""" ======================================================== Classification of text documents: using a MLComp dataset ======================================================== This is an example showing how the scikit-learn can be used to classify documents by topics using a bag-of-words approach. This example uses a scipy.sparse matrix to store the features instead of standard numpy arrays. The dataset used in this example is the 20 newsgroups dataset and should be downloaded from the http://mlcomp.org (free registration required): http://mlcomp.org/datasets/379 Once downloaded unzip the archive somewhere on your filesystem. For instance in:: % mkdir -p ~/data/mlcomp % cd ~/data/mlcomp % unzip /path/to/dataset-379-20news-18828_XXXXX.zip You should get a folder ``~/data/mlcomp/379`` with a file named ``metadata`` and subfolders ``raw``, ``train`` and ``test`` holding the text documents organized by newsgroups. Then set the ``MLCOMP_DATASETS_HOME`` environment variable pointing to the root folder holding the uncompressed archive:: % export MLCOMP_DATASETS_HOME="~/data/mlcomp" Then you are ready to run this example using your favorite python shell:: % ipython examples/mlcomp_sparse_document_classification.py """ print __doc__ # Author: Olivier Grisel # License: Simplified BSD from time import time import sys import os import numpy as np import scipy.sparse as sp import pylab as pl from sklearn.datasets import load_mlcomp from sklearn.feature_extraction.text import TfidfVectorizer from sklearn.linear_model import SGDClassifier from sklearn.metrics import confusion_matrix from sklearn.metrics import classification_report from sklearn.naive_bayes import MultinomialNB if 'MLCOMP_DATASETS_HOME' not in os.environ: print "MLCOMP_DATASETS_HOME not set; please follow the above instructions" sys.exit(0) # Load the training set print "Loading 20 newsgroups training set... " news_train = load_mlcomp('20news-18828', 'train') print news_train.DESCR print "%d documents" % len(news_train.filenames) print "%d categories" % len(news_train.target_names) print "Extracting features from the dataset using a sparse vectorizer" t0 = time() vectorizer = TfidfVectorizer(charset='latin1') X_train = vectorizer.fit_transform((open(f).read() for f in news_train.filenames)) print "done in %fs" % (time() - t0) print "n_samples: %d, n_features: %d" % X_train.shape assert sp.issparse(X_train) y_train = news_train.target print "Loading 20 newsgroups test set... " news_test = load_mlcomp('20news-18828', 'test') t0 = time() print "done in %fs" % (time() - t0) print "Predicting the labels of the test set..." print "%d documents" % len(news_test.filenames) print "%d categories" % len(news_test.target_names) print "Extracting features from the dataset using the same vectorizer" t0 = time() X_test = vectorizer.transform((open(f).read() for f in news_test.filenames)) y_test = news_test.target print "done in %fs" % (time() - t0) print "n_samples: %d, n_features: %d" % X_test.shape ############################################################################### # Benchmark classifiers def benchmark(clf_class, params, name): print "parameters:", params t0 = time() clf = clf_class(**params).fit(X_train, y_train) print "done in %fs" % (time() - t0) if hasattr(clf, 'coef_'): print "Percentage of non zeros coef: %f" % ( np.mean(clf.coef_ != 0) * 100) print "Predicting the outcomes of the testing set" t0 = time() pred = clf.predict(X_test) print "done in %fs" % (time() - t0) print "Classification report on test set for classifier:" print clf print print classification_report(y_test, pred, target_names=news_test.target_names) cm = confusion_matrix(y_test, pred) print "Confusion matrix:" print cm # Show confusion matrix pl.matshow(cm) pl.title('Confusion matrix of the %s classifier' % name) pl.colorbar() print "Testbenching a linear classifier..." parameters = { 'loss': 'hinge', 'penalty': 'l2', 'n_iter': 50, 'alpha': 0.00001, 'fit_intercept': True, } benchmark(SGDClassifier, parameters, 'SGD') print "Testbenching a MultinomialNB classifier..." parameters = {'alpha': 0.01} benchmark(MultinomialNB, parameters, 'MultinomialNB') pl.show()