaaclab.app import AppLauncher # add argparse arguments parser = argparse.ArgumentParser(description="Record demonstrations for Isaac Lab environments.") parser.add_argument("--task", type=str, required=True, help="Name of the task.") parser.add_argument( "--teleop_device", type=str, default="keyboard", help=( "Teleop device. Set here (legacy) or via the environment config. If using the environment config, pass the" " device key/name defined under 'teleop_devices' (it can be a custom name, not necessarily 'handtracking')." " Built-ins: keyboard, spacemouse, gamepad. Not all tasks support all built-ins." ), ) parser.add_argument( "--dataset_file", type=str, default="./datasets/dataset.hdf5", help="File path to export recorded demos." ) parser.add_argument("--step_hz", type=int, default=30, help="Environment stepping rate in Hz.") parser.add_argument( "--num_demos", type=int, default=0, help="Number of demonstrations to record. Set to 0 for infinite." ) parser.add_argument( "--num_success_steps", type=int, default=10, help="Number of continuous steps with task success for concluding a demo as successful. Default is 10.", ) parser.add_argument( "--enable_pinocchio", action="store_true", default=False, help="Enable Pinocchio.", ) # append AppLauncher cli args AppLauncher.add_app_launcher_args(parser) # parse the arguments args_cli = parser.parse_args() # Validate required arguments if args_cli.task is None: parser.error("--task is required") app_launcher_args = vars(args_cli) if args_cli.enable_pinocchio: # Import pinocchio before AppLauncher to force the use of the version # installed by IsaacLab and not the one installed by Isaac Sim. # pinocchio is required by the Pink IK controllers and the GR1T2 retargeter import pinocchio # noqa: F401 if "handtracking" in args_cli.teleop_device.lower(): app_launcher_args["xr"] = True # launch the simulator app_launcher = AppLauncher(args_cli) simulation_app = app_launcher.app """Rest everything follows.""" # Third-party imports import logging import os import time from typing import cast import gymnasium as gym import torch import omni.ui as ui from isaaclab.devices import Se3Keyboard, Se3KeyboardCfg, Se3SpaceMouse, Se3SpaceMouseCfg from isaaclab.devices.openxr import remove_camera_configs from isaaclab.devices.teleop_device_factory import create_teleop_device import isaaclab_mimic.envs # noqa: F401 from isaaclab_mimic.ui.instruction_display import InstructionDisplay, show_subtask_instructions if args_cli.enable_pinocchio: import isaaclab_tasks.manager_based.locomanipulation.pick_place # noqa: F401 import isaaclab_tasks.manager_based.manipulation.pick_place # noqa: F401 from collections.abc import Callable from isaaclab.envs import DirectRLEnvCfg, ManagerBasedRLEnvCfg from isaaclab.envs import ManagerBasedEnv from isaaclab.envs.mdp.recorders.recorders_cfg import ActionStateRecorderManagerCfg from isaaclab.envs.ui import EmptyWindow from isaaclab.managers import DatasetExportMode import isaaclab_tasks # noqa: F401 from isaaclab_tasks.utils.parse_cfg import parse_env_cfg # import logger logger = logging.getLogger(__name__) class RateLimiter: """Convenience class for enforcing rates in loops.""" def __init__(self, hz: int): """Initialize a RateLimiter with specified frequency. Args: hz: Frequency to enforce in Hertz. """ self.hz = hz self.last_time = time.time() self.sleep_duration = 1.0 / hz self.render_period = min(0.033, self.sleep_duration) def sleep(self, env: gym.Env): """Attempt to sleep at the specified rate in hz. Args: env: Environment to render during sleep periods. """ next_wakeup_time = self.last_time + self.sleep_duration while time.time() < next_wakeup_time: time.sleep(self.render_period) env.sim.render() self.last_time = self.last_time + self.sleep_duration # detect time jumping forwards (e.g. loop is too slow) if self.last_time < time.time(): while self.last_time < time.time(): self.last_time += self.sleep_duration def setup_output_directories() -> tuple[str, str]: """Set up output directories for saving demonstrations. Creates the output directory if it doesn't exist and extracts the file name from the dataset file path. Returns: tuple[str, str]: A tuple containing: - output_dir: The directory path where the dataset will be saved - output_file_name: The filename (without extension) for the dataset """ # get directory path and file name (without extension) from cli arguments output_dir = os.path.dirname(args_cli.dataset_file) output_file_name = os.path.splitext(os.path.basename(args_cli.dataset_file))[0] # create directory if it does not exist if not os.path.exists(output_dir): os.makedirs(output_dir) print(f"Created output directory: {output_dir}") return output_dir, output_file_name def create_environment_config( output_dir: str, output_file_name: str ) -> tuple[ManagerBasedRLEnvCfg | DirectRLEnvCfg, object | None]: """Create and configure the environment configuration. Parses the environment configuration and makes necessary adjustments for demo recording. Extracts the success termination function and configures the recorder manager. Args: output_dir: Directory where recorded demonstrations will be saved output_file_name: Name of the file to store the demonstrations Returns: tuple[isaaclab_tasks.utils.parse_cfg.EnvCfg, Optional[object]]: A tuple containing: - env_cfg: The configured environment configuration - success_term: The success termination object or None if not available Raises: Exception: If parsing the environment configuration fails """ # parse configuration try: env_cfg = parse_env_cfg(args_cli.task, device=args_cli.device, num_envs=1) env_cfg.env_name = args_cli.task.split(":")[-1] except Exception as e: logger.error(f"Failed to parse environment configuration: {e}") exit(1) # extract success checking function to invoke in the main loop success_term = None if hasattr(env_cfg.terminations, "success"): success_term = env_cfg.terminations.success env_cfg.terminations.success = None else: logger.warning( "No success termination term was found in the environment." " Will not be able to mark recorded demos as successful." ) if args_cli.xr: # If cameras are not enabled and XR is enabled, remove camera configs if not args_cli.enable_cameras: env_cfg = remove_camera_configs(env_cfg) env_cfg.sim.render.antialiasing_mode = "DLSS" # modify configuration such that the environment runs indefinitely until # the goal is reached or other termination conditions are met env_cfg.terminations.time_out = None env_cfg.observations.policy.concatenate_terms = False env_cfg.recorders: ActionStateRecorderManagerCfg = ActionStateRecorderManagerCfg() env_cfg.recorders.dataset_export_dir_path = output_dir env_cfg.recorders.dataset_filename = output_file_name env_cfg.recorders.dataset_export_mode = DatasetExportMode.EXPORT_SUCCEEDED_ONLY return env_cfg, success_term def create_environment(env_cfg: ManagerBasedRLEnvCfg | DirectRLEnvCfg) -> gym.Env: """Create the environment from the configuration. Args: env_cfg: The environment configuration object that defines the environment properties. This should be an instance of EnvCfg created by parse_env_cfg(). Returns: gym.Env: A Gymnasium environment instance for the specified task. Raises: Exception: If environment creation fails for any reason. """ try: env = gym.make(args_cli.task, cfg=env_cfg).unwrapped return env except Exception as e: logger.error(f"Failed to create environment: {e}") exit(1) def setup_teleop_device(callbacks: dict[str, Callable]) -> object: """Set up the teleoperation device based on configuration. Attempts to create a teleoperation device based on the environment configuration. Falls back to default devices if the specified device is not found in the configuration. Args: callbacks: Dictionary mapping callback keys to functions that will be attached to the teleop device Returns: object: The configured teleoperation device interface Raises: Exception: If teleop device creation fails """ teleop_interface = None try: if hasattr(env_cfg, "teleop_devices") and args_cli.teleop_device in env_cfg.teleop_devices.devices: teleop_interface = create_teleop_device(args_cli.teleop_device, env_cfg.teleop_devices.devices, callbacks) else: logger.warning( f"No teleop device '{args_cli.teleop_device}' found in environment config. Creating default." ) # Create fallback teleop device if args_cli.teleop_device.lower() == "keyboard": teleop_interface = Se3Keyboard(Se3KeyboardCfg(pos_sensitivity=0.2, rot_sensitivity=0.5)) elif args_cli.teleop_device.lower() == "spacemouse": teleop_interface = Se3SpaceMouse(Se3SpaceMouseCfg(pos_sensitivity=0.2, rot_sensitivity=0.5)) else: logger.error(f"Unsupported teleop device: {args_cli.teleop_device}") logger.error("Supported devices: keyboard, spacemouse, handtracking") exit(1) # Add callbacks to fallback device for key, callback in callbacks.items(): teleop_interface.add_callback(key, callback) except Exception as e: logger.error(f"Failed to create teleop device: {e}") exit(1) if teleop_interface is None: logger.error("Failed to create teleop interface") exit(1) return teleop_interface def setup_ui(label_text: str, env: gym.Env) -> InstructionDisplay: """Set up the user interface elements. Creates instruction display and UI window with labels for showing information to the user during demonstration recording. Args: label_text: Text to display showing current recording status env: The environment instance for which UI is being created Returns: InstructionDisplay: The configured instruction display object """ instruction_display = InstructionDisplay(args_cli.xr) if not args_cli.xr: window = EmptyWindow(env, "Instruction") with window.ui_window_elements["main_vstack"]: demo_label = ui.Label(label_text) subtask_label = ui.Label("") instruction_display.set_labels(subtask_label, demo_label) return instruction_display def process_success_condition(env: gym.Env, success_term: object | None, success_step_count: int) -> tuple[int, bool]: """Process the success condition for the current step. Checks if the environment has met the success condition for the required number of consecutive steps. Marks the episode as successful if criteria are met. Args: env: The environment instance to check success_term: The success termination object or None if not available success_step_count: Current count of consecutive successful steps Returns: tuple[int, bool]: A tuple containing: - updated success_step_count: The updated count of consecutive successful steps - success_reset_needed: Boolean indicating if reset is needed due to success """ if success_term is None: return success_step_count, False if bool(success_term.func(env, **success_term.params)[0]): success_step_count += 1 if success_step_count >= args_cli.num_success_steps: env.recorder_manager.record_pre_reset([0], force_export_or_skip=False) env.recorder_manager.set_success_to_episodes( [0], torch.tensor([[True]], dtype=torch.bool, device=env.device) ) env.recorder_manager.export_episodes([0]) print("Success condition met! Recording completed.") return success_step_count, True else: success_step_count = 0 return success_step_count, False def handle_reset( env: gym.Env, success_step_count: int, instruction_display: InstructionDisplay, label_text: str ) -> int: """Handle resetting the environment. Resets the environment, recorder manager, and related state variables. Updates the instruction display with current status. Args: env: The environment instance to reset success_step_count: Current count of consecutive successful steps instruction_display: The display object to update label_text: Text to display showing current recording status Returns: int: Reset success step count (0) """ print("Resetting environment...") env.sim.reset() env.recorder_manager.reset() env.reset() success_step_count = 0 instruction_display.show_demo(label_text) return success_step_count def run_simulation_loop( env: gym.Env, teleop_interface: object | None, success_term: object | None, rate_limiter: RateLimiter | None, ) -> int: """Run the main simulation loop for collecting demonstrations. Sets up callback functions for teleop device, initializes the UI, and runs the main loop that processes user inputs and environment steps. Records demonstrations when success conditions are met. Args: env: The environment instance teleop_interface: Optional teleop interface (will be created if None) success_term: The success termination object or None if not available rate_limiter: Optional rate limiter to control simulation speed Returns: int: Number of successful demonstrations recorded """ current_recorded_demo_count = 0 success_step_count = 0 should_reset_recording_instance = False running_recording_instance = not args_cli.xr # Callback closures for the teleop device def reset_recording_instance(): nonlocal should_reset_recording_instance should_reset_recording_instance = True print("Recording instance reset requested") def start_recording_instance(): nonlocal running_recording_instance running_recording_instance = True print("Recording started") def stop_recording_instance(): nonlocal running_recording_instance running_recording_instance = False print("Recording paused") # Set up teleoperation callbacks teleoperation_callbacks = { "R": reset_recording_instance, "START": start_recording_instance, "STOP": stop_recording_instance, "RESET": reset_recording_instance, } teleop_interface = setup_teleop_device(teleoperation_callbacks) teleop_interface.add_callback("R", reset_recording_instance) # Reset before starting env.sim.reset() env.reset() teleop_interface.reset() label_text = f"Recorded {current_recorded_demo_count} successful demonstrations." instruction_display = setup_ui(label_text, env) subtasks = {} with contextlib.suppress(KeyboardInterrupt) and torch.inference_mode(): while simulation_app.is_running(): # Get keyboard command action = teleop_interface.advance() # Expand to batch dimension actions = action.repeat(env.num_envs, 1) # Perform action on environment if running_recording_instance: # Compute actions based on environment obv = env.step(actions) if subtasks is not None: if subtasks == {}: subtasks = obv[0].get("subtask_terms") elif subtasks: show_subtask_instructions(instruction_display, subtasks, obv, env.cfg) else: env.sim.render() # Check for success condition success_step_count, success_reset_needed = process_success_condition(env, success_term, success_step_count) if success_reset_needed: should_reset_recording_instance = True # Update demo count if it has changed if env.recorder_manager.exported_successful_episode_count > current_recorded_demo_count: current_recorded_demo_count = env.recorder_manager.exported_successful_episode_count label_text = f"Recorded {current_recorded_demo_count} successful demonstrations." print(label_text) # Check if we've reached the desired number of demos if args_cli.num_demos > 0 and env.recorder_manager.exported_successful_episode_count >= args_cli.num_demos: label_text = f"All {current_recorded_demo_count} demonstrations recorded.\nExiting the app." instruction_display.show_demo(label_text) print(label_text) target_time = time.time() + 0.8 while time.time() < target_time: if rate_limiter: rate_limiter.sleep(env) else: env.sim.render() break # Handle reset if requested if should_reset_recording_instance: success_step_count = handle_reset(env, success_step_count, instruction_display, label_text) should_reset_recording_instance = False # Check if simulation is stopped if env.sim.is_stopped(): break # Rate limiting if rate_limiter: rate_limiter.sleep(env) return current_recorded_demo_count def main() -> None: """Collect demonstrations from the environment using teleop interfaces. Main function that orchestrates the entire process: 1. Sets up rate limiting based on configuration 2. Creates output directories for saving demonstrations 3. Configures the environment 4. Runs the simulation loop to collect demonstrations 5. Cleans up resources when done Raises: Exception: Propagates exceptions from any of the called functions """ # if handtracking is selected, rate limiting is achieved via OpenXR if args_cli.xr: rate_limiter = None from isaaclab.ui.xr_widgets import TeleopVisualizationManager, XRVisualization # Assign the teleop visualization manager to the visualization system XRVisualization.assign_manager(TeleopVisualizationManager) else: rate_limiter = RateLimiter(args_cli.step_hz) # Set up output directories output_dir, output_file_name = setup_output_directories() # Create and configure environment global env_cfg # Make env_cfg available to setup_teleop_device env_cfg, success_term = create_environment_config(output_dir, output_file_name) # Create environment env = create_environment(env_cfg) # Print robot joint names (runtime scene access; useful for debugging) try: env_mb = cast(ManagerBasedEnv, env) robot = env_mb.scene["robot"] print(f"===== JOINT NAMES =====\n{robot.data.joint_names}") except Exception as e: logger.warning(f"Failed to print robot joint names: {e}") # Print action term information (dimensions and joint mapping when available) try: env_mb = cast(ManagerBasedEnv, env) print("===== ACTION TERMS =====") print(env_mb.action_manager) # For some action terms (e.g. Pink IK), the IO descriptor includes the resolved joint-name mapping. for desc in env_mb.action_manager.get_IO_descriptors: name = desc.get("name", "") action_type = desc.get("action_type", "") shape = desc.get("shape", None) print(f"- {name}: type={action_type}, shape={shape}") pink_joints = desc.get("pink_controller_joint_names", None) hand_joints = desc.get("hand_joint_names", None) if pink_joints is not None: print(f" pink_controller_joint_names ({len(pink_joints)}): {pink_joints}") if hand_joints is not None: print(f" hand_joint_names ({len(hand_joints)}): {hand_joints}") except Exception as e: logger.warning(f"Failed to print action-space/joint mapping: {e}") # Run simulation loop current_recorded_demo_count = run_simulation_loop(env, None, success_term, rate_limiter) # Clean up env.close() print(f"Recording session completed with {current_recorded_demo_count} successful demonstrations") print(f"Demonstrations saved to: {args_cli.dataset_file}") if __name__ == "__main__": # run the main function main() # close sim app simulation_app.close()