SMILES-based Transformer Encoder-Decoder (SMI-TED)
This repository provides PyTorch source code associated with our publication, "A Large Encoder-Decoder Family of Foundation Models for Chemical Language".
Paper: Arxiv Link
For model weights contact: [email protected] or [email protected] .
Introduction
We present a large encoder-decoder chemical foundation model, SMILES-based Transformer Encoder-Decoder (SMI-TED), pre-trained on a curated dataset of 91 million SMILES samples sourced from PubChem, equivalent to 4 billion molecular tokens. SMI-TED supports various complex tasks, including quantum property prediction, with two main variants ($289M$ and $8 \times 289M$). Our experiments across multiple benchmark datasets demonstrate state-of-the-art performance for various tasks. For model weights contact: [email protected] or [email protected] .
Table of Contents
Getting Started
This code and environment have been tested on Nvidia V100s and Nvidia A100s
Pretrained Models and Training Logs
We provide checkpoints of the SMI-TED model pre-trained on a dataset of ~91M molecules curated from PubChem. The pre-trained model shows competitive performance on classification and regression benchmarks from MoleculeNet. For model weights contact: [email protected] or [email protected] .
Add the SMI-TED pre-trained weights.pt
to the inference/
or finetune/
directory according to your needs. The directory structure should look like the following:
inference/
βββ smi_ted_light
β βββ smi_ted_light.pt
β βββ bert_vocab_curated.txt
β βββ load.py
and/or:
finetune/
βββ smi_ted_light
β βββ smi_ted_light.pt
β βββ bert_vocab_curated.txt
β βββ load.py
Replicating Conda Environment
Follow these steps to replicate our Conda environment and install the necessary libraries:
Create and Activate Conda Environment
conda create --name smi-ted-env python=3.8.18
conda activate smi-ted-env
Install Packages with Conda
conda install pytorch=1.13.1 cudatoolkit=11.4 -c pytorch
conda install numpy=1.23.5 pandas=2.0.3
conda install rdkit=2021.03.5 -c conda-forge
Install Packages with Pip
pip install transformers==4.6.0 pytorch-fast-transformers==0.4.0 torch-optimizer==0.3.0 datasets==1.6.2 scikit-learn==1.3.2 scipy==1.12.0 tqdm==4.66.1
Pretraining
For pretraining, we use two strategies: the masked language model method to train the encoder part and an encoder-decoder strategy to refine SMILES reconstruction and improve the generated latent space.
SMI-TED is pre-trained on canonicalized and curated 91M SMILES from PubChem with the following constraints:
- Compounds are filtered to a maximum length of 202 tokens during preprocessing.
- A 95/5/0 split is used for encoder training, with 5% of the data for decoder pretraining.
- A 100/0/0 split is also used to train the encoder and decoder directly, enhancing model performance.
The pretraining code provides examples of data processing and model training on a smaller dataset, requiring 8 A100 GPUs.
To pre-train the two variants of the SMI-TED model, run:
bash training/run_model_light_training.sh
or
bash training/run_model_large_training.sh
Use train_model_D.py
to train only the decoder or train_model_ED.py
to train both the encoder and decoder.
Finetuning
The finetuning datasets and environment can be found in the finetune directory. After setting up the environment, you can run a finetuning task with:
bash finetune/smi_ted_light/esol/run_finetune_esol.sh
Finetuning training/checkpointing resources will be available in directories named checkpoint_<measure_name>
.
Feature Extraction
The example notebook smi_ted_encoder_decoder_example.ipynb contains code to load checkpoint files and use the pre-trained model for encoder and decoder tasks. It also includes examples of classification and regression tasks. For model weights contact: [email protected] or [email protected].
To load smi-ted, you can simply use:
model = load_smi_ted(
folder='../inference/smi_ted_light',
ckpt_filename='smi_ted_light.pt'
)
To encode SMILES into embeddings, you can use:
with torch.no_grad():
encoded_embeddings = model.encode(df['SMILES'], return_torch=True)
For decoder, you can use the function, so you can return from embeddings to SMILES strings:
with torch.no_grad():
decoded_smiles = model.decode(encoded_embeddings)
Citations
to include