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708fa1d189
* Add GR00T N1.7 support
Add GR00T N1.7 policy configuration, checkpoint compatibility, processor parity, LIBERO documentation, and focused tests.
Co-authored-by: Ryan Halabi <ryhalabi@nvidia.com>
* Move Groot processor compatibility into Groot loader
* Restore GR00T Flash Attention install guidance
* Allow Groot fake RTC chunk prefetch
* Fix GR00T N1.7 RTC action decoding
* Trim GR00T N1.7 RTC chunks to valid horizon
* Ignore padded GR00T N1.7 RTC prefix rows
* removed n1.5 dependency
* removed remaining N1.5 traces
* groot: auto-enable LIBERO gripper action transform for libero_sim
GR00T N1.7 emits gripper in [0,1] but LIBERO expects [-1,1]. The decode
transform existed but was never auto-enabled for embodiment_tag=libero_sim,
so the policy scored 0% on LIBERO eval. Auto-set it in __post_init__ (still
overridable). LIBERO Spatial eval: 0% -> 98%.
* Reconnect GR00T relative action processors
* groot: remove dead N1.5 code (eagle2_hg_model, flow_matching_action_head, action_encoder)
N1.7 backbone is nvidia/Cosmos-Reason2-2B via Qwen3VLForConditionalGeneration,
not Eagle2 — eagle2_hg_model/ had zero refs outside its own dir.
GR00TN17ActionHead (groot_n1_7.py) re-implements MultiEmbodimentActionEncoder +
CategorySpecificLinear + swish + SinusoidalPositionalEncoding locally, so
flow_matching_action_head.py (N1.5 FlowmatchingActionHead) and its sole
dependency action_encoder.py are dead. Verified: no src/ or tests/ reference.
Removed (~2037 LOC):
- eagle2_hg_model/ (4 files, ~1575 LOC)
- action_head/flow_matching_action_head.py (408 LOC)
- action_head/action_encoder.py (54 LOC)
cross_attention_dit.py KEPT (DiT/AlternateVLDiT/SelfAttentionTransformer live in N1.7).
* groot: reuse lerobot get_device_from_parameters instead of inline lookup
modeling_groot.py duplicated next(self.parameters()).device twice. LeRobot
ships get_device_from_parameters in policies/utils.py (used by diffusion,
vqbet, tdmpc, gaussian_actor). Reuse it for consistency with the framework.
* groot: fix stale Eagle VLM docstring in processor (N1.7 uses Qwen3-VL backbone)
Addresses checker nit: processor_groot.py docstring still described the N1.5
Eagle VLM path with eagle_content/eagle_* keys that no longer exist in the code.
* test(groot): add N1.7 original-vs-LeRobot output parity test
Verifies the LeRobot GR00T N1.7 integration produces equivalent raw
action_pred to NVIDIA Isaac-GR00T for the same checkpoint, inputs, seed,
precision (fp32) and attention kernel (SDPA): max|diff|=8.9e-7 on the
libero_sim embodiment (GR00T-N1.7-LIBERO/libero_10).
The two impls pin incompatible transformers majors (orig 4.57.3 vs
LeRobot 5.x) and cannot share a process, so the original outputs + exact
collated inputs are produced out-of-process and loaded from an .npz. The
test skips on CI / when the checkpoint or artifact are absent.
* test(groot): parametrize N1.7 parity across all checkpoint embodiments
Generalize the original-vs-LeRobot N1.7 output-parity test from a single
libero_sim case to every embodiment tag in the checkpoint (libero_sim, oxe_droid,
real_g1, the real_r1_pro_sharpa family, and the xdof family). Inputs are built
generically from checkpoint metadata; the test discovers per-tag .npz artifacts
and runs one parametrized case each, loading the LeRobot model once via a fixture.
All 9 embodiments match the original to fp32 epsilon (max|diff| < 3e-6), confirming
the integration is correct across the model's full embodiment space and not overfit
to libero_sim.
* test(groot): self-contained parity test + in-repo producer + docs
- Rename test_groot_n1_7_vs_original.py -> test_groot_vs_original.py
- Make the test self-contained: producer script (dump_original_n1_7.py) now lives
next to the test; default artifact dir is repo-relative
(tests/policies/groot/artifacts/), overridable via GROOT_N1_7_PARITY_DIR. The
test only reads artifacts and skips if absent -- it never creates external dirs.
- Heavy .npz artifacts (~6-9MB each) are gitignored and regenerated by the producer;
never committed.
- Drop the verbose 'MULTIPLE EMBODIMENTS' docstring block (kept a one-line note).
- Document the parity procedure in the groot policy README (docs/source/policy_groot_README.md).
- Rename test fn test_groot_n1_7_get_action_parity -> test_groot_get_action_parity.
9/9 embodiments still pass (max|diff| < 3e-6, fp32 eps).
* docs(groot): drop WHY TWO ENVIRONMENTS block from parity test docstring
* test(groot): move parity producer into utils/ package
Mirror the tests/policies/pi0_pi05/utils convention: move dump_original_n1_7.py into
a tests/policies/groot/utils/ package (with __init__.py) and update all path
references in the test docstring/skip-message and the policy README.
* test(groot): adopt test_groot_lerobot for GR00T N1.7, drop N1.5
The test loaded MODEL_PATH='aractingi/bimanual-handover-groot-10k', an N1.5
checkpoint (config base_model_path=nvidia/GR00T-N1.5-3B, no model_version). On
load, model_version defaults to n1.7 while the base path infers n1.5, so the
version-consistency guard in GrootConfig.__post_init__ raised ValueError and both
test_lerobot_groot_inference and test_lerobot_groot_forward_pass failed. N1.5 is no
longer a supported model_version.
Adopt the test for N1.7:
- MODEL_PATH -> nvidia/GR00T-N1.7-3B (root-level sharded safetensors; loads via
GrootPolicy.from_pretrained as a base N1.7 model).
- Embodiment tag 'gr1' (N1.5) -> 'gr1_unified' (valid N1.7 tag from the checkpoint
embodiment_id.json), via a single EMBODIMENT_TAG constant.
- DUMMY_ACTION_HORIZON 16 -> 40 to match N1.7's native action-chunk size.
- Docstrings/labels updated to 'GR00T N1.7'.
Both tests run and pass on CUDA; full tests/policies/groot/ suite is
73 passed / 0 failed / 0 skipped.
* docs(groot): document the N1.5 removal and the N1.7 parity test
- groot.mdx: breaking-change warning and migration path (pin lerobot==0.5.1 to
keep N1.5, or move to N1.7); the dead `huggingface-cli download` is replaced
with `hf download`.
- policy_groot_README.md: N1.5 removal note, updated paper / model-card links,
and the two-comparison (model parity + preprocessor parity) description of
the original-vs-LeRobot test, including the raw-observation artifacts and
recorded seed.
* fix(groot): N1.7 backbone loading and DiT parameter-count logging
- select_layer default tracks the N1.7-3B checkpoint value (16); real
checkpoint loads still override it from config.json.
- get_backbone_cls recognizes Cosmos-Reason2 / Qwen3-VL backbones by name and
warns (instead of silently assuming) when an unrecognized backbone is loaded
only on the strength of backbone_model_type='qwen'.
- 'revision' pins the GR00T checkpoint repo only and is no longer forwarded
into the unrelated backbone repo load; pin the backbone via
transformers_loading_kwargs instead.
- DiT / SelfAttentionTransformer parameter counts go through logging.debug
instead of print().
* fix(groot): N1.7 config defaults, N1.5 rejection, and processor/model runtime fixes
Covers the GR00T N1.7 source trio (configuration, processor, model wrapper).
Config:
- GrootConfig defaults are the N1.7 values; explicitly passed legacy N1.5-era
values (chunk_size=50, max_state_dim=64, ...) are remapped with a warning
instead of silently.
- action_decode_transform gains an 'auto' sentinel so an explicit 'none'
opt-out wins over the libero_sim default and survives save/load round-trips.
- action_delta_indices is cached on the inputs that determine it.
- Legacy N1.5 checkpoints/configs (tokenizer_assets_repo, model_type/
architectures/eagle backbone markers) are rejected with a single clear
error pointing to lerobot==0.5.1.
Processor:
- GrootN17ActionDecodeStep handles the 2-D (B, D) actions delivered by sync
select_action (relative eef/non-eef decode in eval/record flows).
- Postprocessor falls back to dataset stats when a raw checkpoint lacks the
configured embodiment tag; raw-state cache is per-instance, not
process-global; caller overrides (device, rename_map) are honored on the
raw-checkpoint branch.
- Camera/modality-key mismatches warn (including the zero-match fallback);
deprecated Qwen2VLImageProcessorFast replaced with Qwen2VLImageProcessor;
removed N1.5 processor steps are stubbed to raise the removal guidance and
the action-unpack step is re-registered as _v2.
Model:
- Flash-attention probe is diagnostic-only; forward raises on a missing loss;
print() replaced with logging; N1.5 base-path mismatch includes the
removal guidance.
* fix(groot): skip normalization overrides for training
* fix(groot): GPU/tensor N1.7 image preprocessing + resize to trained resolution
GR00T training was dataloader-bound (0->100->0 GPU-utilization sawtooth).
GrootN17VLMEncodeStep ran the Qwen3-VL image processor per frame on PIL images
on the single CPU main-loop thread, and that cost is timed inside dataloading_s
(preprocessor(batch) runs in the main process, not the dataloader workers), so
adding workers cannot hide it.
- Feed the torchvision-backed Qwen3-VL processor (C,H,W) uint8 tensors instead
of a per-frame Image.fromarray PIL roundtrip, and run resize/normalize/patchify
on config.device (GPU) when available. Bit-identical on CPU when no resize is
configured; with a resize only the PIL->torchvision bicubic backend differs
(<2/255 per pixel). The use_albumentations path stays PIL/cv2; reload on a box
without the saved device falls back to CPU.
- Default image_target_size/crop to the N1.7 backbone's training geometry
(256x256 / 230x230) when a checkpoint ships no image sizing (checkpoint_assets
is None, e.g. finetuning nvidia/GR00T-N1.7-3B via repo-id with a new
embodiment). Previously image_target_size=None disabled the resize, so
full-resolution frames were patchified into ~4.7x more vision tokens than the
model was trained on -- inflating dataloading_s (patchify) and update_s (VLM
sequence) and skewing the input distribution. Checkpoints that pin their own
sizing are honored; the default constants are shared with GR00T_N1_7_DEFAULTS.
Net: preprocessing leaves the CPU critical path and the VLM sees the resolution
it was trained on -- faster training/inference and a correct train/serve
distribution. Affects inference too (shared preprocessor); existing checkpoints
still load (backward compatible) but must be retrained to gain the benefits.
* refactor(groot): N1.7 style cleanup (utils, imports, flash-attn, config)
Mechanical refactor of the GR00T N1.7 policy to match the repo's architecture and
style standards. No change to policy algorithm/numerics; only UX/CLI and packaging
changes. Tests are intentionally left untouched (out of scope) and need updating
for the removed `model_version` field.
Cleanup & consolidation:
- Add `groot/utils.py` holding the pure, side-effect-free helpers (JSON I/O, value
coercion, stat flattening, rot6d/SE3 math, language/batch prep) shared by the
config and processor layers.
- Remove dead code: the unused `resolve_groot_n1_7_backbone_model` cache-resolver
cluster, `GR00TN17Config.to_filtered_dict/json`, and the `_copy_default` wrapper.
Imports & execution guards:
- Hoist nested imports to module top; relative imports within the package, absolute
for external modules. The version-gated Qwen3-VL classes import under the single
`_transformers_available` guard (transformers is pinned >=5.4, which ships them).
- No import-time side effects: `_register_with_transformers()` now runs in
`GR00TN17.__init__` (idempotent via `register(exist_ok=True)`), and the N1.5 step
stubs register lazily before pipeline deserialization (idempotent via the
registry, no run-once globals).
- Gate optional deps at the point of use with `require_package(..., extra="groot")`.
Dependencies & docs:
- Drop `flash-attn` (and its build-only dep `ninja`) from the `groot` extra; default
to SDPA (numerically equivalent) with opt-in via `--policy.use_flash_attention`.
Un-comment `lerobot[groot]` in the `all` extra and regenerate `uv.lock`.
- Rewrite the `groot.mdx` install section: flash-attn is a purely optional,
user-managed optimization that LeRobot neither installs nor requires.
Config & CLI:
- Surface previously-frozen knobs on `GrootConfig` (plumbed into `GR00TN17Config`;
no-ops at their defaults): inference — `num_inference_timesteps`, `rtc_ramp_rate`,
`use_flash_attention`; fine-tuning — `tune_top_llm_layers` (partial-LLM tuning)
and `tune_vlln` (previously hardwired to True).
- Convert the single-valued `model_version` and `n1_7_backbone_model` fields to
internal constants.
- Keep `base_model_path`: it is NOT equivalent to `pretrained_path` (raw NVIDIA
checkpoints have no LeRobot `type` field and load only via `base_model_path`) and
is genuinely user-tunable.
- Keep the deprecated Isaac-GR00T/N1.5 fields (and the dead LoRA fields) as a
back-compat block so a v0.5.1 N1.5 `config.json` still parses under draccus and is
rejected with the friendly N1.5 removal message instead of an opaque decode error.
* Optimize GR00T N1.7 image preprocessing
* Remove PIL fallback from GR00T preprocessing
* Fix GROOT relative action training stats
* Address GROOT relative action review feedback
* Fix GROOT N1.7 relative action stats
* Fix GROOT relative action training stats
* Fix GROOT relative action padding and RTC leftovers
* Reset rollout state after robot episode end
* Revert "Reset rollout state after robot episode end"
This reverts commit 1322f45aec.
* Move GROOT relative stats out of train script
* Guard GR00T relative action stepwise decode
* Match GR00T N1.7 OSS preprocessing and relative actions
* Apply LIBERO action decode override after loading
* Format GR00T OSS parity changes
* chore(policies): add guards, warnings and comments + recover tests n1.5 check
* fix(style): pre-commit
* fix(ci): guard dependecy checks
* chore(groot): move cv2 to the top as its in the default install tag
* chore(policies): add explicit dataset dependecy to gr00t implementation
* fix(test): add guard
* fix(groot): make N1.7 letterbox opt-in
* feat(groot): activate checkpoint-configured N1.7 raw-state dropout during training
Isaac-GR00T applies dual state regularization during fine-tuning: raw-state
zeroing driven by the processor sidecar's state_dropout_prob (0.2 for the
inspected N1.7 checkpoint) plus encoded-feature dropout. Baseline LeRobot kept
the processor in deterministic mode, so the raw-state dropout never activated
(RCA Tier-2 contributor to the LeRobot-trained SO-101 failures).
- GrootN17PackInputsStep: runtime-only 'training' flag + state_dropout_prob;
whole-sample state zeroing gated on torch.is_grad_enabled() so eval and
no_grad validation paths are unaffected
- sidecar loader reads state_dropout_prob from processor_config.json
- state_dropout_prob serializes with the step; the training flag intentionally
does not (reloaded pipelines default to eval, re-enabled only when processors
are rebuilt with dataset_meta)
- _set_groot_preprocessor_training toggles any dataclass step exposing a
'training' field on serialized-pipeline reloads
Verification: tests/policies/groot/test_groot_state_dropout.py (4 passed) on
RTX PRO 6000 / CUDA 13.3.
* fix(groot): align N1.7 fine-tuning optimizer/scheduler/precision with Isaac-GR00T
Evidence from the LeRobot-vs-OSS checkpoint comparison: the LeRobot/HF 8k
checkpoint's DiT moved only ~19% as far from base as the OSS-trained one
(0.0547 vs 0.285 relative L2) - undertrained because the scheduler decayed over
a hardcoded 10k steps regardless of --steps, on top of beta1/clip mismatches.
- AdamW betas (0.95, 0.999) -> (0.9, 0.999) and grad_clip_norm 10.0 -> 1.0
(Isaac defaults)
- scheduler: hardcoded CosineDecayWithWarmup(10k decay, floor 10% peak) ->
DiffuserSchedulerConfig HF cosine with ceil(max_steps * warmup_ratio) warmup,
deriving num_training_steps from the outer --steps at runtime
- model_params_fp32 (default true): keep master weights in FP32 and compute
under BF16 autocast like the native N1.7 recipe (fixes optimizer-update
numerics vs pure-BF16 params)
- weight-decay grouping via transformers get_parameter_names: biases and norm
parameters excluded from decay
- restore the TF4 lm_head/embedding weight tie so the unused Qwen LM head stays
frozen and deduplicated in checkpoints
- action_mask kept in native dtype for the masked flow-matching loss
- drop_n_last_frames: exclude episode tails that cannot supply a complete
action chunk (Isaac sampler behavior)
Verification: tests/policies/groot/test_groot_training_optim_contract.py
(7 passed) + remaining groot suite 11 passed/5 skipped on RTX PRO 6000 /
CUDA 13.3. Note: tests/policies/groot/test_groot_n1_7.py does not collect on
the base branch (pre-existing ImportError, fixed in PR #37).
* feat(groot): train-time random crop for N1.7 (eval keeps center crop)
Isaac-GR00T crops a random crop_fraction window during training and the
deterministic center window at eval, replaying the sampled window across all
camera views of a sample. This contract is unchanged since the N1.5 release
(gr00t/data/transform/video.py: "If mode is 'train', return a random crop
transform. If mode is 'eval', return a center crop transform.") and mirrors
LeRobot's own Diffusion/VQBeT crop_is_random pattern. The LeRobot N1.7 port
used the eval center crop for training too, so the fine-tuned projector/DiT
never sees frame borders and trains on a single fixed appearance point.
Scope: crop geometry ONLY - no color jitter, no new dependencies. The random
window is plain numpy slicing inside the existing cv2 eval transform:
- _transform_n1_7_image_for_vlm_albumentations gains crop_position=(y, x)
fractions; None keeps the center crop byte-identical to before (verified
by test)
- GrootN17VLMEncodeStep gains a runtime-only 'training' flag (never
serialized; reloaded pipelines default to eval); training samples ONE
window per sample and reuses it across (timestep, view) frames - Isaac's
cross-view consistency
- gated on torch.is_grad_enabled() so no_grad validation and frozen-eval
paths are unaffected
- wired via dataset_meta is not None in make_groot_pre_post_processors and
the existing _set_groot_preprocessor_training on serialized reloads
Verification: tests/policies/groot/test_groot_train_random_crop.py (8 passed:
center-crop bit-exactness with crop_position=None, corner/center windows,
cross-view replay, train!=eval, no_grad gating, seed reproducibility,
serialization contract) + groot suite 23 passed / 5 skipped on RTX PRO 6000 /
CUDA 13.3.
* docs(groot): update Training & hardware Evaluation commands
Replace the multi-GPU accelerate-launch Training snippet with the current
single-command 'uv run lerobot-train' N1.7 recipe (relative actions excluding
gripper, bf16, flash attention, chunk/n_action_steps=16, bs64/20k steps).
Replace the bimanual 'Evaluate in your hardware setup' rollout example with the
SO-101 follower RTC 'uv run lerobot-rollout' command (strategy.type=base,
inference.type=rtc, wrist+front cameras, place-the-vial task).
Docs-only; no source/test changes.
* docs(groot): parameterize commands with env vars + fill LIBERO results
- Introduce BASE_MODEL / DATASET_ID / REPO_ID / JOB_NAME / OUTPUT_DIR env vars
in the training command and reuse OUTPUT_DIR + BASE_MODEL in the rollout cmd.
- Fill the LIBERO benchmark table with GR00T-LeRobot success rates
(Spatial 94%, Object 98%, Goal 93%, LIBERO 10/Long 90%; avg 93.75%),
drop the OSS column and XX placeholders. LeRobot-focused.
* docs(groot): drop export block, reference env vars directly
Use $DATASET_ID / $BASE_MODEL / $REPO_ID / $OUTPUT_DIR / $JOB_NAME as
bare placeholders in the commands without concrete export assignments.
* docs(groot): keep BASE_MODEL export in training command
* docs(groot): use literal HF repo IDs for dataset/policy repo_id
Public-facing Hub references (--dataset.repo_id, --policy.repo_id) shown as
concrete IDs; local-only values ($OUTPUT_DIR, $JOB_NAME) stay as placeholders.
* docs(groot): add LIBERO training command example
* docs(groot): remove LIBERO checkpoints subdirectory section
* docs(groot): use $BASE_MODEL for base_model_path in LIBERO eval
* docs(groot): drop hf download step from LIBERO eval, fix intro
* docs(groot): restore suite checkpoint download intro sentence
* docs(groot): remove checkpoint download note above LIBERO eval
* docs(groot): update training and rollout commands with new parameters and dependencies
* Add sample so101 training command
* Remove sample so101 training command
* docs(groot): remove optional Flash Attention setup instructions and update base model path for evaluation
* docs(groot): update training command with image transformation parameters
* docs(groot): add note on inference.queue_threshold value for stable inference
* chore(style): pre-commit gr00t
* docs(groot): update
* chore(policies): minor details
* fix(groot): license headers + test guards
* chore(policies): fix tests
* docs(groot): relative actions param doc
* chore(policy): address some of the AI review items
---------
Co-authored-by: Andrew Wrenn <awrenn@nvidia.com>
Co-authored-by: Ryan Halabi <ryhalabi@nvidia.com>
Co-authored-by: nv-sachdevkartik <ksachdev@nvidia.com>
Co-authored-by: groot-validation <groot-validation@localhost>
Co-authored-by: johnnynunez <johnnynuca14@gmail.com>
Co-authored-by: lbenhorin <lbenhorin@nvidia.com>
208 lines
7.8 KiB
Python
208 lines
7.8 KiB
Python
#!/usr/bin/env python
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# Copyright 2026 The HuggingFace Inc. team. All rights reserved.
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#
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# Licensed under the Apache License, Version 2.0 (the "License");
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# you may not use this file except in compliance with the License.
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# You may obtain a copy of the License at
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#
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# http://www.apache.org/licenses/LICENSE-2.0
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#
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# Unless required by applicable law or agreed to in writing, software
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# distributed under the License is distributed on an "AS IS" BASIS,
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# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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# See the License for the specific language governing permissions and
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# limitations under the License.
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"""Parity test: original NVIDIA GR00T N1.7 vs the GR00T N1.7 integration in LeRobot.
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Verifies that the self-contained LeRobot reimplementation of the GR00T N1.7 action
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head + Qwen3-VL backbone produces the SAME raw model output (``action_pred``, the
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normalized flow-matching prediction before any action decoding) as NVIDIA's original
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``gr00t`` package, given byte-identical pre-processed inputs and the same
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flow-matching seed. The comparison is parametrized over every embodiment tag present
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in the checkpoint.
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To keep the comparison fair, the original outputs + the exact collated inputs are
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produced once per embodiment in the original ``gr00t`` env via the companion script
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``utils/dump_original_n1_7.py`` (in the ``utils`` package next to this file) and saved
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to per-tag ``.npz`` files.
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This test discovers those artifacts, replays the identical inputs through the LeRobot
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model, and compares.
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This test is LOCAL-only and skips on CI, when ``gr00t``-side prerequisites are not
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present, or when no artifact has been generated. By default it looks for artifacts in
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``<this dir>/artifacts/``; override with ``GROOT_N1_7_PARITY_DIR``. See the
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"Original-vs-LeRobot parity test" section of ``src/lerobot/policies/groot/README.md``
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for the full run procedure.
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"""
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import os
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from pathlib import Path
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import numpy as np
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import pytest
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import torch
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pytestmark = pytest.mark.skipif(
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os.environ.get("CI") == "true" or os.environ.get("GITHUB_ACTIONS") == "true",
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reason="Requires a local GR00T N1.7 checkpoint + pre-generated artifacts; not for CI.",
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)
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from lerobot.policies.groot.configuration_groot import GROOT_N1_7 # noqa: E402,F401
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SEED = 42
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DEVICE = os.environ.get("GROOT_PARITY_DEVICE", "cuda" if torch.cuda.is_available() else "cpu")
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ATOL = float(os.environ.get("GROOT_PARITY_ATOL", "1e-3"))
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RTOL = float(os.environ.get("GROOT_PARITY_RTOL", "1e-3"))
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# Artifact filenames are original_n1_7_<embodiment_tag>.npz
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_ARTIFACT_PREFIX = "original_n1_7_"
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_ARTIFACT_SUFFIX = ".npz"
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def _artifact_dir() -> Path:
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"""Directory holding the per-embodiment .npz artifacts.
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Self-contained by default: a sibling ``artifacts/`` directory next to this test.
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Override with ``GROOT_N1_7_PARITY_DIR`` (e.g. to point at a scratch location).
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The directory is read-only here -- it is populated by ``utils/dump_original_n1_7.py``
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run in the original gr00t environment; the test never creates it.
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"""
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env = os.environ.get("GROOT_N1_7_PARITY_DIR")
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if env:
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return Path(env)
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return Path(__file__).resolve().parent / "artifacts"
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def _discover_artifacts() -> list[tuple[str, Path]]:
|
|
"""Return [(embodiment_tag, npz_path), ...] for every dumped artifact."""
|
|
d = _artifact_dir()
|
|
if not d.is_dir():
|
|
return []
|
|
out = []
|
|
for p in sorted(d.glob(f"{_ARTIFACT_PREFIX}*{_ARTIFACT_SUFFIX}")):
|
|
tag = p.name[len(_ARTIFACT_PREFIX) : -len(_ARTIFACT_SUFFIX)]
|
|
out.append((tag, p))
|
|
return out
|
|
|
|
|
|
def _resolve_checkpoint() -> str:
|
|
env = os.environ.get("GROOT_N1_7_LIBERO_CKPT")
|
|
if env:
|
|
if not Path(env).exists():
|
|
pytest.skip(f"GROOT_N1_7_LIBERO_CKPT={env} does not exist")
|
|
return env
|
|
try:
|
|
from huggingface_hub import snapshot_download
|
|
|
|
root = snapshot_download(
|
|
"nvidia/GR00T-N1.7-LIBERO",
|
|
local_files_only=True,
|
|
allow_patterns=["libero_10/*"],
|
|
)
|
|
except Exception as exc: # noqa: BLE001
|
|
pytest.skip(f"GR00T N1.7 LIBERO checkpoint not available locally: {exc}")
|
|
ckpt = Path(root) / "libero_10"
|
|
if not (ckpt / "config.json").exists():
|
|
pytest.skip(f"GR00T N1.7 LIBERO checkpoint incomplete at {ckpt}")
|
|
return str(ckpt)
|
|
|
|
|
|
def _load_artifact(path: Path):
|
|
data = np.load(path, allow_pickle=True)
|
|
original_action = torch.from_numpy(data["action_pred"]).float()
|
|
dtypes = dict(zip(data["meta_keys"].tolist(), data["meta_dtypes"].tolist(), strict=False))
|
|
inputs = {}
|
|
for key in data.files:
|
|
if not key.startswith("in::"):
|
|
continue
|
|
name = key[4:]
|
|
arr = data[key]
|
|
t = torch.from_numpy(np.asarray(arr))
|
|
declared = dtypes.get(key, "")
|
|
if "int" in declared or "long" in declared:
|
|
t = t.long()
|
|
inputs[name] = t
|
|
return original_action, inputs
|
|
|
|
|
|
def _unflatten(inputs: dict[str, torch.Tensor]) -> dict:
|
|
"""Rebuild the nested model-input dict from dot-prefixed flat keys."""
|
|
nested: dict = {}
|
|
for dotted, value in inputs.items():
|
|
parts = dotted.split(".")
|
|
cur = nested
|
|
for p in parts[:-1]:
|
|
cur = cur.setdefault(p, {})
|
|
cur[parts[-1]] = value
|
|
return nested.get("inputs", nested)
|
|
|
|
|
|
@pytest.fixture(scope="module")
|
|
def lerobot_model():
|
|
"""Load the LeRobot GR00T N1.7 model once (fp32 + SDPA) and reuse across tags."""
|
|
ckpt = _resolve_checkpoint()
|
|
from lerobot.policies.groot.groot_n1_7 import GR00TN17
|
|
|
|
model = GR00TN17.from_pretrained(
|
|
ckpt,
|
|
tune_llm=False,
|
|
tune_visual=False,
|
|
tune_projector=False,
|
|
tune_diffusion_model=False,
|
|
tune_vlln=False,
|
|
transformers_loading_kwargs={"trust_remote_code": True},
|
|
)
|
|
# fp32 + SDPA on both sides: bf16 + differing attention kernels otherwise introduce
|
|
# ~1e-2 numerical noise unrelated to the implementations.
|
|
model.compute_dtype = "float32"
|
|
model.config.compute_dtype = model.compute_dtype
|
|
model.to(device=DEVICE, dtype=torch.float32)
|
|
model.eval()
|
|
return model
|
|
|
|
|
|
_ARTIFACTS = _discover_artifacts()
|
|
|
|
|
|
@pytest.mark.skipif(
|
|
not _ARTIFACTS,
|
|
reason=(
|
|
"No GR00T N1.7 parity artifacts found. Generate them first in the original gr00t "
|
|
"env:\n .venv-original/bin/python tests/policies/groot/utils/dump_original_n1_7.py "
|
|
"--ckpt <ckpt> --out-dir tests/policies/groot/artifacts --device cuda"
|
|
),
|
|
)
|
|
@pytest.mark.parametrize("embodiment_tag,artifact", _ARTIFACTS, ids=[t for t, _ in _ARTIFACTS])
|
|
def test_groot_get_action_parity(embodiment_tag, artifact, lerobot_model):
|
|
"""Raw model.get_action(action_pred) parity per embodiment: original vs LeRobot."""
|
|
original_action, flat_inputs = _load_artifact(artifact)
|
|
model_inputs = _unflatten(flat_inputs)
|
|
|
|
# Align the flow-matching RNG exactly as the producer did (seed right before sampling).
|
|
torch.manual_seed(SEED)
|
|
if torch.cuda.is_available():
|
|
torch.cuda.manual_seed_all(SEED)
|
|
with torch.inference_mode():
|
|
out = lerobot_model.get_action(model_inputs)
|
|
lerobot_action = out["action_pred"].float().cpu()
|
|
|
|
t = min(original_action.shape[1], lerobot_action.shape[1])
|
|
d = min(original_action.shape[2], lerobot_action.shape[2])
|
|
original_action = original_action[:, :t, :d]
|
|
lerobot_action = lerobot_action[:, :t, :d]
|
|
|
|
diff = torch.abs(lerobot_action - original_action)
|
|
max_diff = diff.max().item()
|
|
print(
|
|
f"\n[{embodiment_tag}] shapes lerobot={tuple(lerobot_action.shape)} "
|
|
f"original={tuple(original_action.shape)} "
|
|
f"max|diff|={max_diff:.6e} mean|diff|={diff.mean().item():.6e}"
|
|
)
|
|
|
|
assert torch.allclose(lerobot_action, original_action, atol=ATOL, rtol=RTOL), (
|
|
f"GR00T N1.7 raw action_pred differs for embodiment '{embodiment_tag}' beyond "
|
|
f"atol={ATOL}, rtol={RTOL}: max|diff|={max_diff:.6e}"
|
|
)
|