# SPDX-FileCopyrightText: Copyright (c) 2025 NVIDIA CORPORATION & AFFILIATES. All rights reserved. # SPDX-License-Identifier: Apache-2.0 # # Licensed under the Apache License, Version 2.0 (the "License"); # you may not use this file except in compliance with the License. # You may obtain a copy of the License at # # http://www.apache.org/licenses/LICENSE-2.0 # # Unless required by applicable law or agreed to in writing, software # distributed under the License is distributed on an "AS IS" BASIS, # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. # See the License for the specific language governing permissions and # limitations under the License. """ This script is a replication of the notebook `getting_started/load_dataset.ipynb` """ import json import pathlib import time from dataclasses import dataclass, field from pprint import pprint from typing import List, Literal import matplotlib.pyplot as plt import numpy as np import tyro from gr00t.data.dataset import ( LE_ROBOT_MODALITY_FILENAME, LeRobotMixtureDataset, LeRobotSingleDataset, ModalityConfig, ) from gr00t.data.embodiment_tags import EMBODIMENT_TAG_MAPPING, EmbodimentTag from gr00t.utils.misc import any_describe def print_yellow(text: str) -> None: """Print text in yellow color""" print(f"\033[93m{text}\033[0m") @dataclass class ArgsConfig: """Configuration for loading the dataset.""" dataset_path: List[str] = field(default_factory=lambda: ["demo_data/robot_sim.PickNPlace"]) """Path to the dataset.""" embodiment_tag: Literal[tuple(EMBODIMENT_TAG_MAPPING.keys())] = "gr1" """Embodiment tag to use.""" video_backend: Literal["torchcodec", "decord", "torchvision_av"] = "torchcodec" """Backend to use for video loading, use torchcodec as default.""" plot_state_action: bool = False """Whether to plot the state and action space.""" steps: int = 200 """Number of steps to plot.""" ##################################################################################### def get_modality_keys(dataset_path: pathlib.Path) -> dict[str, list[str]]: """ Get the modality keys from the dataset path. Returns a dictionary with modality types as keys and their corresponding modality keys as values, maintaining the order: video, state, action, annotation """ modality_path = dataset_path / LE_ROBOT_MODALITY_FILENAME with open(modality_path, "r") as f: modality_meta = json.load(f) # Initialize dictionary with ordered keys modality_dict = {} for key in modality_meta.keys(): modality_dict[key] = [] for modality in modality_meta[key]: modality_dict[key].append(f"{key}.{modality}") return modality_dict def plot_state_action_space( state_dict: dict[str, np.ndarray], action_dict: dict[str, np.ndarray], shared_keys: list[str] = ["left_arm", "right_arm", "left_hand", "right_hand"], ): """ Plot the state and action space side by side. state_dict: dict[str, np.ndarray] with key: [Time, Dimension] action_dict: dict[str, np.ndarray] with key: [Time, Dimension] shared_keys: list[str] of keys to plot (without the "state." or "action." prefix) """ # Create a figure with one subplot per shared key fig = plt.figure(figsize=(16, 4 * len(shared_keys))) # Create GridSpec to organize the layout gs = fig.add_gridspec(len(shared_keys), 1) # Color palette for different dimensions colors = plt.cm.tab10.colors for i, key in enumerate(shared_keys): state_key = f"state.{key}" action_key = f"action.{key}" # Skip if either key is not in the dictionaries if state_key not in state_dict or action_key not in action_dict: print( f"Warning: Skipping {key} as it's not found in both state and action dictionaries" ) continue # Get the data state_data = state_dict[state_key] action_data = action_dict[action_key] print(f"{state_key}.shape: {state_data.shape}") print(f"{action_key}.shape: {action_data.shape}") # Create subplot ax = fig.add_subplot(gs[i, 0]) # Plot each dimension with a different color # Determine the minimum number of dimensions to plot min_dims = min(state_data.shape[1], action_data.shape[1]) for dim in range(min_dims): # Create time arrays for both state and action state_time = np.arange(len(state_data)) action_time = np.arange(len(action_data)) # State with dashed line ax.plot( state_time, state_data[:, dim], "--", color=colors[dim % len(colors)], linewidth=1.5, label=f"state dim {dim}", ) # Action with solid line (same color as corresponding state dimension) ax.plot( action_time, action_data[:, dim], "-", color=colors[dim % len(colors)], linewidth=2, label=f"action dim {dim}", ) ax.set_title(f"{key}") ax.set_xlabel("Time") ax.set_ylabel("Value") ax.grid(True, linestyle=":", alpha=0.7) # Create a more organized legend handles, labels = ax.get_legend_handles_labels() # Sort the legend so state and action for each dimension are grouped by_label = dict(zip(labels, handles)) ax.legend(by_label.values(), by_label.keys(), loc="upper right") plt.tight_layout() def plot_image(image: np.ndarray): """ Plot the image. """ # matplotlib show the image plt.imshow(image) plt.axis("off") plt.pause(0.05) # Non-blocking show plt.clf() # Clear the figure for the next frame def load_dataset( dataset_path: List[str], embodiment_tag: str, video_backend: str = "decord", steps: int = 200, plot_state_action: bool = False, ): assert len(dataset_path) > 0, "dataset_path must be a list of at least one path" # 1. get modality keys single_dataset_path = pathlib.Path( dataset_path[0] ) # take first one, assume all have same modality keys modality_keys_dict = get_modality_keys(single_dataset_path) video_modality_keys = modality_keys_dict["video"] language_modality_keys = modality_keys_dict["annotation"] state_modality_keys = modality_keys_dict["state"] action_modality_keys = modality_keys_dict["action"] pprint(f"Valid modality_keys for debugging:: {modality_keys_dict} \n") print(f"state_modality_keys: {state_modality_keys}") print(f"action_modality_keys: {action_modality_keys}") # remove dummy_tensor from state_modality_keys state_modality_keys = [key for key in state_modality_keys if key != "state.dummy_tensor"] # 2. construct modality configs from dataset modality_configs = { "video": ModalityConfig( delta_indices=[0], modality_keys=video_modality_keys, # we will include all video modalities ), "state": ModalityConfig( delta_indices=[0], modality_keys=state_modality_keys, ), "action": ModalityConfig( delta_indices=[0], modality_keys=action_modality_keys, ), } # 3. language modality config (if exists) if language_modality_keys: modality_configs["language"] = ModalityConfig( delta_indices=[0], modality_keys=language_modality_keys, ) # 4. gr00t embodiment tag embodiment_tag: EmbodimentTag = EmbodimentTag(embodiment_tag) # 5. load dataset print(f"Loading dataset from {dataset_path}") if len(dataset_path) == 1: dataset = LeRobotSingleDataset( dataset_path=dataset_path[0], modality_configs=modality_configs, embodiment_tag=embodiment_tag, video_backend=video_backend, ) else: print(f"Loading {len(dataset_path)} datasets") lerobot_single_datasets = [] for data_path in dataset_path: dataset = LeRobotSingleDataset( dataset_path=data_path, modality_configs=modality_configs, embodiment_tag=embodiment_tag, video_backend=video_backend, ) lerobot_single_datasets.append(dataset) # we will do a simple 1.0 sampling weight mix of the datasets dataset = LeRobotMixtureDataset( data_mixture=[(dataset, 1.0) for dataset in lerobot_single_datasets], mode="train", balance_dataset_weights=True, # balance based on number of trajectories balance_trajectory_weights=True, # balance based on trajectory length seed=42, metadata_config={ "percentile_mixing_method": "weighted_average", }, ) print_yellow( "NOTE: when using mixture dataset, we will randomly sample from all the datasets" "thus the state action ploting will not make sense, this is helpful to visualize the images" "to quickly sanity check the dataset used." ) print("\n" * 2) print("=" * 100) print(f"{' Humanoid Dataset ':=^100}") print("=" * 100) # print the 7th data point # resp = dataset[7] resp = dataset[0] any_describe(resp) print(resp.keys()) print("=" * 50) for key, value in resp.items(): if isinstance(value, np.ndarray): print(f"{key}: {value.shape}") else: print(f"{key}: {value}") # 6. plot the first 100 images images_list = [] video_key = video_modality_keys[0] # we will use the first video modality state_dict = {key: [] for key in state_modality_keys} action_dict = {key: [] for key in action_modality_keys} total_images = 20 # show 20 images skip_frames = steps // total_images for i in range(steps): resp = dataset[i] if i % skip_frames == 0: img = resp[video_key][0] # cv2 show the image # plot_image(img) if language_modality_keys: lang_key = language_modality_keys[0] print(f"Image {i}, prompt: {resp[lang_key]}") else: print(f"Image {i}") images_list.append(img.copy()) for state_key in state_modality_keys: state_dict[state_key].append(resp[state_key][0]) for action_key in action_modality_keys: action_dict[action_key].append(resp[action_key][0]) time.sleep(0.05) # convert lists of [np[D]] T size to np(T, D) for state_key in state_modality_keys: state_dict[state_key] = np.array(state_dict[state_key]) for action_key in action_modality_keys: action_dict[action_key] = np.array(action_dict[action_key]) if plot_state_action: plot_state_action_space(state_dict, action_dict) print("Plotted state and action space") fig, axs = plt.subplots(4, total_images // 4, figsize=(20, 10)) for i, ax in enumerate(axs.flat): ax.imshow(images_list[i]) ax.axis("off") ax.set_title(f"Image {i*skip_frames}") plt.tight_layout() # adjust the subplots to fit into the figure area. plt.show() if __name__ == "__main__": config = tyro.cli(ArgsConfig) load_dataset( config.dataset_path, config.embodiment_tag, config.video_backend, config.steps, config.plot_state_action, )