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💵 What is it?

Index Compression Methods (INCOME) repository helps you easily train and evaluate different memory efficient dense retrievers across any custom dataset. The pre-trained models produce float embeddings of sizes from between 512 - 1024. However, when storing a large number of embeddings within an index for fast inference, this requires quite a lot of memory / storage.

In this repository, we focus on index compression and provide models which produce binary embeddings i.e. 1 or -1 which require less dimensions and help you save both storage and money on hosting such models in a practical setup with limited money.

We currently support the following memory efficient dense retriever model architectures:

For more information, checkout our publication:

💵 Installation

One can either install income via pip

pip install income

or via source using git clone

$ git clone https://github.com/Nthakur20/income.git
$ cd income
$ pip install -e .

With that, you should be ready to go!

💵 Models Supported

We currently support training and inference of these compressed dense retrievers within our repository. We compare the performance and cost of hosting these models below:

Backbone MSMARCO BEIR Memory Size Query Time GCP Cloud Cost per. Month (in $)
No Compression
TAS-B (Hofstatter et al., 2021) TAS-B 0.408 0.415 65 GB (1x) 456.9 ms n2-highmem-8 $306.05
TAS-B + HNSW (Hofstatter et al., 2021) TAS-B 0.408 0.415 151 GB (1x) 1.8 ms n2-highmem-32 $1224.19
TAS-B + PQ (Hofstatter et al., 2021) TAS-B 0.358 0.361 2 GB (32x) 44.0 ms n1-standard-1 $24.27
Supervised Compression: BPR
BPR (TAS-B) (Thakur et al., 2022) TAS-B 0.397 0.357 2.2 GB (32x) 38.1 ms n1-standard-1 $24.27
BPR+GenQ (TAS-B) (Thakur et al., 2022) TAS-B 0.397 0.377 2.2 GB (32x) 38.1 ms n1-standard-1 $24.27
BPR+GPL (TAS-B) (Thakur et al., 2022) TAS-B 0.397 0.398 2.2 GB (32x) 38.1 ms n1-standard-1 $24.27
Supervised Compression: JPQ
JPQ (TAS-B) (Thakur et al., 2022) TAS-B (query) (doc) 0.400 0.402 2.2 GB (32x) 44.0 ms n1-standard-1 $24.27
JPQ+GenQ (TAS-B) (Thakur et al., 2022) TAS-B (query) (doc) 0.400 0.417 2.2 GB (32x) 44.0 ms n1-standard-1 $24.27
JPQ+GPL (TAS-B) (Thakur et al., 2022) TAS-B (query) (doc) 0.400 0.435 2.2 GB (32x) 44.0 ms n1-standard-1 $24.27

The scores denote the NDCG@10 performance of the model. The Index size and costs are estimated for a user who wants to build a semantic search engine over the English Wikipedia containing about 21 million passages you need to encode. Using float32 (and no further compression techniques) and 768 dimensions, the resulting embeddings have a size of about 65GB. The n2-highmem-8 server can provide upto 64 GB of memory, whereas the n1-standard-1 server can provide upto 3.75 GB of memory.

💵 Easily compress your dense retriever

Our technique can easily wrap around any HF-based dense retriever and convert them into a BPR or JPQ based model. Overall, we find the stronger the backbone dense retriever in generalization, the better the BPR and JPQ models. We recently converted these new models and made them available publicly on HF. Incase, you wish to convert your model open a pull request or follow the scripts below for BPR and JPQ seperately.

Backbone MSMARCO BEIR Memory Size Query Time GCP Cloud Cost per. Month (in $)
Supervised Compression
BPR (Contriever) (Izacard et al., 2021) Contriever 0.407 0.367 2.2 GB (32x) 38.1 ms n1-standard-1 $24.27
BPR (DPR) (Yamada et al., 2021) NQ (DPR) 0.130 0.201 2.2 GB (32x) 38.1 ms n1-standard-1 $24.27
JPQ (STAR) (Zhan et al., 2021) STAR (query) (doc) 0.402 0.389 2.2 GB (32x) 44.0 ms n1-standard-1 $24.27

💵 Using the INCOME library

The income library can be used to learn various different vector compression strategies for information retrieval. These can be used

💵 BPR Model (Getting Started)

This section would introduce few quick examples to train and evaluate BPR models on any custom data you wish to search on.

Training using GPL: Generative Pseudo Labeling

export dataset="nfcorpus"

python -m income.bpr.train \
    --path_to_generated_data "generated/$dataset" \
    --base_ckpt "msmarco-distilbert-base-tas-b" \
    --gpl_score_function "dot" \
    --batch_size_gpl 32 \
    --gpl_steps 10000 \
    --new_size -1 \
    --queries_per_passage -1 \
    --output_dir "output/$dataset" \
    --generator "BeIR/query-gen-msmarco-t5-base-v1" \
    --retrievers "msmarco-distilbert-base-tas-b" "msmarco-distilbert-base-v3" "msmarco-MiniLM-L-6-v3" \
    --retriever_score_functions "dot" "cos_sim" "cos_sim" \
    --cross_encoder "cross-encoder/ms-marco-MiniLM-L-6-v2" \
    --qgen_prefix "gen-t5-base-2-epoch-default-lr-3-ques" \
    --evaluation_data "./$dataset" \
    --evaluation_output "evaluation/$dataset" \
    --do_evaluation \
    --use_amp   # Use this for efficient training if the machine supports AMP

Inference

from beir.datasets.data_loader import GenericDataLoader
from beir.retrieval.evaluation import EvaluateRetrieval
from beir.retrieval.search.dense import BinaryFaissSearch
from beir import util
from income.bpr.model import BPR

dataset = "nfcorpus"
url = "https://public.ukp.informatik.tu-darmstadt.de/thakur/BEIR/datasets/{}.zip".format(dataset)
out_dir = os.path.join(pathlib.Path(__file__).parent.absolute(), "datasets")
data_path = util.download_and_unzip(url, out_dir)

corpus, queries, qrels = GenericDataLoader(data_folder=data_path).load(split="test")
faiss_search = BinaryFaissSearch(BPR("income/bpr-base-msmarco-distilbert-tas-b"), batch_size=128)

retriever = EvaluateRetrieval(faiss_search, score_function="dot")
results = retriever.retrieve(corpus, queries, rerank=True, binary_k=1000)
ndcg, _map, recall, precision = retriever.evaluate(qrels, results, retriever.k_values)

💵 JPQ Model (Getting Started)

This section would introduce few quick examples to train and evaluate JPQ models on any custom data you wish to search on.

Training using GPL: Generative Pseudo Labeling

Training using JPQ and GPL occurs in four steps:

  1. Preprocess Dataset to JPQ-friendly format
export dataset="nfcorpus"
export PREFIX="gen"

python -m income.jpq.beir.transform \
          --dataset ${dataset} \
          --output_dir "./datasets/${dataset}" \
          --prefix  ${PREFIX} \
  1. Preprocessing Script tokenizes the queries and corpus
CUDA_VISIBLE_DEVICES=0 python -m income.jpq.preprocess \
                                --data_dir "./datasets/${dataset}" \
                                --out_data_dir "./preprocessed/${dataset}"
    
  1. INIT script trains the IVFPQ corpus faiss index
CUDA_VISIBLE_DEVICES=0 python -m income.jpq.init \
  --preprocess_dir "./preprocessed/${dataset}" \
  --model_dir "sebastian-hofstaetter/distilbert-dot-tas_b-b256-msmarco"
  --max_doc_length 350 \
  --output_dir "./init/${dataset}" \
  --subvector_num 96
  1. TRAIN script trains TAS-B using Generative Pseudo Labeling (GPL)
CUDA_VISIBLE_DEVICES=0 python -m income.jpq.train_gpl \
    --preprocess_dir "./preprocessed/${dataset}" \
    --model_save_dir "./final_models/${dataset}/gpl" \
    --log_dir "./logs/${dataset}/log" \
    --init_index_path "./init/${dataset}/OPQ96,IVF1,PQ96x8.index" \
    --init_model_path "sebastian-hofstaetter/distilbert-dot-tas_b-b256-msmarco" \
    --data_path "./datasets/${dataset}" \
    --cross_encoder "cross-encoder/ms-marco-MiniLM-L-6-v2" \
    --lambda_cut 200 \
    --centroid_lr 1e-4 \
    --train_batch_size 32 \
    --num_train_epochs 2 \
    --gpu_search \
    --max_seq_length 64 \
    --loss_neg_topK 25
  1. Convert TAS-B trained model into JPQTower (Reqd. for inference)
python -m income.jpq.models.jpqtower_converter \
        --query_encoder_model "./final_models/${dataset}/genq/epoch-1" \
        --doc_encoder_model "sebastian-hofstaetter/distilbert-dot-tas_b-b256-msmarco" \
        --query_faiss_index "./final_models/${dataset}/genq/epoch-1/OPQ96,IVF1,PQ96x8.index" \
        --doc_faiss_index "./init/${dataset}/OPQ96,IVF1,PQ96x8.index" \
        --model_output_dir "./jpqtower/${dataset}/"

Inference

from income.jpq.models import JPQDualEncoder
from income.jpq.search import DenseRetrievalJPQSearch as DRJS
from beir.datasets.data_loader import GenericDataLoader
from beir.retrieval.evaluation import EvaluateRetrieval
from beir import util

dataset = "nfcorpus"
url = "https://public.ukp.informatik.tu-darmstadt.de/thakur/BEIR/datasets/{}.zip".format(dataset)
out_dir = os.path.join(pathlib.Path(__file__).parent.absolute(), "datasets")
data_path = util.download_and_unzip(url, out_dir)

corpus, queries, qrels = GenericDataLoader(data_folder=data_path).load(split="test")
model = DRJS(JPQDualEncoder((
    "income/jpq-question_encoder-base-msmarco-distilbert-tas-b", 
    "income/jpq-document_encoder-base-msmarco-distilbert-tas-b"
  ), backbone="distilbert"))

retriever = EvaluateRetrieval(model, score_function="dot") 
results = retriever.retrieve(corpus, queries)
ndcg, _map, recall, precision = retriever.evaluate(qrels, results, retriever.k_values)

💵 Reproduction Scripts with TAS-B

Script BEIR (Avg. NDCG@10) Memory Size
Baselines
fp-16 evaluate_fp16.py 0.414 33 GB (2x)
fp-8 evaluate_fp16.py 0.407 16 GB (4x)
PCA evaluate_pca.py 0.235 22 GB (3x)
TLDR evaluate_pca.py 0.240 22 GB (3x)
PQ evaluate_pq.py 0.361 2.2 GB (32x)
Supervised Compression
BPR bpr_beir_evaluation.py 0.357 2.2 GB (32x)
JPQ jpq_beir_evaluation.py 0.402 2.2 GB (32x)

💵 Why should we do domain adaptation?

💵 Disclaimer

For reproducibility purposes, we work with the original code repositories and modify them in INCOME if they available, for eg. BPR and JPQ. It remains the user's responsibility to determine whether you as a user have permission to use the original models and to cite the right owner of each model. Check the below table for reference.

If you're a model owner and wish to update any part of it, or do not want your model to be included in this library, feel free to post an issue here or make a pull request!

Model/Method Citation GitHub
BPR (Yamada et al., 2021) https://github.com/studio-ousia/bpr
JPQ (Zhan et al., 2021) https://github.com/jingtaozhan/JPQ
GPL (Wang et al., 2021) https://github.com/UKPLab/gpl

💵 Citing & Authors

If you find this repository helpful, feel free to cite our recent publication: Domain Adaptation for Memory-Efficient Dense Retrieval:

@article{thakur2022domain,
  title={Domain Adaptation for Memory-Efficient Dense Retrieval},
  author={Thakur, Nandan and Reimers, Nils and Lin, Jimmy},
  journal={arXiv preprint arXiv:2205.11498},
  year={2022},
  url={https://arxiv.org/abs/2205.11498/}
}

The main contributors of this repository are:

Contact person: Nandan Thakur, [email protected]

Don't hesitate to send us an e-mail or report an issue, if something is broken (and it shouldn't be) or if you have further questions.

This repository contains experimental software and is published for the sole purpose of giving additional background details on the respective publication.