""" ================================================================= Selecting dimensionality reduction with Pipeline and GridSearchCV ================================================================= This example constructs a pipeline that does dimensionality reduction followed by prediction with a support vector classifier. It demonstrates the use of ``GridSearchCV`` and ``Pipeline`` to optimize over different classes of estimators in a single CV run -- unsupervised ``PCA`` and ``NMF`` dimensionality reductions are compared to univariate feature selection during the grid search. Additionally, ``Pipeline`` can be instantiated with the ``memory`` argument to memoize the transformers within the pipeline, avoiding to fit again the same transformers over and over. Note that the use of ``memory`` to enable caching becomes interesting when the fitting of a transformer is costly. """ # Authors: Robert McGibbon # Joel Nothman # Guillaume Lemaitre # %% # Illustration of ``Pipeline`` and ``GridSearchCV`` ############################################################################### import matplotlib.pyplot as plt import numpy as np from sklearn.datasets import load_digits from sklearn.decomposition import NMF, PCA from sklearn.feature_selection import SelectKBest, mutual_info_classif from sklearn.model_selection import GridSearchCV from sklearn.pipeline import Pipeline from sklearn.preprocessing import MinMaxScaler from sklearn.svm import LinearSVC X, y = load_digits(return_X_y=True) pipe = Pipeline( [ ("scaling", MinMaxScaler()), # the reduce_dim stage is populated by the param_grid ("reduce_dim", "passthrough"), ("classify", LinearSVC(dual=False, max_iter=10000)), ] ) N_FEATURES_OPTIONS = [2, 4, 8] C_OPTIONS = [1, 10, 100, 1000] param_grid = [ { "reduce_dim": [PCA(iterated_power=7), NMF(max_iter=1_000)], "reduce_dim__n_components": N_FEATURES_OPTIONS, "classify__C": C_OPTIONS, }, { "reduce_dim": [SelectKBest(mutual_info_classif)], "reduce_dim__k": N_FEATURES_OPTIONS, "classify__C": C_OPTIONS, }, ] reducer_labels = ["PCA", "NMF", "KBest(mutual_info_classif)"] grid = GridSearchCV(pipe, n_jobs=1, param_grid=param_grid) grid.fit(X, y) # %% import pandas as pd mean_scores = np.array(grid.cv_results_["mean_test_score"]) # scores are in the order of param_grid iteration, which is alphabetical mean_scores = mean_scores.reshape(len(C_OPTIONS), -1, len(N_FEATURES_OPTIONS)) # select score for best C mean_scores = mean_scores.max(axis=0) # create a dataframe to ease plotting mean_scores = pd.DataFrame( mean_scores.T, index=N_FEATURES_OPTIONS, columns=reducer_labels ) ax = mean_scores.plot.bar() ax.set_title("Comparing feature reduction techniques") ax.set_xlabel("Reduced number of features") ax.set_ylabel("Digit classification accuracy") ax.set_ylim((0, 1)) ax.legend(loc="upper left") plt.show() # %% # Caching transformers within a ``Pipeline`` ############################################################################### # It is sometimes worthwhile storing the state of a specific transformer # since it could be used again. Using a pipeline in ``GridSearchCV`` triggers # such situations. Therefore, we use the argument ``memory`` to enable caching. # # .. warning:: # Note that this example is, however, only an illustration since for this # specific case fitting PCA is not necessarily slower than loading the # cache. Hence, use the ``memory`` constructor parameter when the fitting # of a transformer is costly. from shutil import rmtree from joblib import Memory # Create a temporary folder to store the transformers of the pipeline location = "cachedir" memory = Memory(location=location, verbose=10) cached_pipe = Pipeline( [("reduce_dim", PCA()), ("classify", LinearSVC(dual=False, max_iter=10000))], memory=memory, ) # This time, a cached pipeline will be used within the grid search # Delete the temporary cache before exiting memory.clear(warn=False) rmtree(location) # %% # The ``PCA`` fitting is only computed at the evaluation of the first # configuration of the ``C`` parameter of the ``LinearSVC`` classifier. The # other configurations of ``C`` will trigger the loading of the cached ``PCA`` # estimator data, leading to save processing time. Therefore, the use of # caching the pipeline using ``memory`` is highly beneficial when fitting # a transformer is costly.