This repository contains the code for our paper, Learning Transformer Programs. The code can be used to train a modified Transformer to solve a task, and then convert it into a human-readable Python program. The repository also includes a number of example programs, which we learned for the tasks described in the paper. Please see our paper for more details.
Install PyTorch and then install the remaining requirements: pip install -r requirements.txt.
This code was tested using Python 3.8 and PyTorch version 1.13.1.
In our experiments on NLP tasks, we initialize word embeddings using 300-dimensional pre-trained GloVe embeddings, which can be downloaded here (Common Crawl, cased):
mkdir data
wget https://huggingface.co/stanfordnlp/glove/resolve/main/glove.840B.300d.zip -P data/
unzip data/glove.840B.300d.zipThe code to learn a Transformer Program can be found in src/run.py.
For example, the following command will train a Transformer Program for the sort task, using two layers, four categorical attention heads per-layer, and one-hot input embeddings:
python src/run.py \
--dataset "sort" \
--vocab_size 8 \
--dataset_size 10000 \
--min_length 1 \
--max_length 8 \
--n_epochs 250 \
--batch_size 512 \
--lr "5e-2" \
--n_layers 2 \
--n_heads_cat 4 \
--n_heads_num 0 \
--n_cat_mlps 1 \
--n_num_mlps 0 \
--one_hot_embed \
--count_only \
--seed 0 \
--save \
--save_code \
--output_dir "output/sort";This command will train a Transformer Program for the CoNLL 2003 named-entity recognition task, learning input embeddings composed of four 32-dimensional categorical variables:
python src/run.py \
--dataset "conll_ner" \
--vocab_size 10000 \
--min_length 1 \
--max_length 32 \
--n_epochs 50 \
--batch_size 32 \
--lr "5e-2" \
--n_vars_cat 4 \
--d_var 32 \
--n_layers 2 \
--n_heads_cat 4 \
--n_heads_num 0 \
--n_cat_mlps 1 \
--n_num_mlps 0 \
--mlp_vars_in 2 \
--count_only \
--seed 0 \
--replace_numbers 1 \
--glove_embeddings "data/glove.840B.300d.txt" \
--do_glove 1 \
--save \
--save_code \
--output_dir "output/conll";Please see src/run.py for all of the possible arguments. The training data will either be generated (for the RASP tasks) or downloaded from Hugging Face Datasets; see src/utils/data_utils.py for the supported datasets. The scripts directory contains scripts for training Transformer Programs and standard Transformers with the experiment settings used in the paper.
Run the training script with the --save_code flag to convert the model to a Python program at the end of training.
To convert a model that has already been trained, use src/decompile.py.
For example,
python src/decompile.py --path output/sort/ --output_dir programs/sort/output/sort/ should be the output directory of a training run.
The programs directory contains example programs for small-scale versions of all of the RASP tasks, as well as named-entity recognition.
Each program defines a function called run that takes a sequence of tokens as input and returns a list of predicted labels.
For example:
>>> from programs.rasp.sort import sort
>>> sort.run(["<s>", "3", "1", "4", "2", "4", "0", "</s>"])
['<s>', '0', '1', '2', '3', '4', '4', '</s>']programs/rasp contains the best-performing programs for each task, using both categorical and numerical attention heads. programs/rasp_categorical_only contains the best-performing programs using only categorical variables. programs/conll_ner contains a program for named-entity recognition.
If you have any questions about the code or paper, please email Dan (dfriedman@cs.princeton.edu) or open an issue.
@inproceedings{
friedman2023learning,
title={Learning Transformer Programs},
author={Dan Friedman and Alexander Wettig and Danqi Chen},
booktitle={Thirty-seventh Conference on Neural Information Processing Systems},
year={2023},
url={https://openreview.net/forum?id=Pe9WxkN8Ff}
}