Metadata-Version: 2.1
Name: pyCeterisParibus
Version: 0.5.1
Summary: Ceteris Paribus python package
Home-page: https://github.com/ModelOriented/pyCeterisParibus
Author: Michał Kuźba
Author-email: michal.kuzba@students.mimuw.edu.pl
License: UNKNOWN
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        # pyCeterisParibus
        pyCeterisParibus is a Python library based on an *R* package [CeterisParibus](https://github.com/pbiecek/ceterisParibus).
        It implements Ceteris Paribus Plots.
        They allow understanding how the model response would change if a selected variable is changed. 
        It’s a perfect tool for What-If scenarios. Ceteris Paribus is a Latin phrase meaning all else unchanged. 
        These plots present the change in model response as the values of one feature change with all others being fixed. 
        Ceteris Paribus method is model-agnostic - it works for any Machine Learning model.
        The idea is an extension of PDP (Partial Dependency Plots) and ICE (Individual Conditional Expectations) plots.
        It allows explaining single observations for multiple variables at the same time.
        The plot engine is developed [here](https://github.com/ModelOriented/ceterisParibusD3).
        
        ## Why is it so useful?
        There might be several motivations behind utilizing this idea. 
        Imagine a person gets a low credit score. 
        The client wants to understand how to increase the score and the scoring institution (e.g. a bank) should be able to answer such questions. 
        Moreover, this method is useful for researchers and developers to analyze, debug, explain and improve Machine Learning models, assisting the entire process of the model design.
        
        ## Setup
        Tested on Python 3.5+
        
        PyCeterisParibus is on [PyPI](https://pypi.org/project/pyCeterisParibus/). Simply run:
        
        ```bash
        pip install pyCeterisParibus
        ```
        or install the newest version from GitHub by executing:
        ```bash
        pip install git+https://github.com/ModelOriented/pyCeterisParibus
        ```
        or download the sources, enter the main directory and perform:
        ```bash
        https://github.com/ModelOriented/pyCeterisParibus.git
        cd pyCeterisParibus
        python setup.py install   # (alternatively use pip install .)
        ```
        
        ## Docs
        A detailed description of all methods and their parameters might be found in [documentation](https://pyceterisparibus.readthedocs.io/en/latest/ceteris_paribus.html).
        
        To build the documentation locally:
        ```bash
        pip install -r requirements-dev.txt
        cd docs
        make html
        ```
        and open `_build/html/index.html`
        
        ## Examples
        Below we present use cases on two well-known datasets - Titanic and Iris. More examples e.g. for regression problems might be found [here](examples) and in jupyter notebooks [here](jupyter-notebooks).
        
        Note, that in order to run the examples you need to install extra requirements from `requirements-dev.txt`.
        
        ## Use case - Titanic survival
        We demonstrate Ceteris Paribus Plots using the well-known Titanic dataset. In this problem, we examine the chance of survival for Titanic passengers.
        We start with preprocessing the data and creating an XGBoost model.
        ```python
        import pandas as pd
        df = pd.read_csv('titanic_train.csv')
        
        y = df['Survived']
        x = df.drop(['Survived', 'PassengerId', 'Name', 'Cabin', 'Ticket'],
            inplace=False, axis=1)
            
        valid = x['Age'].isnull() | x['Embarked'].isnull()
        x = x[-valid]
        y = y[-valid]
        
        from sklearn.model_selection import train_test_split
        X_train, X_test, y_train, y_test = train_test_split(x, y,
            test_size=0.2, random_state=42)
        ```
        ```python
        from sklearn.pipeline import Pipeline
        from sklearn.preprocessing import StandardScaler, OneHotEncoder
        from sklearn.compose import ColumnTransformer
        
        # We create the preprocessing pipelines for both numeric and categorical data.
        numeric_features = ['Pclass', 'Age', 'SibSp', 'Parch', 'Fare']
        numeric_transformer = Pipeline(steps=[
            ('scaler', StandardScaler())])
        
        categorical_features = ['Embarked', 'Sex']
        categorical_transformer = Pipeline(steps=[
            ('onehot', OneHotEncoder(handle_unknown='ignore'))])
        
        preprocessor = ColumnTransformer(
            transformers=[
                ('num', numeric_transformer, numeric_features),
                ('cat', categorical_transformer, categorical_features)])
        ```
        
        ```python
        from xgboost import XGBClassifier
        xgb_clf = Pipeline(steps=[('preprocessor', preprocessor),
        ('classifier', XGBClassifier())])
        xgb_clf.fit(X_train, y_train)
        ```
        
        Here the pyCeterisParibus starts. Since this library works in a model agnostic fashion, first we need to create a wrapper around the model with uniform predict interface.
        ```python
        from ceteris_paribus.explainer import explain
        explainer_xgb = explain(xgb_clf, data=x, y=y, label='XGBoost',
            predict_function=lambda X: xgb_clf.predict_proba(X)[::, 1])
        ```
        
        
        ### Single variable profile
        Let's look at Mr Ernest James Crease, the 19-year-old man, travelling on the 3. class from Southampton with an 8 pounds ticket in his pocket. He died on Titanic. Most likely, this would not have been the case had Ernest been a few years younger.
        Figure 1 presents the chance of survival for a person like Ernest at different ages. We can see things were tough for people like him unless they were a child.
        
        ```python
        ernest = X_test.iloc[10]
        label_ernest = y_test.iloc[10]
        from ceteris_paribus.profiles import individual_variable_profile
        cp_xgb = individual_variable_profile(explainer_xgb, ernest, label_ernest)
        ```
        
        Having calculated the profile we can plot it. Note, that `plot_notebook` might be used instead of `plot` when used in Jupyter notebooks.
        
        ```python
        from ceteris_paribus.plots.plots import plot
        plot(cp_xgb, selected_variables=["Age"])
        ```
        
        ![Chance of survival depending on age](misc/titanic_single_response.png)
        
        ### Many models
        The above picture explains the prediction of XGBoost model. What if we compare various models?
        
        ```python
        from sklearn.ensemble import RandomForestClassifier
        from sklearn.linear_model import LogisticRegression
        rf_clf = Pipeline(steps=[('preprocessor', preprocessor),
            ('classifier', RandomForestClassifier())])
        linear_clf = Pipeline(steps=[('preprocessor', preprocessor),
            ('classifier', LogisticRegression())])
            
        rf_clf.fit(X_train, y_train)
        linear_clf.fit(X_train, y_train)
        
        explainer_rf = explain(rf_clf, data=x, y=y, label='RandomForest',
            predict_function=lambda X: rf_clf.predict_proba(X)[::, 1])
        explainer_linear = explain(linear_clf, data=x, y=y, label='LogisticRegression', 
            predict_function=lambda X: linear_clf.predict_proba(X)[::, 1])
            
        plot(cp_xgb, cp_rf, cp_linear, selected_variables=["Age"])
        ```
        
        ![The probability of survival estimated with various models.](misc/titanic_many_models.png)
        
        Clearly, XGBoost offers a better fit than Logistic Regression. 
        Also, it predicts a higher chance of survival at child's age than the Random Forest model does.
        
        ### Profiles for many variables
        This time we have a look at Miss. Elizabeth Mussey Eustis. She is 54 years old, travels at 1. class with her sister Marta, as they return to the US from their tour of southern Europe. They both survived the disaster.
        
        ```python
        elizabeth = X_test.iloc[1]
        label_elizabeth = y_test.iloc[1]
        cp_xgb_2 = individual_variable_profile(explainer_xgb, elizabeth, label_elizabeth)
        ```
        
        ```python
        plot(cp_xgb_2, selected_variables=["Pclass", "Sex", "Age", "Embarked"])
        ```
        
        ![Profiles for many variables.](misc/titanic_many_variables.png)
        
        Would she have returned home if she had travelled at 3. class or if she had been a man? As we can observe this is less likely. On the other hand, for a first class, female passenger chances of survival were high regardless of age. Note, this was different in the case of Ernest. Place of embarkment (Cherbourg) has no influence, which is expected behaviour.
        
        ### Feature interactions and average response
        Now, what if we look at passengers most similar to Miss. Eustis (middle-aged, upper class)?
        
        ```python
        from ceteris_paribus.select_data import select_neighbours
        neighbours = select_neighbours(X_train, elizabeth, 
            selected_variables=['Pclass', 'Age', 'SibSp', 'Parch', 'Fare', 'Embarked'], 
            n=15)
        cp_xgb_ns = individual_variable_profile(explainer_xgb, neighbours)
        ```
        
        ```python
        plot(cp_xgb_ns, color="Sex", selected_variables=["Pclass", "Age"], 
            aggregate_profiles='mean', size_pdps=6, alpha_pdps=1, size=2)
        ```
        
        ![Interaction with gender. Apart from charts with Ceteris Paribus Profiles (top of the visualisation), we can plot a table with observations used to calculate these profiles (bottom of the visualisation).](misc/titanic_interactions_average.png)
        
        There are two distinct clusters of passengers determined with their gender, therefore a *PDP* average plot (on grey) does not show the whole picture. Children of both genders were likely to survive, but then we see a large gap. Also, being female increased the chance of survival mostly for second and first class passengers.
        
        Plot function comes with extensive customization options. List of all parameters might be found in the documentation. Additionally, one can interact with the plot by hovering over a point of interest to see more details. Similarly, there is an interactive table with options for highlighting relevant elements as well as filtering and sorting rows.
        
        
        
        ### Multiclass models - Iris dataset
        Prepare dataset and model
        ```python
        iris = load_iris()
        
        def random_forest_classifier():
            rf_model = RandomForestClassifier(n_estimators=100, random_state=42)
            rf_model.fit(iris['data'], iris['target'])
            return rf_model, iris['data'], iris['target'], iris['feature_names']
        ```
        
        Wrap model into explainers
        ```python
        rf_model, iris_x, iris_y, iris_var_names = random_forest_classifier()
        
        explainer_rf1 = explain(rf_model, iris_var_names, iris_x, iris_y,
                               predict_function= lambda X: rf_model.predict_proba(X)[::, 0], label=iris.target_names[0])
        explainer_rf2 = explain(rf_model, iris_var_names, iris_x, iris_y,
                               predict_function= lambda X: rf_model.predict_proba(X)[::, 1], label=iris.target_names[1])
        explainer_rf3 = explain(rf_model, iris_var_names, iris_x, iris_y,
                               predict_function= lambda X: rf_model.predict_proba(X)[::, 2], label=iris.target_names[2])
        ```
        
        Calculate profiles and plot
        ```python
        cp_rf1 = individual_variable_profile(explainer_rf1, iris_x[0], iris_y[0])
        cp_rf2 = individual_variable_profile(explainer_rf2, iris_x[0], iris_y[0])
        cp_rf3 = individual_variable_profile(explainer_rf3, iris_x[0], iris_y[0])
        
        plot(cp_rf1, cp_rf2, cp_rf3, selected_variables=['petal length (cm)', 'petal width (cm)', 'sepal length (cm)'])
        ```
        ![Multiclass models](misc/multiclass_models.png)
        
        ## Contributing
        You're more than welcomed to contribute to this package. See the [guideline](CONTRIBUTING.md).
        
        ## Acknowledgments
        Work on this package was financially supported by the ‘NCN Opus grant 2016/21/B/ST6/0217’.
        
Platform: UNKNOWN
Classifier: Intended Audience :: Science/Research
Classifier: Intended Audience :: Developers
Classifier: License :: OSI Approved :: Apache Software License
Classifier: Operating System :: OS Independent
Classifier: Programming Language :: Python :: 3
Classifier: Programming Language :: Python :: 3.5
Classifier: Programming Language :: Python :: 3.6
Classifier: Programming Language :: Python :: 3.7
Classifier: Topic :: Scientific/Engineering :: Artificial Intelligence
Classifier: Topic :: Scientific/Engineering :: Visualization
Description-Content-Type: text/markdown
