Based is an efficient architecture inspired by recovering attention-like capabilities (i.e., recall). We do so by combining 2 simple ideas:
- Short sliding window attention (e.g., window size 64), to model fine-grained local dependencies
- "Dense" and global linear attention, to model long-range dependencies
In this way, we aim to capture the same dependencies as Transformers in a 100% subquadratic model, with exact softmax attention locally and a softmax-approximating linear attention for all other tokens. We find this helps close many of the performance gaps between Transformers and other sub-quadratic architecture proposals (matching perplexity is not all you need?).
- In this repo, please find code to (1) train new Based models and (2) evaluate existing Based checkpoints on downstream tasks.
- New Demo pretrained Based models with ThunderKittens CUDA kernels to bo brrrr!!!
Note. The code in this repository is tested on python=3.8.18
and torch=2.1.2
. We recommend using these versions in a clean environment.
# clone the repository
git clone git@github.com:HazyResearch/based.git
cd based
# install torch
pip install torch==2.1.2 torchvision==0.16.2 torchaudio==2.1.2 --index-url https://download.pytorch.org/whl/cu118 # due to observed causal-conv1d dependency
# install based package
pip install -e .
# Note that sometimes the causal-conv1d interface changes (https://github.com/state-spaces/mamba/pull/168) in case you run into an error.
We are releasing the following checkpoints for research, trained at the 360M and 1.3B parameter scales. Each checkpoint is trained on the same 10B to 50B tokens (specified below) of the Pile corpus, using the same data order. The checkpoints are trained using the same code and infrastructure. A quick start notebook is provided at notebooks/03-24-quick-start.ipynb
and further details are below:
Use the code below to load the Based checkpoints:
import torch
from transformers import AutoTokenizer
from based.models.gpt import GPTLMHeadModel
tokenizer = AutoTokenizer.from_pretrained("gpt2")
model = GPTLMHeadModel.from_pretrained_hf("hazyresearch/based-360m")
Architecture | Size | Tokens | WandB | HuggingFace | Config |
---|---|---|---|---|---|
Based | 360m | 10b | 02-20-based-360m | hazyresearch/based-360m | reference/based-360m.yaml |
Based | 1.4b | 10b | 02-21-based-1b | hazyresearch/based-1b | reference/based-1b.yaml |
Based | 1.4b | 50b | 03-31-based-1b-50b | hazyresearch/based-1b-50b | reference/based_1.3b_50b_tok.yaml |
Attention | 360m | 10b | 02-21-attn-360m | hazyresearch/attn-360m | reference/attn-360m.yaml |
Attention | 1.4b | 10b | 02-25-attn-1b | hazyresearch/attn-1b | reference/attn-360m.yaml |
Mamba | 360m | 10b | 02-21-mamba-360m | hazyresearch/mamba-360m | reference/mamba-360m.yaml |
Mamba | 1.4b | 10b | 02-22-mamba-1b | hazyresearch/mamba-1b | reference/mamba-1b.yaml |
Mamba | 1.4b | 50b | 03-31-mamba-1b-50b | hazyresearch/mamba-1b-50b | reference/mamba-1.3b_50b_tok.yaml |
Warning. We are releasing these models for the purpose of efficient architecture research. Because they have not been instruction fine-tuned or audited, they are not intended for use in any downstream applications.
The following code will run text generation for a prompt and print out the response.
input = tokenizer.encode("If I take one more step, it will be", return_tensors="pt").to("cuda")
output = model.generate(input, max_length=20)
print(tokenizer.decode(output[0]))
Note. For the checkpoints from other models, you will need to install other dependencies and use slightly different code.
To load the Attention models, use the following code:
import torch
from transformers import AutoTokenizer
from based.models.transformer.gpt import GPTLMHeadModel
tokenizer = AutoTokenizer.from_pretrained("gpt2")
model = GPTLMHeadModel.from_pretrained_hf("hazyresearch/attn-360m").to("cuda")
To use the Mamba checkpoints, first run pip install mamba-ssm
and then use the following code:
import torch
from transformers import AutoTokenizer
from based.models.mamba import MambaLMHeadModel
tokenizer = AutoTokenizer.from_pretrained("gpt2")
model = MambaLMHeadModel.from_pretrained_hf("hazyresearch/mamba-360m").to("cuda")
Follow the README.md instructions at based/train/
to train your own Based models!
In our paper, we evaluate pretrained language models on a standard suite of benchmarks from the LM Evaluation Harness, as well as a suite of three recall-intensive tasks:
- SWDE (Info. extraction). A popular information extraction benchmark for semi-structured data. SWDE includes raw HTML documents from 8 Movie and 5 University websites (e.g.IMDB, US News) and annotations for 8-274 attributes per website (e.g., Movie runtime). HuggingFace: hazyresearch/based-swde
- FDA (Info. extraction). A popular information extraction benchmark for unstructured data. The FDA setting contains 16 gold attributes and 100 PDF documents, which are up to 20 pages long, randomly sampled from FDA 510(k). HuggingFace: hazyresearch/based-fda
- SQUAD-Completion (Document-QA). We find that original SQUAD dataset is challenging for our models without instruction fine-tuning. So we introduce a modified version of SQUAD where questions are reworded as next-token prediction tasks. For example, "What is the capital of France?" becomes "The capital of France is". HuggingFace: hazyresearch/based-squad
Under evaluate
, we have a clone of EleutherAI's lm-evaluation-harness that includes these new tasks and provides scripts for running all the evaluations from the paper. The following instructions can be used to reproduce our results on the LM-Eval harness using the pretrained checkpoints.
cd evaluate
# init the submodule and install
git submodule init
git submodule update
pip install -e .
We provide a script evaluate/launch.py
that launch evaluations on the checkpoints we've released.
For example, running the following from the evaluate
folder will evaluate the 360M Based, Mamba, and Attention models on the SWDE dataset.
You can set your huggingface cache directory to a location with sufficient space (export TRANSFORMERS_CACHE
, export HF_HOME
).
python launch.py \
--task swde --task fda --task squad_completion \
--model "hazyresearch/based-360m" \
--model "hazyresearch/mamba-360m" \
--model "hazyresearch/attn-360m" \
--model "hazyresearch/based-1b" \
--model "hazyresearch/mamba-1b" \
--model "hazyresearch/attn-1b"
Optionally, if you have access to multiple GPUs, you can pass the -p
flag to run each evaluation on a different GPU.
To run a limited number of samples for each task (e.g. 100), use the --limit=100
option.
Below we include the results produced from running the command above. Note: the results below are on the new models trained and evaluated with the cleaned-up code in this repository. As a result, the results reported in our paper differ slightly, however the trends and conclusions remain the same.
Architecture | Size | HuggingFace | SWDE | FDA | SQUAD |
---|---|---|---|---|---|
Based | 360m | hazyresearch/based-360m | 25.65 | 14.34 | 24.23 |
Mamba | 360m | hazyresearch/mamba-360m | 17.28 | 5.90 | 24.83 |
Attention | 360m | hazyresearch/attn-360m | 56.26 | 57.89 | 27.85 |
Based | 1.4b | hazyresearch/attn-1b | 37.71 | 19.06 | 29.49 |
Mamba | 1.4b | hazyresearch/attn-1b | 28.35 | 11.07 | 29.42 |
Attention | 1.4b | hazyresearch/attn-1b | 69.04 | 68.87 | 35.89 |
Note that the results shown may differ slightly if the Flash-Attention kernels are not used during inference.
In our paper, we demonstrate the recall-throughput tradeoff using a synthetic associative recall task (see Figure 2, below, and Figure 3 in the paper).
The code for reproducing these figures is provided in a separate repository: HazyResearch/zoology. Follow the setup instruction in the Zoology README. The instructions for reproducing the are provided in zoology/experiments. For example, you can create the figure above using.
python -m zoology.launch zoology/experiments/arxiv24_based_figure2/configs.py -p
Try out Based models with speedy ThunderKittens kernels!
git submodule init
git submodule update
cd ThunderKittens/demos/based_demos
Enjoy!
This repo contains work based on the following papers. Please consider citing if you found the work or code useful:
@article{arora2024simple,
title={Simple linear attention language models balance the recall-throughput tradeoff},
author={Arora, Simran and Eyuboglu, Sabri and Zhang, Michael and Timalsina, Aman and Alberti, Silas and Zinsley, Dylan and Zou, James and Rudra, Atri and Ré, Christopher},
journal={arXiv:2402.18668},
year={2024}
}
@article{zhang2024hedgehog,
title={The Hedgehog \& the Porcupine: Expressive Linear Attentions with Softmax Mimicry},
author={Zhang, Michael and Bhatia, Kush and Kumbong, Hermann and R{\'e}, Christopher},
journal={arXiv preprint arXiv:2402.04347},
year={2024}
}
@article{arora2023zoology,
title={Zoology: Measuring and Improving Recall in Efficient Language Models},
author={Arora, Simran and Eyuboglu, Sabri and Timalsina, Aman and Johnson, Isys and Poli, Michael and Zou, James and Rudra, Atri and Ré, Christopher},
journal={arXiv:2312.04927},
year={2023}
}
This project was made possible by a number of other open source projects; please cite if you use their work! Notably:
- Our training code and sliding window implementation are based on Tri Dao's FlashAttention.
- We use EleutherAI's lm-evaluation-harness for evaluation.
- We use the conv1d kernel from Mamba.
- We integrated the causal dot product kernel from Fast Transformers.
- We integrated the based kernels from Flash Linear Attention.
Models in this project were trained using compute provided by:
- Together.ai
- Google Cloud Platform through Stanford HAI
Please reach out with feedback and questions!