# RAFT ANN Benchmarks This project provides a benchmark program for various ANN search implementations. It's especially suitable for comparing GPU implementations as well as comparing GPU against CPU. ## Table of Contents - [Installing the benchmarks](#installing-the-benchmarks) - [Conda](#conda) - [Docker](#docker) - [How to run the benchmarks](#how-to-run-the-benchmarks) - [Step 1: prepare dataset](#step-1-prepare-dataset) - [Step 2: build and search index](#step-2-build-and-search-index) - [Step 3: data export](#step-3-data-export) - [Step 4: plot results](#step-4-plot-results) - [Running the benchmarks](#running-the-benchmarks) - [End to end: small-scale (<1M to 10M)](#end-to-end-small-scale-benchmarks-1m-to-10m) - [End to end: large-scale (>10M)](#end-to-end-large-scale-benchmarks-10m-vectors) - [Running with Docker containers](#running-with-docker-containers) - [Evaluating the results](#evaluating-the-results) - [Creating and customizing dataset configurations](#creating-and-customizing-dataset-configurations) - [Adding a new ANN algorithm](#adding-a-new-ann-algorithm) - [Parameter tuning guide](https://docs.rapids.ai/api/raft/nightly/ann_benchmarks_param_tuning/) - [Wiki-all RAG/LLM Dataset](https://docs.rapids.ai/api/raft/nightly/wiki_all_dataset/) ## Installing the benchmarks There are two main ways pre-compiled benchmarks are distributed: - [Conda](#Conda): For users not using containers but want an easy to install and use Python package. Pip wheels are planned to be added as an alternative for users that cannot use conda and prefer to not use containers. - [Docker](#Docker): Only needs docker and [NVIDIA docker](https://github.com/NVIDIA/nvidia-docker) to use. Provides a single docker run command for basic dataset benchmarking, as well as all the functionality of the conda solution inside the containers. ## Conda If containers are not an option or not preferred, the easiest way to install the ANN benchmarks is through conda. We provide packages for GPU enabled systems, as well for systems without a GPU. We suggest using mamba as it generally leads to a faster install time: ```bash mamba create --name raft_ann_benchmarks conda activate raft_ann_benchmarks # to install GPU package: mamba install -c rapidsai -c conda-forge -c nvidia raft-ann-bench= cuda-version=11.8* # to install CPU package for usage in CPU-only systems: mamba install -c rapidsai -c conda-forge raft-ann-bench-cpu ``` The channel `rapidsai` can easily be substituted `rapidsai-nightly` if nightly benchmarks are desired. The CPU package currently allows to run the HNSW benchmarks. Please see the [build instructions](ann_benchmarks_build.md) to build the benchmarks from source. ## Docker We provide images for GPU enabled systems, as well as systems without a GPU. The following images are available: - `raft-ann-bench`: Contains GPU and CPU benchmarks, can run all algorithms supported. Will download million-scale datasets as required. Best suited for users that prefer a smaller container size for GPU based systems. Requires the NVIDIA Container Toolkit to run GPU algorithms, can run CPU algorithms without it. - `raft-ann-bench-datasets`: Contains the GPU and CPU benchmarks with million-scale datasets already included in the container. Best suited for users that want to run multiple million scale datasets already included in the image. - `raft-ann-bench-cpu`: Contains only CPU benchmarks with minimal size. Best suited for users that want the smallest containers to reproduce benchmarks on systems without a GPU. Nightly images are located in [dockerhub](https://hub.docker.com/r/rapidsai/raft-ann-bench/tags), meanwhile release (stable) versions are located in [NGC](https://hub.docker.com/r/rapidsai/raft-ann-bench), starting with release 23.12. - The following command pulls the nightly container for python version 10, cuda version 12, and RAFT version 23.10: ```bash docker pull rapidsai/raft-ann-bench:24.08a-cuda12.0-py3.10 #substitute raft-ann-bench for the exact desired container. ``` The CUDA and python versions can be changed for the supported values: Supported CUDA versions: 11.2 and 12.0 Supported Python versions: 3.9 and 3.10. You can see the exact versions as well in the dockerhub site: - [RAFT ANN Benchmark images](https://hub.docker.com/r/rapidsai/raft-ann-bench/tags) - [RAFT ANN Benchmark with datasets preloaded images](https://hub.docker.com/r/rapidsai/raft-ann-bench-cpu/tags) - [RAFT ANN Benchmark CPU only images](https://hub.docker.com/r/rapidsai/raft-ann-bench-datasets/tags) **Note:** GPU containers use the CUDA toolkit from inside the container, the only requirement is a driver installed on the host machine that supports that version. So, for example, CUDA 11.8 containers can run in systems with a CUDA 12.x capable driver. Please also note that the Nvidia-Docker runtime from the [Nvidia Container Toolkit](https://github.com/NVIDIA/nvidia-docker) is required to use GPUs inside docker containers. [//]: # (- The following command (only available after RAPIDS 23.10 release) pulls the container:) [//]: # () [//]: # (```bash) [//]: # (docker pull nvcr.io/nvidia/rapidsai/raft-ann-bench:24.08-cuda11.8-py3.10 #substitute raft-ann-bench for the exact desired container.) [//]: # (```) ## How to run the benchmarks We provide a collection of lightweight Python scripts to run the benchmarks. There are 4 general steps to running the benchmarks and visualizing the results. 1. Prepare Dataset 2. Build Index and Search Index 3. Data Export 4. Plot Results ### Step 1: Prepare Dataset The script `raft_ann_bench.get_dataset` will download and unpack the dataset in directory that the user provides. As of now, only million-scale datasets are supported by this script. For more information on [datasets and formats](ann_benchmarks_dataset.md). The usage of this script is: ```bash usage: get_dataset.py [-h] [--name NAME] [--dataset-path DATASET_PATH] [--normalize] options: -h, --help show this help message and exit --dataset DATASET dataset to download (default: glove-100-angular) --dataset-path DATASET_PATH path to download dataset (default: ${RAPIDS_DATASET_ROOT_DIR}) --normalize normalize cosine distance to inner product (default: False) ``` When option `normalize` is provided to the script, any dataset that has cosine distances will be normalized to inner product. So, for example, the dataset `glove-100-angular` will be written at location `datasets/glove-100-inner/`. ### Step 2: Build and Search Index The script `raft_ann_bench.run` will build and search indices for a given dataset and its specified configuration. The usage of the script `raft_ann_bench.run` is: ```bash usage: __main__.py [-h] [--subset-size SUBSET_SIZE] [-k COUNT] [-bs BATCH_SIZE] [--dataset-configuration DATASET_CONFIGURATION] [--configuration CONFIGURATION] [--dataset DATASET] [--dataset-path DATASET_PATH] [--build] [--search] [--algorithms ALGORITHMS] [--groups GROUPS] [--algo-groups ALGO_GROUPS] [-f] [-m SEARCH_MODE] options: -h, --help show this help message and exit --subset-size SUBSET_SIZE the number of subset rows of the dataset to build the index (default: None) -k COUNT, --count COUNT the number of nearest neighbors to search for (default: 10) -bs BATCH_SIZE, --batch-size BATCH_SIZE number of query vectors to use in each query trial (default: 10000) --dataset-configuration DATASET_CONFIGURATION path to YAML configuration file for datasets (default: None) --configuration CONFIGURATION path to YAML configuration file or directory for algorithms Any run groups found in the specified file/directory will automatically override groups of the same name present in the default configurations, including `base` (default: None) --dataset DATASET name of dataset (default: glove-100-inner) --dataset-path DATASET_PATH path to dataset folder, by default will look in RAPIDS_DATASET_ROOT_DIR if defined, otherwise a datasets subdirectory from the calling directory (default: os.getcwd()/datasets/) --build --search --algorithms ALGORITHMS run only comma separated list of named algorithms. If parameters `groups` and `algo-groups are both undefined, then group `base` is run by default (default: None) --groups GROUPS run only comma separated groups of parameters (default: base) --algo-groups ALGO_GROUPS add comma separated . to run. Example usage: "--algo-groups=raft_cagra.large,hnswlib.large" (default: None) -f, --force re-run algorithms even if their results already exist (default: False) -m SEARCH_MODE, --search-mode SEARCH_MODE run search in 'latency' (measure individual batches) or 'throughput' (pipeline batches and measure end-to-end) mode (default: throughput) -t SEARCH_THREADS, --search-threads SEARCH_THREADS specify the number threads to use for throughput benchmark. Single value or a pair of min and max separated by ':'. Example --search-threads=1:4. Power of 2 values between 'min' and 'max' will be used. If only 'min' is specified, then a single test is run with 'min' threads. By default min=1, max=. (default: None) -r, --dry-run dry-run mode will convert the yaml config for the specified algorithms and datasets to the json format that's consumed by the lower-level c++ binaries and then print the command to run execute the benchmarks but will not actually execute the command. (default: False) ``` `dataset`: name of the dataset to be searched in [datasets.yaml](#yaml-dataset-config) `dataset-configuration`: optional filepath to custom dataset YAML config which has an entry for arg `dataset` `configuration`: optional filepath to YAML configuration for an algorithm or to directory that contains YAML configurations for several algorithms. [Here's how to configure an algorithm.](#yaml-algo-config) `algorithms`: runs all algorithms that it can find in YAML configs found by `configuration`. By default, only `base` group will be run. `groups`: run only specific groups of parameters configurations for an algorithm. Groups are defined in YAML configs (see `configuration`), and by default run `base` group `algo-groups`: this parameter is helpful to append any specific algorithm+group combination to run the benchmark for in addition to all the arguments from `algorithms` and `groups`. It is of the format `.`, or for example, `raft_cagra.large` For every algorithm run by this script, it outputs an index build statistics JSON file in `/result/build/<{algo},{group}.json>` and an index search statistics JSON file in `/result/search/<{algo},{group},k{k},bs{batch_size}.json>`. NOTE: The filenames will not have ",{group}" if `group = "base"`. `dataset-path` : 1. data is read from `/` 2. indices are built in `//index` 3. build/search results are stored in `//result` `build` and `search` : if both parameters are not supplied to the script then it is assumed both are `True`. `indices` and `algorithms` : these parameters ensure that the algorithm specified for an index is available in `algos.yaml` and not disabled, as well as having an associated executable. ### Step 3: Data Export The script `raft_ann_bench.data_export` will convert the intermediate JSON outputs produced by `raft_ann_bench.run` to more easily readable CSV files, which are needed to build charts made by `raft_ann_bench.plot`. ```bash usage: data_export.py [-h] [--dataset DATASET] [--dataset-path DATASET_PATH] options: -h, --help show this help message and exit --dataset DATASET dataset to download (default: glove-100-inner) --dataset-path DATASET_PATH path to dataset folder (default: ${RAPIDS_DATASET_ROOT_DIR}) ``` Build statistics CSV file is stored in `/result/build/<{algo},{group}.csv>` and index search statistics CSV file in `/result/search/<{algo},{group},k{k},bs{batch_size},{suffix}.csv>`, where suffix has three values: 1. `raw`: All search results are exported 2. `throughput`: Pareto frontier of throughput results is exported 3. `latency`: Pareto frontier of latency results is exported ### Step 4: Plot Results The script `raft_ann_bench.plot` will plot results for all algorithms found in index search statistics CSV files `/result/search/*.csv`. The usage of this script is: ```bash usage: [-h] [--dataset DATASET] [--dataset-path DATASET_PATH] [--output-filepath OUTPUT_FILEPATH] [--algorithms ALGORITHMS] [--groups GROUPS] [--algo-groups ALGO_GROUPS] [-k COUNT] [-bs BATCH_SIZE] [--build] [--search] [--x-scale X_SCALE] [--y-scale {linear,log,symlog,logit}] [--x-start X_START] [--mode {throughput,latency}] [--time-unit {s,ms,us}] [--raw] options: -h, --help show this help message and exit --dataset DATASET dataset to plot (default: glove-100-inner) --dataset-path DATASET_PATH path to dataset folder (default: /home/coder/raft/datasets/) --output-filepath OUTPUT_FILEPATH directory for PNG to be saved (default: /home/coder/raft) --algorithms ALGORITHMS plot only comma separated list of named algorithms. If parameters `groups` and `algo-groups are both undefined, then group `base` is plot by default (default: None) --groups GROUPS plot only comma separated groups of parameters (default: base) --algo-groups ALGO_GROUPS, --algo-groups ALGO_GROUPS add comma separated . to plot. Example usage: "--algo-groups=raft_cagra.large,hnswlib.large" (default: None) -k COUNT, --count COUNT the number of nearest neighbors to search for (default: 10) -bs BATCH_SIZE, --batch-size BATCH_SIZE number of query vectors to use in each query trial (default: 10000) --build --search --x-scale X_SCALE Scale to use when drawing the X-axis. Typically linear, logit or a2 (default: linear) --y-scale {linear,log,symlog,logit} Scale to use when drawing the Y-axis (default: linear) --x-start X_START Recall values to start the x-axis from (default: 0.8) --mode {throughput,latency} search mode whose Pareto frontier is used on the y-axis (default: throughput) --time-unit {s,ms,us} time unit to plot when mode is latency (default: ms) --raw Show raw results (not just Pareto frontier) of mode arg (default: False) ``` `mode`: plots pareto frontier of `throughput` or `latency` results exported in the previous step `algorithms`: plots all algorithms that it can find results for the specified `dataset`. By default, only `base` group will be plotted. `groups`: plot only specific groups of parameters configurations for an algorithm. Groups are defined in YAML configs (see `configuration`), and by default run `base` group `algo-groups`: this parameter is helpful to append any specific algorithm+group combination to plot results for in addition to all the arguments from `algorithms` and `groups`. It is of the format `.`, or for example, `raft_cagra.large` The figure below is the resulting plot of running our benchmarks as of August 2023 for a batch size of 10, on an NVIDIA H100 GPU and an Intel Xeon Platinum 8480CL CPU. It presents the throughput (in Queries-Per-Second) performance for every level of recall. ![Throughput vs recall plot comparing popular ANN algorithms with RAFT's at batch size 10](../../img/raft-vector-search-batch-10.png) ## Running the benchmarks ### End to end: small-scale benchmarks (<1M to 10M) The steps below demonstrate how to download, install, and run benchmarks on a subset of 10M vectors from the Yandex Deep-1B dataset By default the datasets will be stored and used from the folder indicated by the `RAPIDS_DATASET_ROOT_DIR` environment variable if defined, otherwise a datasets sub-folder from where the script is being called: ```bash # (1) prepare dataset. python -m raft_ann_bench.get_dataset --dataset deep-image-96-angular --normalize # (2) build and search index python -m raft_ann_bench.run --dataset deep-image-96-inner --algorithms raft_cagra --batch-size 10 -k 10 # (3) export data python -m raft_ann_bench.data_export --dataset deep-image-96-inner # (4) plot results python -m raft_ann_bench.plot --dataset deep-image-96-inner ``` Configuration files already exist for the following list of the million-scale datasets. Please refer to [ann-benchmarks datasets](https://github.com/erikbern/ann-benchmarks/#data-sets) for more information, including actual train and sizes. These all work out-of-the-box with the `--dataset` argument. Other million-scale datasets from `ann-benchmarks.com` will work, but will require a json configuration file to be created in `$CONDA_PREFIX/lib/python3.xx/site-packages/raft_ann_bench/run/conf`, or you can specify the `--configuration` option to use a specific file. | Dataset Name | Train Rows | Columns | Test Rows | Distance | |-----|------------|----|----------------|------------| | `deep-image-96-angular` | 10M | 96 | 10K | Angular | | `fashion-mnist-784-euclidean` | 60K | 784 | 10K | Euclidean | | `glove-50-angular` | 1.1M | 50 | 10K | Angular | | `glove-100-angular` | 1.1M | 100 | 10K | Angular | | `mnist-784-euclidean` | 60K | 784 | 10K | Euclidean | | `nytimes-256-angular` | 290K | 256 | 10K | Angular | | `sift-128-euclidean` | 1M | 128 | 10K | Euclidean| All of the datasets above contain ground test datasets with 100 neighbors. Thus `k` for these datasets must be less than or equal to 100. ### End to end: large-scale benchmarks (>10M vectors) `raft_ann_bench.get_dataset` cannot be used to download the [billion-scale datasets](ann_benchmarks_dataset.md#billion-scale) due to their size. You should instead use our billion-scale datasets guide to download and prepare them. All other python commands mentioned below work as intended once the billion-scale dataset has been downloaded. To download billion-scale datasets, visit [big-ann-benchmarks](http://big-ann-benchmarks.com/neurips21.html) We also provide a new dataset called `wiki-all` containing 88 million 768-dimensional vectors. This dataset is meant for benchmarking a realistic retrieval-augmented generation (RAG)/LLM embedding size at scale. It also contains 1M and 10M vector subsets for smaller-scale experiments. See our [Wiki-all Dataset Guide](https://docs.rapids.ai/api/raft/nightly/wiki_all_dataset/) for more information and to download the dataset. The steps below demonstrate how to download, install, and run benchmarks on a subset of 100M vectors from the Yandex Deep-1B dataset. Please note that datasets of this scale are recommended for GPUs with larger amounts of memory, such as the A100 or H100. ```bash mkdir -p datasets/deep-1B # (1) prepare dataset # download manually "Ground Truth" file of "Yandex DEEP" # suppose the file name is deep_new_groundtruth.public.10K.bin python -m raft_ann_bench.split_groundtruth --groundtruth datasets/deep-1B/deep_new_groundtruth.public.10K.bin # two files 'groundtruth.neighbors.ibin' and 'groundtruth.distances.fbin' should be produced # (2) build and search index python -m raft_ann_bench.run --dataset deep-1B --algorithms raft_cagra --batch-size 10 -k 10 # (3) export data python -m raft_ann_bench.data_export --dataset deep-1B # (4) plot results python -m raft_ann_bench.plot --dataset deep-1B ``` The usage of `python -m raft_ann_bench.split_groundtruth` is: ```bash usage: split_groundtruth.py [-h] --groundtruth GROUNDTRUTH options: -h, --help show this help message and exit --groundtruth GROUNDTRUTH Path to billion-scale dataset groundtruth file (default: None) ``` ### Running with Docker containers Two methods are provided for running the benchmarks with the Docker containers. #### End-to-end run on GPU When no other entrypoint is provided, an end-to-end script will run through all the steps in [Running the benchmarks](#running-the-benchmarks) above. For GPU-enabled systems, the `DATA_FOLDER` variable should be a local folder where you want datasets stored in `$DATA_FOLDER/datasets` and results in `$DATA_FOLDER/result` (we highly recommend `$DATA_FOLDER` to be a dedicated folder for the datasets and results of the containers): ```bash export DATA_FOLDER=path/to/store/datasets/and/results docker run --gpus all --rm -it -u $(id -u) \ -v $DATA_FOLDER:/data/benchmarks \ rapidsai/raft-ann-bench:24.08a-cuda11.8-py3.10 \ "--dataset deep-image-96-angular" \ "--normalize" \ "--algorithms raft_cagra,raft_ivf_pq --batch-size 10 -k 10" \ "" ``` Usage of the above command is as follows: | Argument | Description | |-----------------------------------------------------------|----------------------------------------------------------------------------------------------------| | `rapidsai/raft-ann-bench:24.08a-cuda11.8-py3.10` | Image to use. Can be either `raft-ann-bench` or `raft-ann-bench-datasets` | | `"--dataset deep-image-96-angular"` | Dataset name | | `"--normalize"` | Whether to normalize the dataset | | `"--algorithms raft_cagra,hnswlib --batch-size 10 -k 10"` | Arguments passed to the `run` script, such as the algorithms to benchmark, the batch size, and `k` | | `""` | Additional (optional) arguments that will be passed to the `plot` script. | ***Note about user and file permissions:*** The flag `-u $(id -u)` allows the user inside the container to match the `uid` of the user outside the container, allowing the container to read and write to the mounted volume indicated by the `$DATA_FOLDER` variable. #### End-to-end run on CPU The container arguments in the above section also be used for the CPU-only container, which can be used on systems that don't have a GPU installed. ***Note:*** the image changes to `raft-ann-bench-cpu` container and the `--gpus all` argument is no longer used: ```bash export DATA_FOLDER=path/to/store/datasets/and/results docker run --rm -it -u $(id -u) \ -v $DATA_FOLDER:/data/benchmarks \ rapidsai/raft-ann-bench-cpu:24.08a-py3.10 \ "--dataset deep-image-96-angular" \ "--normalize" \ "--algorithms hnswlib --batch-size 10 -k 10" \ "" ``` #### Manually run the scripts inside the container All of the `raft-ann-bench` images contain the Conda packages, so they can be used directly by logging directly into the container itself: ```bash export DATA_FOLDER=path/to/store/datasets/and/results docker run --gpus all --rm -it -u $(id -u) \ --entrypoint /bin/bash \ --workdir /data/benchmarks \ -v $DATA_FOLDER:/data/benchmarks \ rapidsai/raft-ann-bench:24.08a-cuda11.8-py3.10 ``` This will drop you into a command line in the container, with the `raft-ann-bench` python package ready to use, as described in the [Running the benchmarks](#running-the-benchmarks) section above: ``` (base) root@00b068fbb862:/data/benchmarks# python -m raft_ann_bench.get_dataset --dataset deep-image-96-angular --normalize ``` Additionally, the containers can be run in detached mode without any issue. ### Evaluating the results The benchmarks capture several different measurements. The table below describes each of the measurements for index build benchmarks: | Name | Description | |------------|--------------------------------------------------------| | Benchmark | A name that uniquely identifies the benchmark instance | | Time | Wall-time spent training the index | | CPU | CPU time spent training the index | | Iterations | Number of iterations (this is usually 1) | | GPU | GPU time spent building | | index_size | Number of vectors used to train index | The table below describes each of the measurements for the index search benchmarks. The most important measurements `Latency`, `items_per_second`, `end_to_end`. | Name | Description | |------------|-------------------------------------------------------------------------------------------------------------------------------------------------------| | Benchmark | A name that uniquely identifies the benchmark instance | | Time | The wall-clock time of a single iteration (batch) divided by the number of threads. | | CPU | The average CPU time (user + sys time). This does not include idle time (which can also happen while waiting for GPU sync). | | Iterations | Total number of batches. This is going to be `total_queries` / `n_queries`. | | GPU | GPU latency of a single batch (seconds). In throughput mode this is averaged over multiple threads. | | Latency | Latency of a single batch (seconds), calculated from wall-clock time. In throughput mode this is averaged over multiple threads. | | Recall | Proportion of correct neighbors to ground truth neighbors. Note this column is only present if groundtruth file is specified in dataset configuration.| | items_per_second | Total throughput, a.k.a Queries per second (QPS). This is approximately `total_queries` / `end_to_end`. | | k | Number of neighbors being queried in each iteration | | end_to_end | Total time taken to run all batches for all iterations | | n_queries | Total number of query vectors in each batch | | total_queries | Total number of vectors queries across all iterations ( = `iterations` * `n_queries`) | Note the following: - A slightly different method is used to measure `Time` and `end_to_end`. That is why `end_to_end` = `Time` * `Iterations` holds only approximately. - The actual table displayed on the screen may differ slightly as the hyper-parameters will also be displayed for each different combination being benchmarked. - Recall calculation: the number of queries processed per test depends on the number of iterations. Because of this, recall can show slight fluctuations if less neighbors are processed then it is available for the benchmark. ## Creating and customizing dataset configurations A single configuration will often define a set of algorithms, with associated index and search parameters, that can be generalize across datasets. We use YAML to define dataset specific and algorithm specific configurations. A default `datasets.yaml` is provided by RAFT in `${RAFT_HOME}/python/raft-ann-bench/src/raft_ann_bench/run/conf` with configurations available for several datasets. Here's a simple example entry for the `sift-128-euclidean` dataset: ```yaml - name: sift-128-euclidean base_file: sift-128-euclidean/base.fbin query_file: sift-128-euclidean/query.fbin groundtruth_neighbors_file: sift-128-euclidean/groundtruth.neighbors.ibin dims: 128 distance: euclidean ``` Configuration files for ANN algorithms supported by `raft-ann-bench` are provided in `${RAFT_HOME}/python/raft-ann-bench/src/raft_ann_bench/run/conf`. `raft_cagra` algorithm configuration looks like: ```yaml name: raft_cagra groups: base: build: graph_degree: [32, 64] intermediate_graph_degree: [64, 96] graph_build_algo: ["NN_DESCENT"] search: itopk: [32, 64, 128] large: build: graph_degree: [32, 64] search: itopk: [32, 64, 128] ``` The default parameters for which the benchmarks are run can be overridden by creating a custom YAML file for algorithms with a `base` group. There config above has 2 fields: 1. `name` - define the name of the algorithm for which the parameters are being specified. 2. `groups` - define a run group which has a particular set of parameters. Each group helps create a cross-product of all hyper-parameter fields for `build` and `search`. The table below contains all algorithms supported by RAFT. Each unique algorithm will have its own set of `build` and `search` settings. The [ANN Algorithm Parameter Tuning Guide](ann_benchmarks_param_tuning.md) contains detailed instructions on choosing build and search parameters for each supported algorithm. | Library | Algorithms | |-----------|---------------------------------------------------------------------------------------| | FAISS GPU | `faiss_gpu_flat`, `faiss_gpu_ivf_flat`, `faiss_gpu_ivf_pq` | | FAISS CPU | `faiss_cpu_flat`, `faiss_cpu_ivf_flat`, `faiss_cpu_ivf_pq` | | GGNN | `ggnn` | | HNSWlib | `hnswlib` | | RAFT | `raft_brute_force`, `raft_cagra`, `raft_ivf_flat`, `raft_ivf_pq`, `raft_cagra_hnswlib`| ## Adding a new ANN algorithm ### Implementation and Configuration Implementation of a new algorithm should be a C++ class that inherits `class ANN` (defined in `cpp/bench/ann/src/ann.h`) and implements all the pure virtual functions. In addition, it should define two `struct`s for building and searching parameters. The searching parameter class should inherit `struct ANN::AnnSearchParam`. Take `class HnswLib` as an example, its definition is: ```c++ template class HnswLib : public ANN { public: struct BuildParam { int M; int ef_construction; int num_threads; }; using typename ANN::AnnSearchParam; struct SearchParam : public AnnSearchParam { int ef; int num_threads; }; // ... }; ``` The benchmark program uses JSON format in a configuration file to specify indexes to build, along with the build and search parameters. To add the new algorithm to the benchmark, need be able to specify `build_param`, whose value is a JSON object, and `search_params`, whose value is an array of JSON objects, for this algorithm in configuration file. The `build_param` and `search_param` arguments will vary depending on the algorithm. Take the configuration for `HnswLib` as an example: ```json { "name" : "hnswlib.M12.ef500.th32", "algo" : "hnswlib", "build_param": {"M":12, "efConstruction":500, "numThreads":32}, "file" : "/path/to/file", "search_params" : [ {"ef":10, "numThreads":1}, {"ef":20, "numThreads":1}, {"ef":40, "numThreads":1}, ], "search_result_file" : "/path/to/file" }, ``` How to interpret these JSON objects is totally left to the implementation and should be specified in `cpp/bench/ann/src/factory.cuh`: 1. First, add two functions for parsing JSON object to `struct BuildParam` and `struct SearchParam`, respectively: ```c++ template void parse_build_param(const nlohmann::json& conf, typename cuann::HnswLib::BuildParam& param) { param.ef_construction = conf.at("efConstruction"); param.M = conf.at("M"); if (conf.contains("numThreads")) { param.num_threads = conf.at("numThreads"); } } template void parse_search_param(const nlohmann::json& conf, typename cuann::HnswLib::SearchParam& param) { param.ef = conf.at("ef"); if (conf.contains("numThreads")) { param.num_threads = conf.at("numThreads"); } } ``` 2. Next, add corresponding `if` case to functions `create_algo()` (in `cpp/bench/ann/) and `create_search_param()` by calling parsing functions. The string literal in `if` condition statement must be the same as the value of `algo` in configuration file. For example, ```c++ // JSON configuration file contains a line like: "algo" : "hnswlib" if (algo == "hnswlib") { // ... } ``` ### Adding a CMake Target In `raft/cpp/bench/ann/CMakeLists.txt`, we provide a `CMake` function to configure a new Benchmark target with the following signature: ``` ConfigureAnnBench( NAME PATH INCLUDES CXXFLAGS LINKS ) ``` To add a target for `HNSWLIB`, we would call the function as: ``` ConfigureAnnBench( NAME HNSWLIB PATH bench/ann/src/hnswlib/hnswlib_benchmark.cpp INCLUDES ${CMAKE_CURRENT_BINARY_DIR}/_deps/hnswlib-src/hnswlib CXXFLAGS "${HNSW_CXX_FLAGS}" ) ``` This will create an executable called `HNSWLIB_ANN_BENCH`, which can then be used to run `HNSWLIB` benchmarks. Add a new entry to `algos.yaml` to map the name of the algorithm to its binary executable and specify whether the algorithm requires GPU support. ```yaml raft_ivf_pq: executable: RAFT_IVF_PQ_ANN_BENCH requires_gpu: true ``` `executable` : specifies the name of the binary that will build/search the index. It is assumed to be available in `raft/cpp/build/`. `requires_gpu` : denotes whether an algorithm requires GPU to run.