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02_finetune_new_observation_action.py
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02_finetune_new_observation_action.py
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"""
This script demonstrates how to finetune Octo to a new observation space (single camera + proprio)
and new action space (bimanual) using a simulated ALOHA cube handover dataset (https://tonyzhaozh.github.io/aloha/).
To run this example, first download and extract the dataset from here: https://rail.eecs.berkeley.edu/datasets/example_sim_data.zip
python examples/02_finetune_new_observation_action.py --pretrained_path=hf://rail-berkeley/octo-small --data_dir=...
"""
from absl import app, flags, logging
import flax
import jax
import optax
import tensorflow as tf
import tqdm
import wandb
from octo.data.dataset import make_single_dataset
from octo.data.utils.data_utils import NormalizationType
from octo.model.components.action_heads import L1ActionHead
from octo.model.components.tokenizers import LowdimObsTokenizer
from octo.model.octo_model import OctoModel
from octo.utils.jax_utils import initialize_compilation_cache
from octo.utils.spec import ModuleSpec
from octo.utils.train_utils import (
freeze_weights,
merge_params,
process_text,
TrainState,
)
FLAGS = flags.FLAGS
flags.DEFINE_string(
"pretrained_path", None, "Path to pre-trained Octo checkpoint directory."
)
flags.DEFINE_string("data_dir", None, "Path to finetuning dataset, in RLDS format.")
flags.DEFINE_string("save_dir", None, "Directory for saving finetuning checkpoints.")
flags.DEFINE_integer("batch_size", 128, "Batch size for finetuning.")
flags.DEFINE_bool(
"freeze_transformer",
False,
"Whether pre-trained transformer weights should be frozen.",
)
def main(_):
assert (
FLAGS.batch_size % jax.device_count() == 0
), "Batch size must be divisible by device count."
initialize_compilation_cache()
# prevent tensorflow from using GPU memory since it's only used for data loading
tf.config.set_visible_devices([], "GPU")
# setup wandb for logging
wandb.init(name="finetune_aloha", project="octo")
# load pre-trained model
logging.info("Loading pre-trained model...")
pretrained_model = OctoModel.load_pretrained(FLAGS.pretrained_path)
# make finetuning dataset
# apply Gaussian normalization, load chunks of 50 actions since we'll train with action chunking
# delete goal images in the data loader since we will train a language-conditioned-only policy
# TODO: directly load this from raw data to make it less opaque?
logging.info("Loading finetuning dataset...")
dataset = make_single_dataset(
dataset_kwargs=dict(
name="aloha_sim_cube_scripted_dataset",
data_dir=FLAGS.data_dir,
image_obs_keys={"primary": "top"},
state_obs_keys=["state"],
language_key="language_instruction",
action_proprio_normalization_type=NormalizationType.NORMAL,
absolute_action_mask=[True] * 14,
),
traj_transform_kwargs=dict(
window_size=1,
future_action_window_size=49, # so we get 50 actions for our action chunk
),
frame_transform_kwargs=dict(
resize_size={"primary": (256, 256)},
),
train=True,
)
train_data_iter = (
dataset.repeat()
.unbatch()
.shuffle(10000) # can reduce this if RAM consumption too high
.batch(FLAGS.batch_size)
.iterator()
)
# run text tokenizer over batch (this needs to happen before training / sharding) + delete unused keys
text_processor = pretrained_model.text_processor
def process_batch(batch):
batch = process_text(batch, text_processor)
del batch["dataset_name"]
return batch
train_data_iter = map(process_batch, train_data_iter)
example_batch = next(train_data_iter)
# load pre-training config and modify --> remove wrist cam, add proprio input, change action head
# following Zhao et al. we use "action chunks" of length 50 and L1 loss for ALOHA
config = pretrained_model.config
del config["model"]["observation_tokenizers"]["wrist"]
###
config["model"]["observation_tokenizers"]["proprio"] = ModuleSpec.create(
LowdimObsTokenizer,
n_bins=256,
bin_type="normal",
low=-2.0,
high=2.0,
obs_keys=["proprio"],
)
# Fully override the old action head with a new one (for smaller changes, you can use update_module_config)
config["model"]["heads"]["action"] = ModuleSpec.create(
L1ActionHead,
pred_horizon=50,
action_dim=14,
readout_key="readout_action",
)
# initialize weights for modified Octo model, then merge in all applicable pre-trained weights
# new position encodings for proprio inputs & weights for new action head will remain "from scratch"
logging.info("Updating model for new observation & action space...")
model = OctoModel.from_config(
config,
example_batch,
text_processor,
verbose=True,
dataset_statistics=dataset.dataset_statistics,
)
merged_params = merge_params(model.params, pretrained_model.params)
# can perform any additional parameter surgery here...
# ...
model = model.replace(params=merged_params)
del pretrained_model
# create optimizer & train_state, optionally freeze keys for pre-trained transformer
# train_state bundles parameters & optimizers
learning_rate = optax.join_schedules(
[optax.linear_schedule(0, 3e-5, 100), optax.constant_schedule(3e-5)], [100]
)
tx = optax.adamw(learning_rate)
frozen_keys = model.config["optimizer"]["frozen_keys"]
if FLAGS.freeze_transformer:
frozen_keys.append("BlockTransformer_0")
tx = freeze_weights(tx, model.params, frozen_keys)
train_state = TrainState.create(
rng=jax.random.PRNGKey(1234),
model=model,
tx=tx,
)
# define loss function and train step
def loss_fn(params, batch, rng, train=True):
bound_module = model.module.bind({"params": params}, rngs={"dropout": rng})
transformer_embeddings = bound_module.octo_transformer(
batch["observation"],
batch["task"],
batch["observation"]["pad_mask"],
train=train,
)
action_loss, action_metrics = bound_module.heads["action"].loss(
transformer_embeddings, # Action head knows to pull out the action readout_key
batch["action"],
pad_mask=batch["observation"]["pad_mask"],
train=train,
)
return action_loss, action_metrics
@jax.jit
def train_step(state, batch):
rng, dropout_rng = jax.random.split(state.rng)
(loss, info), grads = jax.value_and_grad(loss_fn, has_aux=True)(
state.model.params, batch, dropout_rng, train=True
)
new_state = state.apply_gradients(grads=grads, rng=rng)
return new_state, info
# run finetuning loop
logging.info("Starting finetuning...")
for i in tqdm.tqdm(range(5000), total=5000, dynamic_ncols=True):
batch = next(train_data_iter)
train_state, update_info = train_step(train_state, batch)
if (i + 1) % 100 == 0:
update_info = jax.device_get(update_info)
wandb.log(
flax.traverse_util.flatten_dict({"training": update_info}, sep="/"),
step=i,
)
if (i + 1) % 1000 == 0:
# save checkpoint
train_state.model.save_pretrained(step=i, checkpoint_path=FLAGS.save_dir)
if __name__ == "__main__":
app.run(main)