Warning
This library is currently in a phase of active development. All features are subject to change without prior notice. If you are interested in collaborating, please feel free to reach out by opening an issue or starting a discussion.
SKADA is a library for domain adaptation (DA) with a scikit-learn and PyTorch/skorch compatible API with the following features:
- DA estimators and transformers with a scikit-learn compatible API (fit, transform, predict).
- PyTorch/skorch API for deep learning DA algorithms.
- Classifier/Regressor and data Adapter DA algorithms compatible with scikit-learn pipelines.
- Compatible with scikit-learn validation loops (cross_val_score, GridSearchCV, etc).
The following algorithms are currently implemented.
- Sample reweighting methods (Gaussian [1], Discriminant [2], KLIEPReweight [3], DensityRatio [4], TarS [21], KMMReweight [23])
- Sample mapping methods (CORAL [5], Optimal Transport DA OTDA [6], LinearMonge [7], LS-ConS [21])
- Subspace methods (SubspaceAlignment [8], TCA [9])
- Other methods (JDOT [10], DASVM [11])
Any methods that can be cast as an adaptation of the input data can be used in one of two ways:
- a scikit-learn transformer (Adapter) which provides both a full Classifier/Regressor estimator
- or an
Adapter
that can be used in a DA pipeline withmake_da_pipeline
. Refer to the examples below and visit the galleryfor more details.
- Deep Correlation alignment (DeepCORAL [12])
- Deep joint distribution optimal (DeepJDOT [13])
- Divergence minimization (MMD/DAN [14])
- Adversarial/discriminator based DA (DANN [15], CDAN [16])
- Importance Weighted [17]
- Prediction entropy [18]
- Soft neighborhood density [19]
- Deep Embedded Validation (DEV) [20]
- Circular Validation [11]
The library is not yet available on PyPI. You can install it from the source code.
pip install git+https://github.com/scikit-adaptation/skada
We provide here a few examples to illustrate the use of the library. For more details, please refer to this example, the quick start guide and the gallery.
First, the DA data in the SKADA API is stored in the following format:
X, y, sample_domain
Where X
is the input data, y
is the target labels and sample_domain
is the
domain labels (positive for source and negative for target domains). We provide
below an example ho how to fit a DA estimator:
from skada import CORAL
da = CORAL()
da.fit(X, y, sample_domain=sample_domain) # sample_domain passed by name
ypred = da.predict(Xt) # predict on test data
One can also use Adapter
classes to create a full pipeline with DA:
from skada import CORALAdapter, make_da_pipeline
from sklearn.preprocessing import StandardScaler
from sklearn.linear_model import LogisticRegression
pipe = make_da_pipeline(StandardScaler(), CORALAdapter(), LogisticRegression())
pipe.fit(X, y, sample_domain=sample_domain) # sample_domain passed by name
Please note that for Adapter
classes that implement sample reweighting, the
subsequent classifier/regressor must require sample_weights as input. This is
done with the set_fit_requires
method. For instance, with LogisticRegression
, you
would use LogisticRegression().set_fit_requires('sample_weight')
:
from skada import GaussianReweightAdapter, make_da_pipeline
pipe = make_da_pipeline(GaussianReweightAdapter(),
LogisticRegression().set_fit_request(sample_weight=True))
Finally SKADA can be used for cross validation scores estimation and hyperparameter selection :
from sklearn.model_selection import cross_val_score, GridSearchCV
from sklearn.preprocessing import StandardScaler
from sklearn.linear_model import LogisticRegression
from skada import CORALAdapter, make_da_pipeline
from skada.model_selection import SourceTargetShuffleSplit
from skada.metrics import PredictionEntropyScorer
# make pipeline
pipe = make_da_pipeline(StandardScaler(), CORALAdapter(), LogisticRegression())
# split and score
cv = SourceTargetShuffleSplit()
scorer = PredictionEntropyScorer()
# cross val score
scores = cross_val_score(pipe, X, y, params={'sample_domain': sample_domain},
cv=cv, scoring=scorer)
# grid search
param_grid = {'coraladapter__reg': [0.1, 0.5, 0.9]}
grid_search = GridSearchCV(estimator=pipe,
param_grid=param_grid,
cv=cv, scoring=scorer)
grid_search.fit(X, y, sample_domain=sample_domain)
This toolbox has been created and is maintained by the SKADA team that includes the following members:
- Théo Gnassounou
- Oleksii Kachaiev
- Rémi Flamary
- Antoine Collas
- Yanis Lalou
- Antoine de Mathelin
- Ruben Bueno
The library is distributed under the 3-Clause BSD license.
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