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TaPA

TaPA

TaPA

Official implementation of Embodied Task Planning with Large Language Models.

Try out the web demo 🤗 of TaPA: Hugging Face Spaces

The repository contains:

News

  • [2023.07.04] The training code for TaPA are released. 📌

Overview

The pipeline of our embodied task planning framwork. We first collect multiple RGB images in different achivable standing points and views, and utilize an open-voculary detector to generate the list of existing objects in the scene. With the human instructions and predicted object list, our TaPA can generate executable action plans for subsequent navigation or manipulation robots.

Setup

Here is a from-scratch script for TaPA.

# Install Lit-LLaMA
conda create -n tapa python=3.10
conda activate tapa
git clone https://github.com/Gary3410/TaPA.git
cd TaPA
pip install -r requirements.txt
# If you want to utilize more than one GPU
pip install deepspeed
If you have problems with the installation, you can follow these steps
  1. conda create -n tapa python=3.10
  2. conda activate tapa
  3. git clone https://github.com/Gary3410/tapa
  4. cd TaPA
  5. pip install torch==2.0.0+cu117 torchvision==0.15.1+cu117 torchaudio==2.0.1 --index-url https://download.pytorch.org/whl/cu117
  6. pip install sentencepiece
  7. pip install tqdm
  8. pip install numpy
  9. pip install jsonargparse[signatures]
  10. pip install bitsandbytes
  11. pip install datasets
  12. pip install zstandard
  13. pip install lightning==2.1.0.dev0
  14. pip install deepspeed
# Install Detic
# Exit the TaPA file first
cd ..
git clone [email protected]:facebookresearch/detectron2.git
cd detectron2
pip install -e .

cd ..
git clone https://github.com/facebookresearch/Detic.git --recurse-submodules
cd Detic
pip install -r requirements.txt

Note: If you have any problems with the installation, you can refer to Detic_INSTALL.md Meanwhile, you also need to download the appropriate pre-trained model and put the weights into the models folder.

Once the installation is complete, we need to copy the files from Detic to the tapa directory.

The TaPA file directory should be:

TaPA
├── checkpoints
│   ├── lit-llama
│   ├── llama
├── configs 
├── create_dataset
├── data
├── datasets
├── detic
├── docs
├── evaluate
├── finetune
├── generate
├── howto
├── lit-llama
├── models
│   ├── Detic_LCOCOI21k_CLIP_SwinB_896b32_4x_ft4x_max-size.pth
├── pretrain
├── quantize
├── scripts
├── tests
├── third_party
│   ├── CenterNet2
│   ├── Deformable-DETR
├── tools
......

If you want to make your own dataset, please install the openAI API and AI2-THOR.

# Install OpenAI API
pip install openai
# If there is a communication error, please try
pip install urllib3==1.25.11

# Install AI2THOR
pip install ai2thor

# If this is your first installation, please run
python prepare_thor.py
# to download the necessary scene resources

For more details on the installation and usage of AI2-THOR, please visit AI2-THOR.

Data Release

alpaca_15k_instruction.json contains 15K instruction-following data we used for fine-tuning the LLaMA-7B model.

The format is the same as Aplaca. Each dictionary contains the following fields:

  • instruction: str, instructions given by the user, e.g., Please give me a cup of coffee.
  • input: str, categories of objects contained in the scene.
  • output: str, the step-by-step actions to the instruction as generated by gpt-3.5-turbo-0301.

As for the prompts, we used the prompts proposed by Alpaca directly.

Of course, we can also modify the prompts from Alpaca a bit, such as:

 Below is an instruction that describes a task, paired with an input that provides further context. Write a response that appropriately completes the request and list each step to finish the instruction.
 
 ### Instruction:
 {instruction}
 
 ### Input:
 {input}
 
 ### Response:

Training and inference stages keep the same prompts.

Data Generation Process

This is an example of making a dataset in AI2THOR.

If you need to make your own dataset, the easiest way is to modify the way the object list is generated.

# Create object list from AI2THOR scenes
cd create_dataset
python create_scene_obj_list.py
python create_json_data.py
python create_gpt_respond.py
python prase_json_2_alpaca.py

After running the above code, you will get the file alpaca_15k_instruction.json which contains almost 15K instructions.

We performed preliminary statistics on the dataset and found that the instructions generated by GPT-3.5 are more diverse and complex.

We plot the following graph to show the diversity of our data, with the inner circle being the root verb in the instruction and the outer circle representing the direct object in the instruction.

Meanwhile, we also count the average number of actions required by the Top7 instructions to demonstrate the complexity.

Fine-tuning

We fine-tune the LLaMA-7B model on alpaca_15k_instruction.json according to the script provided by Lit-LLaMA.

Prepare LLaMA-7B model

Please request access to the pre-trained LLaMA from this form (official) or download the LLaMA-7B from Hugging Face (unofficial).

Then, put them in the checkpoints directory.

TaPA
├── checkpoints
│   ├── lit-llama
│   ├── llama
│   │   ├── 7B
│   │   │   ├── checklist.chk
│   │   │   ├── consolidated.00.pth
│   │   │   ├── params.json
│   │   ├── tokenizer.model

Convert the weights to the Lit-LLaMA format:

python scripts/convert_checkpoint.py --model_size 7B

Once converted, you should have a folder like this:

TaPA
├── checkpoints
│   ├── lit-llama
│   │   ├── 7B
│   │   │   ├── lit-llama.pth
│   │   ├── tokenizer.model
│   ├── llama
│   │   ├── 7B
│   │   │   ├── checklist.chk
│   │   │   ├── consolidated.00.pth
│   │   │   ├── params.json
│   │   ├── tokenizer.model

Prepare dataset

Generate the Alpaca format instruction tuning dataset:

python scripts/prepare_alpaca.py

Running the finetuning

The finetuning requires at least one GPU with ~24 GB memory (RTX 3090). You can speed up training by setting the devices variable in the script to utilize more GPUs if available.

Here are some parameter settings.

devices = 2
micro_batch_size = 8

# GPU memory limit
devices = 8
micro_batch_size = 2
# Use 2 GPUs
CUDA_VISIBLE_DEVICES=0,1 python finetune/adapter.py
# Use 8 GPUs
CUDA_VISIBLE_DEVICES=0,1,2,3,4,5,6,7 python finetune/adapter.py

Running the inference

You can test the finetuned model with your own instructions by running:

python generate/adapter_robot.py \
    --prompt "Can you prepare me a sandwich?" \
    --quantize llm.int8 \
    --max_new_tokens 512 \
    --input "[Cabinet, PaperTowelRoll, Cup, ButterKnife, Shelf, Bowl, Fridge, CounterTop, Drawer, Potato, DishSponge, Bread, Statue, Spoon, SoapBottle, ShelvingUnit, HousePlant, Sink, Fork, Spatula, GarbageCan, Plate, Pot, Blinds, Kettle, Lettuce,Stool, Vase, Tomato, Mug, StoveBurner, StoveKnob, CoffeeMachine, LightSwitch, Toaster, Microwave, Ladle, SaltShaker, Apple, PepperShaker]"

You can also take several scene images and save them to ./input/rgb_img directory and use Detic to generate a list of scene objects.

python generate/adapter_with_detic.py \
    --prompt "Can you open the computer?" \
    --max_new_tokens 512 \
    --img_path input/rgb_img

Running the validation

If you want to try to get results on the validation set, need to prepare the validation set first.

# Creating multi-modal validation set
python create_partial_vision_dataset.py
python create_vision_dataset.py

The default validation set instructions are stored in alpaca_20_val_instruction.json.

If you want to create your own validation set, you can perform the dataset generation process again based on alpaca_20_val.json

Once the validation set generation is complete, run:

python generate/adapter_detic_robot_eval_random.py --navigation_strategy Select one of the random strategies
python generate/adapter_detic_robot_eval_traversal.py --navigation_strategy Select one of the traversal strategies

Omnigibson preparation

python docker_build.py
./run_docker.sh -h <ABS_DATA_PATH>

Contributors

All grad students below contributed equally and the order is determined by random draw.

All advised by Jiwen Lu. Zhenyu Wu is also advised by Haibin Yan.

Acknowledgement

This repo benefits from AI2THOR, LLaMA, Stanford Alpaca, Detic, and Lit-LLaMA. Thanks for their wonderful works.