- Zero-dependency header-only C 99 library with bindings for Python and JavaScript.
- Targets ARM NEON, SVE, x86 AVX2, AVX-512 (VNNI, FP16) hardware backends.
- Zero-copy compatible with NumPy, PyTorch, TensorFlow, and other tensors.
- Handles
f64
double-,f32
single-, andf16
half-precision,i8
integral, and binary vectors. - Up to 200x faster than
scipy.spatial.distance
andnumpy.inner
. - Used in USearch and several DBMS products.
Implemented distance functions include:
- Euclidean (L2), Inner Distance, and Cosine (Angular) spatial distances.
- Hamming (~ Manhattan) and Jaccard (~ Tanimoto) binary distances.
- Kullback-Leibler and Jensen–Shannon divergences for probability distributions.
Technical Insights and related articles:
- Uses Horner's method for polynomial approximations, beating GCC 12 by 119x.
- Uses Arm SVE and x86 AVX-512's masked loads to eliminate tail
for
-loops. - Uses AVX-512 FP16 for half-precision operations, that few compilers vectorize.
- Substitutes LibC's
sqrt
calls with bithacks using Jan Kadlec's constant. - For Python avoids slow PyBind11, SWIG, and even
PyArg_ParseTuple
for speed. - For JavaScript uses typed arrays and NAPI for zero-copy calls.
Given 1000 embeddings from OpenAI Ada API with 1536 dimensions, running on the Apple M2 Pro Arm CPU with NEON support, here's how SimSIMD performs against conventional methods:
Kind | f32 improvement |
f16 improvement |
i8 improvement |
Conventional method | SimSIMD |
---|---|---|---|---|---|
Cosine | 32 x | 79 x | 133 x | scipy.spatial.distance.cosine |
cosine |
Euclidean ² | 5 x | 26 x | 17 x | scipy.spatial.distance.sqeuclidean |
sqeuclidean |
Inner Distance | 2 x | 9 x | 18 x | numpy.inner |
inner |
Jensen Shannon | 31 x | 53 x | scipy.spatial.distance.jensenshannon |
jensenshannon |
On the Intel Sapphire Rapids platform, SimSIMD was benchmarked against auto-vectorized code using GCC 12. GCC handles single-precision float
but might not be the best choice for int8
and _Float16
arrays, which has been part of the C language since 2011.
Kind | GCC 12 f32 |
GCC 12 f16 |
SimSIMD f16 |
f16 improvement |
---|---|---|---|---|
Cosine | 3.28 M/s | 336.29 k/s | 6.88 M/s | 20 x |
Euclidean ² | 4.62 M/s | 147.25 k/s | 5.32 M/s | 36 x |
Inner Distance | 3.81 M/s | 192.02 k/s | 5.99 M/s | 31 x |
Jensen Shannon | 1.18 M/s | 18.13 k/s | 2.14 M/s | 118 x |
Broader Benchmarking Results:
pip install simsimd
import simsimd
import numpy as np
vec1 = np.random.randn(1536).astype(np.float32)
vec2 = np.random.randn(1536).astype(np.float32)
dist = simsimd.cosine(vec1, vec2)
Supported functions include cosine
, inner
, sqeuclidean
, hamming
, and jaccard
.
batch1 = np.random.randn(100, 1536).astype(np.float32)
batch2 = np.random.randn(100, 1536).astype(np.float32)
dist = simsimd.cosine(batch1, batch2)
If either batch has more than one vector, the other batch must have one or the same number of vectors. If it contains just one, the value is broadcasted.
For calculating distances between all possible pairs of rows across two matrices (akin to scipy.spatial.distance.cdist
):
matrix1 = np.random.randn(1000, 1536).astype(np.float32)
matrix2 = np.random.randn(10, 1536).astype(np.float32)
distances = simsimd.cdist(matrix1, matrix2, metric="cosine")
By default, computations use a single CPU core. To optimize and utilize all CPU cores on Linux systems, add the threads=0
argument. Alternatively, specify a custom number of threads:
distances = simsimd.cdist(matrix1, matrix2, metric="cosine", threads=0)
To view a list of hardware backends that SimSIMD supports:
print(simsimd.get_capabilities())
Want to use it in Python with USearch?
You can wrap the raw C function pointers SimSIMD backends into a CompiledMetric
and pass it to USearch, similar to how it handles Numba's JIT-compiled code.
from usearch.index import Index, CompiledMetric, MetricKind, MetricSignature
from simsimd import pointer_to_sqeuclidean, pointer_to_cosine, pointer_to_inner
metric = CompiledMetric(
pointer=pointer_to_cosine("f16"),
kind=MetricKind.Cos,
signature=MetricSignature.ArrayArraySize,
)
index = Index(256, metric=metric)
To install, choose one of the following options depending on your environment:
npm install --save simsimd
yarn add simsimd
pnpm add simsimd
bun install simsimd
The package is distributed with prebuilt binaries for Node.js v10 and above for Linux (x86_64, arm64), macOS (x86_64, arm64), and Windows (i386,x86_64).
If your platform is not supported, you can build the package from source via npm run build
. This will automatically happen unless you install the package with --ignore-scripts
flag or use Bun.
After you install it, you will be able to call the SimSIMD functions on various TypedArray
variants:
const { sqeuclidean, cosine, inner, hamming, jaccard } = require('simsimd');
const vectorA = new Float32Array([1.0, 2.0, 3.0]);
const vectorB = new Float32Array([4.0, 5.0, 6.0]);
const distance = sqeuclidean(vectorA, vectorB);
console.log('Squared Euclidean Distance:', distance);
For integration within a CMake-based project, add the following segment to your CMakeLists.txt
:
FetchContent_Declare(
simsimd
GIT_REPOSITORY https://github.com/ashvardanian/simsimd.git
GIT_SHALLOW TRUE
)
FetchContent_MakeAvailable(simsimd)
If you're aiming to utilize the _Float16
functionality with SimSIMD, ensure your development environment is compatible with C 11.
For other functionalities of SimSIMD, C 99 compatibility will suffice.
A minimal usage example would be:
#include <simsimd/simsimd.h>
int main() {
simsimd_f32_t vector_a[1536];
simsimd_f32_t vector_b[1536];
simsimd_f32_t distance = simsimd_avx512_f32_cos(vector_a, vector_b, 1536);
return 0;
}
All of the functions names follow the same pattern: simsimd_{backend}_{type}_{metric}
.
- The backend can be
avx512
,avx2
,neon
, orsve
. - The type can be
f64
,f32
,f16
,i8
, orb8
. - The metric can be
cos
,ip
,l2sq
,hamming
,jaccard
,kl
, orjs
.
In case you want to avoid hard-coding the backend, you can use the simsimd_metric_punned_t
to pun the function pointer, and simsimd_capabilities
function to get the available backends at runtime.
To rerun experiments utilize the following command:
cmake -DCMAKE_BUILD_TYPE=Release -DSIMSIMD_BUILD_BENCHMARKS=1 -B ./build_release
cmake --build build_release --config Release
./build_release/simsimd_bench
./build_release/simsimd_bench --benchmark_filter=js
To test and benchmark with Python bindings:
pip install -e .
pytest python/test.py -s -x
pip install numpy scipy scikit-learn # for comparison baselines
python python/bench.py # to run default benchmarks
python python/bench.py --n 1000 --ndim 1000000 # batch size and dimensions
To test and benchmark JavaScript bindings:
npm install --dev
npm test
npm run bench
To test and benchmark GoLang bindings:
cd golang
go test # To test
go test -run=^$ -bench=. -benchmem # To benchmark