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The Waikato Environment for Knowledge Analysis (WEKA), a machine
learning workbench. This version represents the developer version, the
"bleeding edge" of development, you could say. New functionality gets added
to this version.
/*
* This program is free software: you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation, either version 3 of the License, or
* (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program. If not, see .
*/
/*
* MultiClassClassifier.java
* Copyright (C) 1999-2012 University of Waikato, Hamilton, New Zealand
*
*/
package weka.classifiers.meta;
import java.io.Serializable;
import java.util.ArrayList;
import java.util.Collections;
import java.util.Enumeration;
import java.util.Random;
import java.util.Vector;
import weka.classifiers.AbstractClassifier;
import weka.classifiers.Classifier;
import weka.classifiers.RandomizableSingleClassifierEnhancer;
import weka.classifiers.rules.ZeroR;
import weka.core.Attribute;
import weka.core.Capabilities;
import weka.core.Capabilities.Capability;
import weka.core.Instance;
import weka.core.Instances;
import weka.core.Option;
import weka.core.OptionHandler;
import weka.core.Range;
import weka.core.RevisionHandler;
import weka.core.RevisionUtils;
import weka.core.SelectedTag;
import weka.core.Tag;
import weka.core.Utils;
import weka.filters.Filter;
import weka.filters.unsupervised.attribute.MakeIndicator;
import weka.filters.unsupervised.instance.RemoveWithValues;
/**
* A metaclassifier for handling multi-class datasets with 2-class classifiers. This classifier is also capable of applying error correcting output codes for increased accuracy.
*
*
* Valid options are:
*
* -M <num>
* Sets the method to use. Valid values are 0 (1-against-all),
* 1 (random codes), 2 (exhaustive code), and 3 (1-against-1). (default 0)
*
*
* -R <num>
* Sets the multiplier when using random codes. (default 2.0)
*
* -P
* Use pairwise coupling (only has an effect for 1-against1)
*
* -S <num>
* Random number seed.
* (default 1)
*
* -D
* If set, classifier is run in debug mode and
* may output additional info to the console
*
* -W
* Full name of base classifier.
* (default: weka.classifiers.functions.Logistic)
*
*
* Options specific to classifier weka.classifiers.functions.Logistic:
*
*
* -D
* Turn on debugging output.
*
* -R <ridge>
* Set the ridge in the log-likelihood.
*
* -M <number>
* Set the maximum number of iterations (default -1, until convergence).
*
*
* @author Eibe Frank ([email protected])
* @author Len Trigg ([email protected])
* @author Richard Kirkby ([email protected])
* @version $Revision: 10649 $
*/
public class MultiClassClassifier
extends RandomizableSingleClassifierEnhancer
implements OptionHandler {
/** for serialization */
static final long serialVersionUID = -3879602011542849141L;
/** The classifiers. */
protected Classifier [] m_Classifiers;
/** Use pairwise coupling with 1-vs-1 */
protected boolean m_pairwiseCoupling = false;
/** Needed for pairwise coupling */
protected double [] m_SumOfWeights;
/** The filters used to transform the class. */
protected Filter[] m_ClassFilters;
/** ZeroR classifier for when all base classifier return zero probability. */
private ZeroR m_ZeroR;
/** Internal copy of the class attribute for output purposes */
protected Attribute m_ClassAttribute;
/** A transformed dataset header used by the 1-against-1 method */
protected Instances m_TwoClassDataset;
/**
* The multiplier when generating random codes. Will generate
* numClasses * m_RandomWidthFactor codes
*/
private double m_RandomWidthFactor = 2.0;
/** The multiclass method to use */
protected int m_Method = METHOD_1_AGAINST_ALL;
/** 1-against-all */
public static final int METHOD_1_AGAINST_ALL = 0;
/** random correction code */
public static final int METHOD_ERROR_RANDOM = 1;
/** exhaustive correction code */
public static final int METHOD_ERROR_EXHAUSTIVE = 2;
/** 1-against-1 */
public static final int METHOD_1_AGAINST_1 = 3;
/** The error correction modes */
public static final Tag [] TAGS_METHOD = {
new Tag(METHOD_1_AGAINST_ALL, "1-against-all"),
new Tag(METHOD_ERROR_RANDOM, "Random correction code"),
new Tag(METHOD_ERROR_EXHAUSTIVE, "Exhaustive correction code"),
new Tag(METHOD_1_AGAINST_1, "1-against-1")
};
/**
* Constructor.
*/
public MultiClassClassifier() {
m_Classifier = new weka.classifiers.functions.Logistic();
}
/**
* String describing default classifier.
*
* @return the default classifier classname
*/
protected String defaultClassifierString() {
return "weka.classifiers.functions.Logistic";
}
/**
* Interface for the code constructors
*/
private abstract class Code
implements Serializable, RevisionHandler {
/** for serialization */
static final long serialVersionUID = 418095077487120846L;
/**
* Subclasses must allocate and fill these.
* First dimension is number of codes.
* Second dimension is number of classes.
*/
protected boolean [][]m_Codebits;
/**
* Returns the number of codes.
* @return the number of codes
*/
public int size() {
return m_Codebits.length;
}
/**
* Returns the indices of the values set to true for this code,
* using 1-based indexing (for input to Range).
*
* @param which the index
* @return the 1-based indices
*/
public String getIndices(int which) {
StringBuffer sb = new StringBuffer();
for (int i = 0; i < m_Codebits[which].length; i++) {
if (m_Codebits[which][i]) {
if (sb.length() != 0) {
sb.append(',');
}
sb.append(i + 1);
}
}
return sb.toString();
}
/**
* Returns a human-readable representation of the codes.
* @return a string representation of the codes
*/
public String toString() {
StringBuffer sb = new StringBuffer();
for(int i = 0; i < m_Codebits[0].length; i++) {
for (int j = 0; j < m_Codebits.length; j++) {
sb.append(m_Codebits[j][i] ? " 1" : " 0");
}
sb.append('\n');
}
return sb.toString();
}
/**
* Returns the revision string.
*
* @return the revision
*/
public String getRevision() {
return RevisionUtils.extract("$Revision: 10649 $");
}
}
/**
* Constructs a code with no error correction
*/
private class StandardCode
extends Code {
/** for serialization */
static final long serialVersionUID = 3707829689461467358L;
/**
* constructor
*
* @param numClasses the number of classes
*/
public StandardCode(int numClasses) {
m_Codebits = new boolean[numClasses][numClasses];
for (int i = 0; i < numClasses; i++) {
m_Codebits[i][i] = true;
}
//System.err.println("Code:\n" + this);
}
/**
* Returns the revision string.
*
* @return the revision
*/
public String getRevision() {
return RevisionUtils.extract("$Revision: 10649 $");
}
}
/**
* Constructs a random code assignment
*/
private class RandomCode
extends Code {
/** for serialization */
static final long serialVersionUID = 4413410540703926563L;
/** random number generator */
Random r = null;
/**
* constructor
*
* @param numClasses the number of classes
* @param numCodes the number of codes
* @param data the data to use
*/
public RandomCode(int numClasses, int numCodes, Instances data) {
r = data.getRandomNumberGenerator(m_Seed);
numCodes = Math.max(2, numCodes); // Need at least two classes
m_Codebits = new boolean[numCodes][numClasses];
int i = 0;
do {
randomize();
//System.err.println(this);
} while (!good() && (i++ < 100));
//System.err.println("Code:\n" + this);
}
private boolean good() {
boolean [] ninClass = new boolean[m_Codebits[0].length];
boolean [] ainClass = new boolean[m_Codebits[0].length];
for (int i = 0; i < ainClass.length; i++) {
ainClass[i] = true;
}
for (int i = 0; i < m_Codebits.length; i++) {
boolean ninCode = false;
boolean ainCode = true;
for (int j = 0; j < m_Codebits[i].length; j++) {
boolean current = m_Codebits[i][j];
ninCode = ninCode || current;
ainCode = ainCode && current;
ninClass[j] = ninClass[j] || current;
ainClass[j] = ainClass[j] && current;
}
if (!ninCode || ainCode) {
return false;
}
}
for (int j = 0; j < ninClass.length; j++) {
if (!ninClass[j] || ainClass[j]) {
return false;
}
}
return true;
}
/**
* randomizes
*/
private void randomize() {
for (int i = 0; i < m_Codebits.length; i++) {
for (int j = 0; j < m_Codebits[i].length; j++) {
double temp = r.nextDouble();
m_Codebits[i][j] = (temp < 0.5) ? false : true;
}
}
}
/**
* Returns the revision string.
*
* @return the revision
*/
public String getRevision() {
return RevisionUtils.extract("$Revision: 10649 $");
}
}
/*
* TODO: Constructs codes as per:
* Bose, R.C., Ray Chaudhuri (1960), On a class of error-correcting
* binary group codes, Information and Control, 3, 68-79.
* Hocquenghem, A. (1959) Codes corecteurs d'erreurs, Chiffres, 2, 147-156.
*/
//private class BCHCode extends Code {...}
/** Constructs an exhaustive code assignment */
private class ExhaustiveCode
extends Code {
/** for serialization */
static final long serialVersionUID = 8090991039670804047L;
/**
* constructor
*
* @param numClasses the number of classes
*/
public ExhaustiveCode(int numClasses) {
int width = (int)Math.pow(2, numClasses - 1) - 1;
m_Codebits = new boolean[width][numClasses];
for (int j = 0; j < width; j++) {
m_Codebits[j][0] = true;
}
for (int i = 1; i < numClasses; i++) {
int skip = (int) Math.pow(2, numClasses - (i + 1));
for(int j = 0; j < width; j++) {
m_Codebits[j][i] = ((j / skip) % 2 != 0);
}
}
//System.err.println("Code:\n" + this);
}
/**
* Returns the revision string.
*
* @return the revision
*/
public String getRevision() {
return RevisionUtils.extract("$Revision: 10649 $");
}
}
/**
* Returns default capabilities of the classifier.
*
* @return the capabilities of this classifier
*/
public Capabilities getCapabilities() {
Capabilities result = super.getCapabilities();
// class
result.disableAllClasses();
result.disableAllClassDependencies();
result.enable(Capability.NOMINAL_CLASS);
return result;
}
/**
* Builds the classifiers.
*
* @param insts the training data.
* @throws Exception if a classifier can't be built
*/
public void buildClassifier(Instances insts) throws Exception {
Instances newInsts;
// can classifier handle the data?
getCapabilities().testWithFail(insts);
// zero training instances - could be incremental
boolean zeroTrainingInstances = insts.numInstances() == 0;
// remove instances with missing class
insts = new Instances(insts);
insts.deleteWithMissingClass();
if (m_Classifier == null) {
throw new Exception("No base classifier has been set!");
}
m_ZeroR = new ZeroR();
m_ZeroR.buildClassifier(insts);
m_TwoClassDataset = null;
int numClassifiers = insts.numClasses();
if (numClassifiers <= 2) {
m_Classifiers = AbstractClassifier.makeCopies(m_Classifier, 1);
m_Classifiers[0].buildClassifier(insts);
m_ClassFilters = null;
} else if (m_Method == METHOD_1_AGAINST_1) {
// generate fastvector of pairs
ArrayListpairs = new ArrayList();
for (int i=0; i 0 || zeroTrainingInstances) {
newInsts.setClassIndex(insts.classIndex());
m_Classifiers[i].buildClassifier(newInsts);
m_ClassFilters[i] = classFilter;
m_SumOfWeights[i] = newInsts.sumOfWeights();
} else {
m_Classifiers[i] = null;
m_ClassFilters[i] = null;
}
}
// construct a two-class header version of the dataset
m_TwoClassDataset = new Instances(insts, 0);
int classIndex = m_TwoClassDataset.classIndex();
m_TwoClassDataset.setClassIndex(-1);
ArrayList classLabels = new ArrayList();
classLabels.add("class0");
classLabels.add("class1");
m_TwoClassDataset.replaceAttributeAt(new Attribute("class", classLabels),
classIndex);
m_TwoClassDataset.setClassIndex(classIndex);
} else { // use error correcting code style methods
Code code = null;
switch (m_Method) {
case METHOD_ERROR_EXHAUSTIVE:
code = new ExhaustiveCode(numClassifiers);
break;
case METHOD_ERROR_RANDOM:
code = new RandomCode(numClassifiers,
(int)(numClassifiers * m_RandomWidthFactor),
insts);
break;
case METHOD_1_AGAINST_ALL:
code = new StandardCode(numClassifiers);
break;
default:
throw new Exception("Unrecognized correction code type");
}
numClassifiers = code.size();
m_Classifiers = AbstractClassifier.makeCopies(m_Classifier, numClassifiers);
m_ClassFilters = new MakeIndicator[numClassifiers];
for (int i = 0; i < m_Classifiers.length; i++) {
m_ClassFilters[i] = new MakeIndicator();
MakeIndicator classFilter = (MakeIndicator) m_ClassFilters[i];
classFilter.setAttributeIndex("" + (insts.classIndex() + 1));
classFilter.setValueIndices(code.getIndices(i));
classFilter.setNumeric(false);
classFilter.setInputFormat(insts);
newInsts = Filter.useFilter(insts, m_ClassFilters[i]);
m_Classifiers[i].buildClassifier(newInsts);
}
}
m_ClassAttribute = insts.classAttribute();
}
/**
* Returns the individual predictions of the base classifiers
* for an instance. Used by StackedMultiClassClassifier.
* Returns the probability for the second "class" predicted
* by each base classifier.
*
* @param inst the instance to get the prediction for
* @return the individual predictions
* @throws Exception if the predictions can't be computed successfully
*/
public double[] individualPredictions(Instance inst) throws Exception {
double[] result = null;
if (m_Classifiers.length == 1) {
result = new double[1];
result[0] = m_Classifiers[0].distributionForInstance(inst)[1];
} else {
result = new double[m_ClassFilters.length];
for(int i = 0; i < m_ClassFilters.length; i++) {
if (m_Classifiers[i] != null) {
if (m_Method == METHOD_1_AGAINST_1) {
Instance tempInst = (Instance)inst.copy();
tempInst.setDataset(m_TwoClassDataset);
result[i] = m_Classifiers[i].distributionForInstance(tempInst)[1];
} else {
m_ClassFilters[i].input(inst);
m_ClassFilters[i].batchFinished();
result[i] = m_Classifiers[i].
distributionForInstance(m_ClassFilters[i].output())[1];
}
}
}
}
return result;
}
/**
* Returns the distribution for an instance.
*
* @param inst the instance to get the distribution for
* @return the distribution
* @throws Exception if the distribution can't be computed successfully
*/
public double[] distributionForInstance(Instance inst) throws Exception {
if (m_Classifiers.length == 1) {
return m_Classifiers[0].distributionForInstance(inst);
}
double[] probs = new double[inst.numClasses()];
if (m_Method == METHOD_1_AGAINST_1) {
double[][] r = new double[inst.numClasses()][inst.numClasses()];
double[][] n = new double[inst.numClasses()][inst.numClasses()];
for(int i = 0; i < m_ClassFilters.length; i++) {
if (m_Classifiers[i] != null) {
Instance tempInst = (Instance)inst.copy();
tempInst.setDataset(m_TwoClassDataset);
double [] current = m_Classifiers[i].distributionForInstance(tempInst);
Range range = new Range(((RemoveWithValues)m_ClassFilters[i])
.getNominalIndices());
range.setUpper(m_ClassAttribute.numValues());
int[] pair = range.getSelection();
if (m_pairwiseCoupling && inst.numClasses() > 2) {
r[pair[0]][pair[1]] = current[0];
n[pair[0]][pair[1]] = m_SumOfWeights[i];
} else {
if (current[0] > current[1]) {
probs[pair[0]] += 1.0;
} else {
probs[pair[1]] += 1.0;
}
}
}
}
if (m_pairwiseCoupling && inst.numClasses() > 2) {
return pairwiseCoupling(n, r);
}
} else {
// error correcting style methods
for(int i = 0; i < m_ClassFilters.length; i++) {
m_ClassFilters[i].input(inst);
m_ClassFilters[i].batchFinished();
double [] current = m_Classifiers[i].
distributionForInstance(m_ClassFilters[i].output());
for (int j = 0; j < m_ClassAttribute.numValues(); j++) {
if (((MakeIndicator)m_ClassFilters[i]).getValueRange().isInRange(j)) {
probs[j] += current[1];
} else {
probs[j] += current[0];
}
}
}
}
if (Utils.gr(Utils.sum(probs), 0)) {
Utils.normalize(probs);
return probs;
} else {
return m_ZeroR.distributionForInstance(inst);
}
}
/**
* Prints the classifiers.
*
* @return a string representation of the classifier
*/
public String toString() {
if (m_Classifiers == null) {
return "MultiClassClassifier: No model built yet.";
}
StringBuffer text = new StringBuffer();
text.append("MultiClassClassifier\n\n");
for (int i = 0; i < m_Classifiers.length; i++) {
text.append("Classifier ").append(i + 1);
if (m_Classifiers[i] != null) {
if ((m_ClassFilters != null) && (m_ClassFilters[i] != null)) {
if (m_ClassFilters[i] instanceof RemoveWithValues) {
Range range = new Range(((RemoveWithValues)m_ClassFilters[i])
.getNominalIndices());
range.setUpper(m_ClassAttribute.numValues());
int[] pair = range.getSelection();
text.append(", " + (pair[0]+1) + " vs " + (pair[1]+1));
} else if (m_ClassFilters[i] instanceof MakeIndicator) {
text.append(", using indicator values: ");
text.append(((MakeIndicator)m_ClassFilters[i]).getValueRange());
}
}
text.append('\n');
text.append(m_Classifiers[i].toString() + "\n\n");
} else {
text.append(" Skipped (no training examples)\n");
}
}
return text.toString();
}
/**
* Returns an enumeration describing the available options
*
* @return an enumeration of all the available options
*/
public Enumeration
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