Metadata-Version: 2.4
Name: skfolio
Version: 0.10.2
Summary: Portfolio optimization built on top of scikit-learn
Author-email: Hugo Delatte <delatte.hugo@gmail.com>
Maintainer-email: Hugo Delatte <delatte.hugo@gmail.com>, Matteo Manzi <matteomanzi09@gmail.com>, Carlo Nicolini <c.nicolini@ipazia.com>
License: BSD 3-Clause License
        
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Project-URL: API Reference, https://www.skfolio.org/api_reference.html
Project-URL: Documentation, https://www.skfolio.org
Project-URL: Tutorials, https://www.skfolio.org
Project-URL: Repository, https://github.com/skfolio/skfolio
Keywords: portfolio,optimization,optimisation,finance,asset,allocation,quantitative,quant,investment,strategy,machine-learning,scikit-learn,data-mining,data-science
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===============
|icon|  skfolio
===============
.. |icon| image:: https://raw.githubusercontent.com/skfolio/skfolio/master/docs/_static/logo_animate.svg
    :width: 100
    :alt: skfolio documentation
    :target: https://skfolio.org/


**skfolio** is a Python library for portfolio optimization built on top of scikit-learn.
It offers a unified interface and tools compatible with scikit-learn to build, fine-tune,
and cross-validate portfolio models.

It is distributed under the open-source 3-Clause BSD license.

.. image:: https://raw.githubusercontent.com/skfolio/skfolio/master/docs/_static/expo.jpg
    :target: https://skfolio.org/auto_examples/
    :alt: examples

Important links
~~~~~~~~~~~~~~~

- Documentation: https://skfolio.org/
- Examples: https://skfolio.org/auto_examples/
- User Guide: https://skfolio.org/user_guide/
- GitHub Repo: https://github.com/skfolio/skfolio/

Installation
~~~~~~~~~~~~

`skfolio` is available on PyPI and can be installed with::

    pip install -U skfolio


Dependencies
~~~~~~~~~~~~

`skfolio` requires:

- python (>= |PythonMinVersion|)
- numpy (>= |NumpyMinVersion|)
- scipy (>= |ScipyMinVersion|)
- pandas (>= |PandasMinVersion|)
- cvxpy-base (>= |CvxpyBaseMinVersion|)
- clarabel (>= |ClarabelMinVersion|)
- scikit-learn (>= |SklearnMinVersion|)
- joblib (>= |JoblibMinVersion|)
- plotly (>= |PlotlyMinVersion|)

Docker
~~~~~~

You can also spin up a reproducible JupyterLab environment using Docker:

Build the image::

    docker build -t skfolio-jupyterlab .

Run the container::

    docker run -p 8888:8888 -v <path-to-your-folder-containing-data>:/app/data -it skfolio-jupyterlab

Browse:

Open localhost:8888/lab and start using `skfolio`

Key Concepts
~~~~~~~~~~~~
Since the development of modern portfolio theory by Markowitz (1952), mean-variance
optimization (MVO) has received considerable attention.

Unfortunately, it faces a number of shortcomings, including high sensitivity to the
input parameters (expected returns and covariance), weight concentration, high turnover,
and poor out-of-sample performance.

It is well-known that naive allocation (1/N, inverse-vol, etc.) tends to outperform
MVO out-of-sample (DeMiguel, 2007).

Numerous approaches have been developed to alleviate these shortcomings (shrinkage,
additional constraints, regularization, uncertainty set, higher moments, Bayesian
approaches, coherent risk measures, left-tail risk optimization, distributionally robust
optimization, factor model, risk-parity, hierarchical clustering, ensemble methods,
pre-selection, etc.).

Given the large number of methods, and the fact that they can be combined, there is a
need for a unified framework with a machine-learning approach to perform model
selection, validation, and parameter tuning while mitigating the risk of data leakage
and overfitting.

This framework is built on scikit-learn's API.

Available models
~~~~~~~~~~~~~~~~

* Portfolio Optimization:
    * Naive:
        * Equal-Weighted
        * Inverse-Volatility
        * Random (Dirichlet)
    * Convex:
        * Mean-Risk
        * Risk Budgeting
        * Maximum Diversification
        * Distributionally Robust CVaR
    * Clustering:
        * Hierarchical Risk Parity
        * Hierarchical Equal Risk Contribution
        * Nested Clusters Optimization
    * Ensemble Methods:
        * Stacking Optimization

* Expected Returns Estimator:
    * Empirical
    * Exponentially Weighted
    * Equilibrium
    * Shrinkage

* Covariance Estimator:
    * Empirical
    * Gerber
    * Denoising
    * Detoning
    * Exponentially Weighted
    * Ledoit-Wolf
    * Oracle Approximating Shrinkage
    * Shrunk Covariance
    * Graphical Lasso CV
    * Implied Covariance

* Distance Estimator:
    * Pearson Distance
    * Kendall Distance
    * Spearman Distance
    * Covariance Distance (based on any of the above covariance estimators)
    * Distance Correlation
    * Variation of Information

* Distribution Estimator:
    * Univariate:
        * Gaussian
        * Student's t
        * Johnson Su
        * Normal Inverse Gaussian
    * Bivariate Copula
        * Gaussian Copula
        * Student's t Copula
        * Clayton Copula
        * Gumbel Copula
        * Joe Copula
        * Independent Copula
    * Multivariate
        * Vine Copula (Regular, Centered, Clustered, Conditional Sampling)

* Prior Estimator:
    * Empirical
    * Black & Litterman
    * Factor Model
    * Synthetic Data (Stress Test, Factor Stress Test)
    * Entropy Pooling
    * Opinion Pooling

* Uncertainty Set Estimator:
    * On Expected Returns:
        * Empirical
        * Circular Bootstrap
    * On Covariance:
        * Empirical
        * Circular Bootstrap

* Pre-Selection Transformer:
    * Non-Dominated Selection
    * Select K Extremes (Best or Worst)
    * Drop Highly Correlated Assets
    * Select Non-Expiring Assets
    * Select Complete Assets (handle late inception, delisting, etc.)
    * Drop Zero Variance

* Cross-Validation and Model Selection:
    * Compatible with all `sklearn` methods (KFold, etc.)
    * Walk Forward
    * Combinatorial Purged Cross-Validation

* Hyper-Parameter Tuning:
    * Compatible with all `sklearn` methods (GridSearchCV, RandomizedSearchCV)

* Risk Measures:
    * Variance
    * Semi-Variance
    * Mean Absolute Deviation
    * First Lower Partial Moment
    * CVaR (Conditional Value at Risk)
    * EVaR (Entropic Value at Risk)
    * Worst Realization
    * CDaR (Conditional Drawdown at Risk)
    * Maximum Drawdown
    * Average Drawdown
    * EDaR (Entropic Drawdown at Risk)
    * Ulcer Index
    * Gini Mean Difference
    * Value at Risk
    * Drawdown at Risk
    * Entropic Risk Measure
    * Fourth Central Moment
    * Fourth Lower Partial Moment
    * Skew
    * Kurtosis

* Optimization Features:
    * Minimize Risk
    * Maximize Returns
    * Maximize Utility
    * Maximize Ratio
    * Transaction Costs
    * Management Fees
    * L1 and L2 Regularization
    * Weight Constraints
    * Group Constraints
    * Budget Constraints
    * Tracking Error Constraints
    * Turnover Constraints
    * Cardinality and Group Cardinality Constraints
    * Threshold (Long and Short) Constraints

Quickstart
~~~~~~~~~~
The code snippets below are designed to introduce the functionality of `skfolio` so you
can start using it quickly. It follows the same API as scikit-learn.

Imports
-------
.. code-block:: python

    from sklearn import set_config
    from sklearn.model_selection import (
        GridSearchCV,
        KFold,
        RandomizedSearchCV,
        train_test_split,
    )
    from sklearn.pipeline import Pipeline
    from scipy.stats import loguniform

    from skfolio import RatioMeasure, RiskMeasure
    from skfolio.datasets import load_factors_dataset, load_sp500_dataset
    from skfolio.distribution import VineCopula
    from skfolio.model_selection import (
        CombinatorialPurgedCV,
        WalkForward,
        cross_val_predict,
    )
    from skfolio.moments import (
        DenoiseCovariance,
        DetoneCovariance,
        EWMu,
        GerberCovariance,
        ShrunkMu,
    )
    from skfolio.optimization import (
        MeanRisk,
        HierarchicalRiskParity,
        NestedClustersOptimization,
        ObjectiveFunction,
        RiskBudgeting,
    )
    from skfolio.pre_selection import SelectKExtremes
    from skfolio.preprocessing import prices_to_returns
    from skfolio.prior import (
        BlackLitterman,
        EmpiricalPrior,
        EntropyPooling,
        FactorModel,
        OpinionPooling,
        SyntheticData,
     )
    from skfolio.uncertainty_set import BootstrapMuUncertaintySet

Load Dataset
------------
.. code-block:: python

    prices = load_sp500_dataset()

Train/Test split
----------------
.. code-block:: python

    X = prices_to_returns(prices)
    X_train, X_test = train_test_split(X, test_size=0.33, shuffle=False)


Minimum Variance
----------------
.. code-block:: python

    model = MeanRisk()

Fit on Training Set
-------------------
.. code-block:: python

    model.fit(X_train)

    print(model.weights_)

Predict on Test Set
-------------------
.. code-block:: python

    portfolio = model.predict(X_test)

    print(portfolio.annualized_sharpe_ratio)
    print(portfolio.summary())



Maximum Sortino Ratio
---------------------
.. code-block:: python

    model = MeanRisk(
        objective_function=ObjectiveFunction.MAXIMIZE_RATIO,
        risk_measure=RiskMeasure.SEMI_VARIANCE,
    )


Denoised Covariance & Shrunk Expected Returns
---------------------------------------------
.. code-block:: python

    model = MeanRisk(
        objective_function=ObjectiveFunction.MAXIMIZE_RATIO,
        prior_estimator=EmpiricalPrior(
            mu_estimator=ShrunkMu(), covariance_estimator=DenoiseCovariance()
        ),
    )

Uncertainty Set on Expected Returns
-----------------------------------
.. code-block:: python

    model = MeanRisk(
        objective_function=ObjectiveFunction.MAXIMIZE_RATIO,
        mu_uncertainty_set_estimator=BootstrapMuUncertaintySet(),
    )


Weight Constraints & Transaction Costs
--------------------------------------
.. code-block:: python

    model = MeanRisk(
        min_weights={"AAPL": 0.10, "JPM": 0.05},
        max_weights=0.8,
        transaction_costs={"AAPL": 0.0001, "RRC": 0.0002},
        groups=[
            ["Equity"] * 3 + ["Fund"] * 5 + ["Bond"] * 12,
            ["US"] * 2 + ["Europe"] * 8 + ["Japan"] * 10,
        ],
        linear_constraints=[
            "Equity <= 0.5 * Bond",
            "US >= 0.1",
            "Europe >= 0.5 * Fund",
            "Japan <= 1",
        ],
    )
    model.fit(X_train)


Risk Parity on CVaR
-------------------
.. code-block:: python

    model = RiskBudgeting(risk_measure=RiskMeasure.CVAR)

Risk Parity & Gerber Covariance
-------------------------------
.. code-block:: python

    model = RiskBudgeting(
        prior_estimator=EmpiricalPrior(covariance_estimator=GerberCovariance())
    )

Nested Cluster Optimization with Cross-Validation and Parallelization
---------------------------------------------------------------------
.. code-block:: python

    model = NestedClustersOptimization(
        inner_estimator=MeanRisk(risk_measure=RiskMeasure.CVAR),
        outer_estimator=RiskBudgeting(risk_measure=RiskMeasure.VARIANCE),
        cv=KFold(),
        n_jobs=-1,
    )

Randomized Search of the L2 Norm
--------------------------------
.. code-block:: python

    randomized_search = RandomizedSearchCV(
        estimator=MeanRisk(),
        cv=WalkForward(train_size=252, test_size=60),
        param_distributions={
            "l2_coef": loguniform(1e-3, 1e-1),
        },
    )
    randomized_search.fit(X_train)

    best_model = randomized_search.best_estimator_

    print(best_model.weights_)


Grid Search on Embedded Parameters
----------------------------------
.. code-block:: python

    model = MeanRisk(
        objective_function=ObjectiveFunction.MAXIMIZE_RATIO,
        risk_measure=RiskMeasure.VARIANCE,
        prior_estimator=EmpiricalPrior(mu_estimator=EWMu(alpha=0.2)),
    )

    print(model.get_params(deep=True))

    gs = GridSearchCV(
        estimator=model,
        cv=KFold(n_splits=5, shuffle=False),
        n_jobs=-1,
        param_grid={
            "risk_measure": [
                RiskMeasure.VARIANCE,
                RiskMeasure.CVAR,
                RiskMeasure.VARIANCE.CDAR,
            ],
            "prior_estimator__mu_estimator__alpha": [0.05, 0.1, 0.2, 0.5],
        },
    )
    gs.fit(X)

    best_model = gs.best_estimator_

    print(best_model.weights_)


Black & Litterman Model
-----------------------
.. code-block:: python

    views = ["AAPL - BBY == 0.03 ", "CVX - KO == 0.04", "MSFT == 0.06 "]
    model = MeanRisk(
        objective_function=ObjectiveFunction.MAXIMIZE_RATIO,
        prior_estimator=BlackLitterman(views=views),
    )

Factor Model
------------
.. code-block:: python

    factor_prices = load_factors_dataset()

    X, factors = prices_to_returns(prices, factor_prices)
    X_train, X_test, factors_train, factors_test = train_test_split(
        X, factors, test_size=0.33, shuffle=False
    )

    model = MeanRisk(prior_estimator=FactorModel())
    model.fit(X_train, factors_train)

    print(model.weights_)

    portfolio = model.predict(X_test)

    print(portfolio.calmar_ratio)
    print(portfolio.summary())

Factor Model & Covariance Detoning
----------------------------------
.. code-block:: python

    model = MeanRisk(
        prior_estimator=FactorModel(
            factor_prior_estimator=EmpiricalPrior(covariance_estimator=DetoneCovariance())
        )
    )

Black & Litterman Factor Model
------------------------------
.. code-block:: python

    factor_views = ["MTUM - QUAL == 0.03 ", "VLUE == 0.06"]
    model = MeanRisk(
        objective_function=ObjectiveFunction.MAXIMIZE_RATIO,
        prior_estimator=FactorModel(
            factor_prior_estimator=BlackLitterman(views=factor_views),
        ),
    )

Pre-Selection Pipeline
----------------------
.. code-block:: python

    set_config(transform_output="pandas")
    model = Pipeline(
        [
            ("pre_selection", SelectKExtremes(k=10, highest=True)),
            ("optimization", MeanRisk()),
        ]
    )
    model.fit(X_train)

    portfolio = model.predict(X_test)




K-fold Cross-Validation
-----------------------
.. code-block:: python

    model = MeanRisk()
    mmp = cross_val_predict(model, X_test, cv=KFold(n_splits=5))
    # mmp is the predicted MultiPeriodPortfolio object composed of 5 Portfolios (1 per testing fold)

    mmp.plot_cumulative_returns()
    print(mmp.summary())


Combinatorial Purged Cross-Validation
-------------------------------------
.. code-block:: python

    model = MeanRisk()

    cv = CombinatorialPurgedCV(n_folds=10, n_test_folds=2)

    print(cv.summary(X_train))

    population = cross_val_predict(model, X_train, cv=cv)

    population.plot_distribution(
        measure_list=[RatioMeasure.SHARPE_RATIO, RatioMeasure.SORTINO_RATIO]
    )
    population.plot_cumulative_returns()
    print(population.summary())


Minimum CVaR Optimization on Synthetic Returns
----------------------------------------------
.. code-block:: python

    vine = VineCopula(log_transform=True, n_jobs=-1)
    prior = SyntheticData(distribution_estimator=vine, n_samples=2000)
    model = MeanRisk(risk_measure=RiskMeasure.CVAR, prior_estimator=prior)
    model.fit(X)
    print(model.weights_)


Stress Test
-----------
.. code-block:: python

    vine = VineCopula(log_transform=True, central_assets=["BAC"], n_jobs=-1)
    vine.fit(X)
    X_stressed = vine.sample(n_samples=10_000, conditioning = {"BAC": -0.2})
    ptf_stressed = model.predict(X_stressed)


Minimum CVaR Optimization on Synthetic Factors
----------------------------------------------
.. code-block:: python

    vine = VineCopula(central_assets=["QUAL"], log_transform=True, n_jobs=-1)
    factor_prior = SyntheticData(
        distribution_estimator=vine,
        n_samples=10_000,
        sample_args=dict(conditioning={"QUAL": -0.2}),
    )
    factor_model = FactorModel(factor_prior_estimator=factor_prior)
    model = MeanRisk(risk_measure=RiskMeasure.CVAR, prior_estimator=factor_model)
    model.fit(X, factors)
    print(model.weights_)


Factor Stress Test
------------------
.. code-block:: python

    factor_model.set_params(factor_prior_estimator__sample_args=dict(
        conditioning={"QUAL": -0.5}
    ))
    factor_model.fit(X, factors)
    stressed_dist = factor_model.return_distribution_
    stressed_ptf = model.predict(stressed_dist)

Entropy Pooling
---------------
.. code-block:: python

    entropy_pooling = EntropyPooling(
        mean_views=[
            "JPM == -0.002",
            "PG >= LLY",
            "BAC >= prior(BAC) * 1.2",
        ],
        cvar_views=[
            "GE == 0.08",
        ],
    )
    entropy_pooling.fit(X)
    print(entropy_pooling.relative_entropy_)
    print(entropy_pooling.effective_number_of_scenarios_)
    print(entropy_pooling.return_distribution_.sample_weight)

CVaR Hierarchical Risk Parity optimization on Entropy Pooling
-------------------------------------------------------------
.. code-block:: python

    entropy_pooling = EntropyPooling(cvar_views=["GE == 0.08"])
    model = HierarchicalRiskParity(
        risk_measure=RiskMeasure.CVAR,
        prior_estimator=entropy_pooling
    )
    model.fit(X)
    print(model.weights_)

Stress Test with Entropy Pooling on Factor Synthetic Data
---------------------------------------------------------
.. code-block:: python

    # Regular Vine Copula and sampling of 100,000 synthetic factor returns
    factor_synth = SyntheticData(
        n_samples=100_000,
        distribution_estimator=VineCopula(log_transform=True, n_jobs=-1, random_state=0)
    )

    # Entropy Pooling by imposing a CVaR-95% of 10% on the Quality factor
    factor_entropy_pooling = EntropyPooling(
        prior_estimator=factor_synth,
        cvar_views=["QUAL == 0.10"],
    )

    factor_entropy_pooling.fit(X, factors)

    # We retrieve the stressed distribution:
    stressed_dist = factor_model.return_distribution_

    # We stress-test our portfolio:
    stressed_ptf = model.predict(stressed_dist)

Opinion Pooling
---------------
.. code-block:: python

    # We consider two expert opinions, each generated via Entropy Pooling with
    # user-defined views.
    # We assign probabilities of 40% to Expert 1, 50% to Expert 2, and by default
    # the remaining 10% is allocated to the prior distribution:
    opinion_1 = EntropyPooling(cvar_views=["AMD == 0.10"])
    opinion_2 = EntropyPooling(
        mean_views=["AMD >= BAC", "JPM <= prior(JPM) * 0.8"],
        cvar_views=["GE == 0.12"],
    )

    opinion_pooling = OpinionPooling(
        estimators=[("opinion_1", opinion_1), ("opinion_2", opinion_2)],
        opinion_probabilities=[0.4, 0.5],
    )

    opinion_pooling.fit(X)


Recognition
~~~~~~~~~~~

We would like to thank all contributors to our direct dependencies, such as
`scikit-learn <https://github.com/scikit-learn/scikit-learn>`_ and `cvxpy <https://github.com/cvxpy/cvxpy>`_, as well as the contributors of the following resources that
served as sources of inspiration:

    * PyPortfolioOpt
    * Riskfolio-Lib
    * scikit-portfolio
    * microprediction
    * statsmodels
    * rsome
    * danielppalomar.com
    * gautier.marti.ai


Citation
~~~~~~~~

If you use `skfolio` in a scientific publication, we would appreciate citations:

**The library**::

        @software{skfolio,
          title     = {skfolio},
          author    = {Delatte, Hugo and Nicolini, Carlo and Manzi, Matteo},
          year      = {2024},
          doi       = {TBD after next release},
          url       = {https://github.com/skfolio/skfolio}
        }

**The paper**::

        @article{nicolini2025skfolio,
          title         = {skfolio: Portfolio Optimization in Python},
          author        = {Nicolini, Carlo and Manzi, Matteo and Delatte, Hugo},
          journal       = {arXiv preprint arXiv:2507.04176},
          year          = {2025},
          eprint        = {2507.04176},
          archivePrefix = {arXiv},
          url           = {https://arxiv.org/abs/2507.04176}
        }

