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Benchmarks of approximate nearest neighbor libraries in Python

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Benchmarking nearest neighbors

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Doing fast searching of nearest neighbors in high dimensional spaces is an increasingly important problem with notably few empirical attempts at comparing approaches in an objective way, despite a clear need for such to drive optimization forward.

This project contains tools to benchmark various implementations of approximate nearest neighbor (ANN) search for selected metrics. We have pre-generated datasets (in HDF5 format) and prepared Docker containers for each algorithm, as well as a test suite to verify function integrity.

Evaluated

Data sets

We have a number of precomputed data sets in HDF5 format. All data sets have been pre-split into train/test and include ground truth data for the top-100 nearest neighbors.

Dataset Dimensions Train size Test size Neighbors Distance Download
DEEP1B 96 9,990,000 10,000 100 Angular HDF5 (3.6GB)
Fashion-MNIST 784 60,000 10,000 100 Euclidean HDF5 (217MB)
GIST 960 1,000,000 1,000 100 Euclidean HDF5 (3.6GB)
GloVe 25 1,183,514 10,000 100 Angular HDF5 (121MB)
GloVe 50 1,183,514 10,000 100 Angular HDF5 (235MB)
GloVe 100 1,183,514 10,000 100 Angular HDF5 (463MB)
GloVe 200 1,183,514 10,000 100 Angular HDF5 (918MB)
Kosarak 27,983 74,962 500 100 Jaccard HDF5 (33MB)
MNIST 784 60,000 10,000 100 Euclidean HDF5 (217MB)
MovieLens-10M 65,134 69,363 500 100 Jaccard HDF5 (63MB)
NYTimes 256 290,000 10,000 100 Angular HDF5 (301MB)
SIFT 128 1,000,000 10,000 100 Euclidean HDF5 (501MB)
Last.fm 65 292,385 50,000 100 Angular HDF5 (135MB)

Results

These are all as of April 2023, running all benchmarks on a r6i.16xlarge machine on AWS with --parallelism 31 and hyperthreading disabled. All benchmarks are single-CPU.

glove-100-angular

glove-100-angular

sift-128-euclidean

glove-100-angular

fashion-mnist-784-euclidean

fashion-mnist-784-euclidean

nytimes-256-angular

nytimes-256-angular

gist-960-euclidean

gist-960-euclidean

glove-25-angular

glove-25-angular

TODO: update plots on http://ann-benchmarks.com.

Install

The only prerequisite is Python (tested with 3.10.6) and Docker.

  1. Clone the repo.
  2. Run pip install -r requirements.txt.
  3. Run python install.py to build all the libraries inside Docker containers (this can take a while, like 10-30 minutes).

Running

  1. Run python run.py (this can take an extremely long time, potentially days)
  2. Run python plot.py or python create_website.py to plot results.
  3. Run python data_export.py --out res.csv to export all results into a csv file for additional post-processing.

You can customize the algorithms and datasets as follows:

  • Check that ann_benchmarks/algorithms/{YOUR_IMPLEMENTATION}/config.yml contains the parameter settings that you want to test
  • To run experiments on SIFT, invoke python run.py --dataset glove-100-angular. See python run.py --help for more information on possible settings. Note that experiments can take a long time.
  • To process the results, either use python plot.py --dataset glove-100-angular or python create_website.py. An example call: python create_website.py --plottype recall/time --latex --scatter --outputdir website/.

Including your algorithm

Add your algorithm in the folder ann_benchmarks/algorithms/{YOUR_IMPLEMENTATION}/ by providing

  • A small Python wrapper in module.py
  • A Dockerfile named Dockerfile
  • A set of hyper-parameters in config.yml
  • A CI test run by adding your implementation to .github/workflows/benchmarks.yml

Check the available implementations for inspiration.

Principles

  • Everyone is welcome to submit pull requests with tweaks and changes to how each library is being used.
  • In particular: if you are the author of any of these libraries, and you think the benchmark can be improved, consider making the improvement and submitting a pull request.
  • This is meant to be an ongoing project and represent the current state.
  • Make everything easy to replicate, including installing and preparing the datasets.
  • Try many different values of parameters for each library and ignore the points that are not on the precision-performance frontier.
  • High-dimensional datasets with approximately 100-1000 dimensions. This is challenging but also realistic. Not more than 1000 dimensions because those problems should probably be solved by doing dimensionality reduction separately.
  • Single queries are used by default. ANN-Benchmarks enforces that only one CPU is saturated during experimentation, i.e., no multi-threading. A batch mode is available that provides all queries to the implementations at once. Add the flag --batch to run.py and plot.py to enable batch mode.
  • Avoid extremely costly index building (more than several hours).
  • Focus on datasets that fit in RAM. For billion-scale benchmarks, see the related big-ann-benchmarks project.
  • We mainly support CPU-based ANN algorithms. GPU support exists for FAISS, but it has to be compiled with GPU support locally and experiments must be run using the flags --local --batch.
  • Do proper train/test set of index data and query points.
  • Note that we consider that set similarity datasets are sparse and thus we pass a sorted array of integers to algorithms to represent the set of each user.

Authors

Built by Erik Bernhardsson with significant contributions from Martin Aumüller and Alexander Faithfull.

Related Publication

Design principles behind the benchmarking framework are described in the following publications:

Related Projects

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