156 lines
5.6 KiB
Python
156 lines
5.6 KiB
Python
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"""
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=============================================
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Early stopping of Stochastic Gradient Descent
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=============================================
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Stochastic Gradient Descent is an optimization technique which minimizes a loss
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function in a stochastic fashion, performing a gradient descent step sample by
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sample. In particular, it is a very efficient method to fit linear models.
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As a stochastic method, the loss function is not necessarily decreasing at each
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iteration, and convergence is only guaranteed in expectation. For this reason,
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monitoring the convergence on the loss function can be difficult.
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Another approach is to monitor convergence on a validation score. In this case,
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the input data is split into a training set and a validation set. The model is
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then fitted on the training set and the stopping criterion is based on the
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prediction score computed on the validation set. This enables us to find the
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least number of iterations which is sufficient to build a model that
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generalizes well to unseen data and reduces the chance of over-fitting the
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training data.
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This early stopping strategy is activated if ``early_stopping=True``; otherwise
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the stopping criterion only uses the training loss on the entire input data. To
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better control the early stopping strategy, we can specify a parameter
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``validation_fraction`` which set the fraction of the input dataset that we
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keep aside to compute the validation score. The optimization will continue
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until the validation score did not improve by at least ``tol`` during the last
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``n_iter_no_change`` iterations. The actual number of iterations is available
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at the attribute ``n_iter_``.
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This example illustrates how the early stopping can used in the
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:class:`~sklearn.linear_model.SGDClassifier` model to achieve almost the same
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accuracy as compared to a model built without early stopping. This can
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significantly reduce training time. Note that scores differ between the
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stopping criteria even from early iterations because some of the training data
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is held out with the validation stopping criterion.
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"""
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# Authors: Tom Dupre la Tour
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#
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# License: BSD 3 clause
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import sys
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import time
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import matplotlib.pyplot as plt
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import numpy as np
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import pandas as pd
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from sklearn import linear_model
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from sklearn.datasets import fetch_openml
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from sklearn.exceptions import ConvergenceWarning
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from sklearn.model_selection import train_test_split
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from sklearn.utils import shuffle
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from sklearn.utils._testing import ignore_warnings
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def load_mnist(n_samples=None, class_0="0", class_1="8"):
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"""Load MNIST, select two classes, shuffle and return only n_samples."""
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# Load data from http://openml.org/d/554
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mnist = fetch_openml("mnist_784", version=1, as_frame=False)
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# take only two classes for binary classification
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mask = np.logical_or(mnist.target == class_0, mnist.target == class_1)
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X, y = shuffle(mnist.data[mask], mnist.target[mask], random_state=42)
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if n_samples is not None:
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X, y = X[:n_samples], y[:n_samples]
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return X, y
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@ignore_warnings(category=ConvergenceWarning)
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def fit_and_score(estimator, max_iter, X_train, X_test, y_train, y_test):
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"""Fit the estimator on the train set and score it on both sets"""
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estimator.set_params(max_iter=max_iter)
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estimator.set_params(random_state=0)
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start = time.time()
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estimator.fit(X_train, y_train)
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fit_time = time.time() - start
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n_iter = estimator.n_iter_
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train_score = estimator.score(X_train, y_train)
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test_score = estimator.score(X_test, y_test)
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return fit_time, n_iter, train_score, test_score
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# Define the estimators to compare
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estimator_dict = {
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"No stopping criterion": linear_model.SGDClassifier(n_iter_no_change=3),
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"Training loss": linear_model.SGDClassifier(
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early_stopping=False, n_iter_no_change=3, tol=0.1
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),
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"Validation score": linear_model.SGDClassifier(
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early_stopping=True, n_iter_no_change=3, tol=0.0001, validation_fraction=0.2
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),
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}
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# Load the dataset
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X, y = load_mnist(n_samples=10000)
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X_train, X_test, y_train, y_test = train_test_split(X, y, test_size=0.5, random_state=0)
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results = []
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for estimator_name, estimator in estimator_dict.items():
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print(estimator_name + ": ", end="")
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for max_iter in range(1, 50):
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print(".", end="")
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sys.stdout.flush()
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fit_time, n_iter, train_score, test_score = fit_and_score(
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estimator, max_iter, X_train, X_test, y_train, y_test
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)
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results.append(
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(estimator_name, max_iter, fit_time, n_iter, train_score, test_score)
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)
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print("")
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# Transform the results in a pandas dataframe for easy plotting
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columns = [
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"Stopping criterion",
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"max_iter",
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"Fit time (sec)",
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"n_iter_",
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"Train score",
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"Test score",
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]
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results_df = pd.DataFrame(results, columns=columns)
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# Define what to plot
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lines = "Stopping criterion"
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x_axis = "max_iter"
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styles = ["-.", "--", "-"]
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# First plot: train and test scores
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fig, axes = plt.subplots(nrows=1, ncols=2, sharey=True, figsize=(12, 4))
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for ax, y_axis in zip(axes, ["Train score", "Test score"]):
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for style, (criterion, group_df) in zip(styles, results_df.groupby(lines)):
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group_df.plot(x=x_axis, y=y_axis, label=criterion, ax=ax, style=style)
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ax.set_title(y_axis)
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ax.legend(title=lines)
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fig.tight_layout()
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# Second plot: n_iter and fit time
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fig, axes = plt.subplots(nrows=1, ncols=2, figsize=(12, 4))
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for ax, y_axis in zip(axes, ["n_iter_", "Fit time (sec)"]):
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for style, (criterion, group_df) in zip(styles, results_df.groupby(lines)):
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group_df.plot(x=x_axis, y=y_axis, label=criterion, ax=ax, style=style)
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ax.set_title(y_axis)
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ax.legend(title=lines)
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fig.tight_layout()
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plt.show()
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