Metadata-Version: 2.1
Name: dbscan
Version: 0.0.11
Summary: Theoretically efficient and practical parallel DBSCAN
Home-page: https://github.com/wangyiqiu/dbscan-python
Author: Yiqiu Wang
Author-email: Yiqiu Wang <yiqiu_wang@icloud.com>
Maintainer-email: Anirudh Vegesana <avegesan@cs.stanford.edu>
License: MIT
Project-URL: homepage, https://sites.google.com/view/yiqiuwang/dbscan
Project-URL: repository, https://github.com/wangyiqiu/dbscan-python
Keywords: cluster,clustering,density,dbscan
Classifier: Development Status :: 2 - Pre-Alpha
Classifier: Intended Audience :: Science/Research
Classifier: Intended Audience :: Developers
Classifier: License :: OSI Approved :: MIT License
Classifier: Programming Language :: C++
Classifier: Programming Language :: Python :: 3
Classifier: Topic :: Software Development
Classifier: Topic :: Scientific/Engineering
Requires-Python: >=3.10,<4
Description-Content-Type: text/markdown
Provides-Extra: scikit-learn
Provides-Extra: example
License-File: LICENSE

# Theoretically-Efficient and Practical Parallel DBSCAN

[![arXiv](https://img.shields.io/badge/arXiv-1912.06255-b31b1b.svg)](https://arxiv.org/abs/1912.06255)
[![build](https://github.com/wangyiqiu/dbscan-python/actions/workflows/build_wheels.yml/badge.svg)](https://github.com/wangyiqiu/dbscan-python/actions/workflows/build_wheels.yml)

## Overview

This repository hosts fast parallel DBSCAN clustering code for low dimensional Euclidean space. The code automatically uses the available threads on a parallel shared-memory machine to speedup DBSCAN clustering. It stems from a paper presented in SIGMOD'20: [Theoretically Efficient and Practical Parallel DBSCAN](https://dl.acm.org/doi/10.1145/3318464.3380582).

Our software on 1 thread is on par with all serial state-of-the-art DBSCAN packages, and provides additional speedup via multi-threading. Below, we show a simple benchmark comparing our code with the DBSCAN implementation of Sklearn, tested on a 6-core computer using a 2-dimensional data set with 50000 data points. We also show a visualization of the clustering result on a smaller data set.

Data sets with dimensionality 2 - 20 are supported by default, which can be modified by modifying ``DBSCAN_MIN_DIMS`` and ``DBSCAN_MAX_DIMS`` in the [source code](https://github.com/wangyiqiu/dbscan-python/blob/master/include/dbscan/capi.h).

<p float="left">
<img src="https://github.com/wangyiqiu/dbscan-python/blob/master/compare.png" alt="timing" width="300"/>
<img src="https://github.com/wangyiqiu/dbscan-python/blob/master/example.png" alt="example" width="300"/>
</p>

## Tutorial

### Option 1: Use the binary executable

Compile and run the program:

```
mkdir build
cd build
cmake ..
cd executable
make -j # this will take a while
./dbscan -eps 0.1 -minpts 10 -o clusters.txt <data-file>
```

The `<data-file>` can be any CSV-like point data file, where each line contains a data point -- see an example [here](https://github.com/wangyiqiu/hdbscan/blob/main/example-data.csv). The data file can be either with or without header. The cluster output `clusters.txt` will contain a cluster ID on each line (other than the first-line header), giving a cluster assignment in the same ordering as the input file. A noise point will have a cluster ID of `-1`.

### Option 2: Use the Python binding

There are two ways to install it:

* Install it using PyPI: ``pip3 install --user dbscan`` (you can find the wheels [here](https://pypi.org/project/dbscan/#files))
* (harder and not recommended) Compile it yourself: First install dependencies ``pip3 install -r requirements.txt`` and ``sudo apt install libpython3-dev``. Run ``python3 setup.py build``, The compilation will take a few minutes, and generate a ``.so`` library containing the ``DBSCAN`` module.
To create a wheel that is supported universally across many Python versions for your given OS, run ``python setup.py bdist_wheel`` in an environment containing the oldest numpy version available for the version of Python that you are compiling for. For example, for Python 3.8, use numpy 1.17 to compile the wheel. Then, the wheel will work on all Python and numpy versions that are newer that that for your given OS. This is done automatically when installing via pip.

An example for using the Python module is provided in ``example.py``. If the dependencies above are installed, simply run ``python3 example.py`` from the root directory to reproduce the plots above.

#### Python API

```
from dbscan import DBSCAN
labels, core_samples_mask = DBSCAN(X, eps=0.3, min_samples=10)
```

#### Input

* ``X``: A 2-D Numpy array containing the input data points. The first dimension of ``X`` is the number of data points ``n``, and the second dimension is the data set dimensionality (the maximum supported dimensionality is 20).
* ``eps``: The epsilon parameter (default 0.5).
* ``min_samples``: The minPts parameter (default 5).

#### Output

* ``labels``: A length ``n`` Numpy array (``dtype=np.int32``) containing cluster IDs of the data points, in the same ordering as the input data. Noise points are given a pseudo-ID of ``-1``.
* ``core_samples_mask``: A length ``n`` Numpy array (``dtype=np.bool``) masking the core points, in the same ordering as the input data.

We provide a complete example below that generates a toy data set, computes the DBSCAN clustering, and visualizes the result as shown in the plot above.

```
import numpy as np
from sklearn.datasets import make_blobs
from sklearn.preprocessing import StandardScaler

# #############################################################################
# Generate sample data
centers = [[1, 1], [-1, -1], [1, -1]]
X, labels_true = make_blobs(n_samples=750, centers=centers, cluster_std=0.4,
                            random_state=0)
X = StandardScaler().fit_transform(X)

# #############################################################################
# Compute DBSCAN

from dbscan import sklDBSCAN as DBSCAN
db = DBSCAN(eps=0.3, min_samples=10).fit(X)
core_samples_mask = np.zeros_like(db.labels_, dtype=bool)
core_samples_mask[db.core_sample_indices_] = True
labels = db.labels_

# OR direct call of the C API:
# from dbscan import DBSCAN
# labels, core_samples_mask = DBSCAN(X, eps=0.3, min_samples=10)

# #############################################################################
# Plot result
import matplotlib.pyplot as plt

n_clusters_ = len(set(labels)) - (1 if -1 in labels else 0)
n_noise_ = list(labels).count(-1)
# Black removed and is used for noise instead.
unique_labels = set(labels)
colors = [plt.cm.Spectral(each)
          for each in np.linspace(0, 1, len(unique_labels))]
for k, col in zip(unique_labels, colors):
    if k == -1:
        # Black used for noise.
        col = [0, 0, 0, 1]

    class_member_mask = (labels == k)

    xy = X[class_member_mask & core_samples_mask]
    plt.plot(xy[:, 0], xy[:, 1], 'o', markerfacecolor=tuple(col),
             markeredgecolor='k', markersize=14)

    xy = X[class_member_mask & ~core_samples_mask]
    plt.plot(xy[:, 0], xy[:, 1], 'o', markerfacecolor=tuple(col),
             markeredgecolor='k', markersize=6)

plt.title('Estimated number of clusters: %d' % n_clusters_)
plt.show()
```

### Option 3: Include directly in your own C++ program

Create your own caller header and source file by instantiating the DBSCAN template function in "dbscan/algo.h".

dbscan.h:
```c++
template<int dim>
int DBSCAN(int n, double* PF, double epsilon, int minPts, bool* coreFlagOut, int* coreFlag, int* cluster);

// equivalent to
// int DBSCAN(intT n, floatT PF[n][dim], double epsilon, intT minPts, bool coreFlagOut[n], intT coreFlag[n], intT cluster[n])
// if C++ syntax was a little more flexible

template<>
int DBSCAN<3>(int n, double* PF, double epsilon, int minPts, bool* coreFlagOut, int* coreFlag, int* cluster);
```

dbscan.cpp:
```c++
#include "dbscan/algo.h"
#include "dbscan.h"
```

Calling the instantiated function:
```c++
int n = ...; // number of data points
double data[n][3] = ...; // data points
int labels[n]; // label ids get saved here
bool core_samples[n]; // a flag determining whether or not the sample is a core sample is saved here
{
  int ignore[n];
  DBSCAN<3>(n, (void*)data, 70, 100, core_samples, ignore, labels);
}
```

Doing this will only compile the function for the number of dimensions that you want, which saves on compilation time.

You can also include the "dbscan/capi.h" and define your own ``DBSCAN_MIN_DIMS`` and ``DBSCAN_MAX_DIMS`` macros the same way the Python extension uses it. The function exported has the following signature.
```c++
extern "C" int DBSCAN(int dim, int n, double* PF, double epsilon, int minPts, bool* coreFlag, int* cluster);
```

Right now, the only two files that are guaranteed to remain in the C/C++ API are "dbscan/algo.h" and "dbscan/capi.h" and the functions named DBSCAN within.

## Citation

If you use our work in a publication, we would appreciate citations:

    @inproceedings{wang2020theoretically,
      author = {Wang, Yiqiu and Gu, Yan and Shun, Julian},
      title = {Theoretically-Efficient and Practical Parallel DBSCAN},
      year = {2020},
      isbn = {9781450367356},
      publisher = {Association for Computing Machinery},
      address = {New York, NY, USA},
      url = {https://doi.org/10.1145/3318464.3380582},
      doi = {10.1145/3318464.3380582},
      booktitle = {Proceedings of the 2020 ACM SIGMOD International Conference on Management of Data},
      pages = {2555–2571},
      numpages = {17},
      keywords = {parallel algorithms, spatial clustering, DBScan},
      location = {Portland, OR, USA},
      series = {SIGMOD ’20}
    }
