An implementation of Stochastic Bloc model and Latent Block model efficient with sparse matrices
Project description
Getting started with SparseBM
SparseBM is a python module for handling sparse graphs with Block Models. The module is an implementation of the variational inference algorithm for the Stochastic Block Model (SBM) and the Latent Block Model (LBM) for sparse graphs, which leverages the sparsity of edges to scale to very large numbers of nodes. The module can use Cupy to take advantage of the hardware acceleration provided by graphics processing units (GPU).
Installing
The SparseBM module is distributed through the PyPI repository and the documentation is available here.
With GPU acceleration (recommended if GPUs are available)
This option is recommended if GPUs are available to speedup computation.
With the package installer pip:
pip3 install sparsebm[gpu]
The Cupy module will be installed as a dependency.
Alternatively Cupy can be installed separately, and will be used by sparsebm
if available.
pip3 install sparsebm
pip3 install cupy
Without GPU acceleration
Without GPU acceleration, only CPUs are used. The infererence process still uses sparsity, but no GPU linear algebra operations.
pip3 install sparsebm
For users who do not have GPU, we recommend the free serverless Jupyter notebook environment provided by Google Colab where the Cupy module is already installed and ready to be used with a GPU.
Complete examples (notebook for Google Colab and scripts) are given in the
Examples section (and in the examples/ of the repository).
Quick example with the Stochastic Block Model
-
Generate a synthetic graph for analysis with SBM:
from sparsebm import generate_SBM_dataset dataset = generate_SBM_dataset(symmetric=True)
-
Infer with the Bernoulli Stochastic Bloc Model:
from sparsebm import SBM # A number of classes must be specified. Otherwise see model selection. model = SBM(dataset.clusters) model.fit(dataset.data, symmetric=True) print("Labels:", model.labels)
-
Compute performance:
from sparsebm.utils import ARI ari = ARI(dataset.labels, model.labels) print("Adjusted Rand index is {:.2f}".format(ari))
-
Model selection: Infer with the Bernoulli Stochastic Bloc Model with an unknown number of groups:
from sparsebm import ModelSelection model_selection = ModelSelection("SBM") models = model_selection.fit(dataset.data, symmetric=True) print("Labels:", models.best.labels) from sparsebm.utils import ARI ari = ARI(dataset.labels, models.best.labels) print("Adjusted Rand index is {:.2f}".format(ari))
Quick example with the Latent Block Model
-
Generate a synthetic graph for analysis with LBM:
from sparsebm import generate_LBM_dataset dataset = generate_LBM_dataset()
-
Use the Bernoulli Latent Bloc Model:
from sparsebm import LBM # A number of classes must be specified. Otherwise see model selection. model = LBM( dataset.row_clusters, dataset.column_clusters, n_init_total_run=1, ) model.fit(dataset.data) print("Row Labels:", model.row_labels) print("Column Labels:", model.column_labels)
-
Compute performance:
from sparsebm.utils import CARI cari = CARI( dataset.row_labels, dataset.column_labels, model.row_labels, model.column_labels, ) print("Co-Adjusted Rand index is {:.2f}".format(cari))
-
Model selection: Infer with the Bernoulli Latent Bloc Model with an unknown number of groups:
from sparsebm import ModelSelection model_selection = ModelSelection("LBM") models = model_selection.fit(dataset.data) print("Row Labels:", models.best.row_labels) print("Column Labels:", models.best.column_labels) from sparsebm.utils import CARI cari = CARI( dataset.row_labels, dataset.column_labels, models.best.row_labels, models.best.column_labels, ) print("Co-Adjusted Rand index is {:.2f}".format(cari))
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