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source: branches/ClassificationModelComparison/HeuristicLab.Algorithms.DataAnalysis/3.4/Linear/OneR.cs @ 9135

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Last change on this file since 9135 was 9135, checked in by sforsten, 11 years ago

OneR handles missing values separately
adapted OneRClassificationModelView to show the class of missing values
with a double-click on the row header in ClassificationSolutionComparisonView the selected solution opens in a new view
put a try catch block around linear discriminant analysis solution (it is only shown, if it doesn't throw an exception)

File size: 11.2 KB

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1	#region License Information
2	/* HeuristicLab
3	* Copyright (C) 2002-2012 Heuristic and Evolutionary Algorithms Laboratory (HEAL)
4	*
5	* This file is part of HeuristicLab.
6	*
7	* HeuristicLab is free software: you can redistribute it and/or modify
8	* it under the terms of the GNU General Public License as published by
9	* the Free Software Foundation, either version 3 of the License, or
10	* (at your option) any later version.
11	*
12	* HeuristicLab is distributed in the hope that it will be useful,
13	* but WITHOUT ANY WARRANTY; without even the implied warranty of
14	* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
15	* GNU General Public License for more details.
16	*
17	* You should have received a copy of the GNU General Public License
18	* along with HeuristicLab. If not, see <http://www.gnu.org/licenses/>.
19	*/
20	#endregion
21
22	using System;
23	using System.Collections.Generic;
24	using System.Linq;
25	using HeuristicLab.Common;
26	using HeuristicLab.Core;
27	using HeuristicLab.Data;
28	using HeuristicLab.Optimization;
29	using HeuristicLab.Parameters;
30	using HeuristicLab.Persistence.Default.CompositeSerializers.Storable;
31	using HeuristicLab.Problems.DataAnalysis;
32	using HeuristicLab.Random;
33
34	namespace HeuristicLab.Algorithms.DataAnalysis {
35	/// <summary>
36	/// 1R classification algorithm.
37	/// </summary>
38	[Item("OneR", "1R classification algorithm.")]
39	[Creatable("Data Analysis")]
40	[StorableClass]
41	public sealed class OneR : FixedDataAnalysisAlgorithm<IClassificationProblem> {
42
43	public IValueParameter<IntValue> MinBucketSizeParameter {
44	get { return (IValueParameter<IntValue>)Parameters["MinBucketSize"]; }
45	}
46	public IValueParameter<IRandom> RandomParameter {
47	get { return (IValueParameter<IRandom>)Parameters["Random"]; }
48	}
49
50	[StorableConstructor]
51	private OneR(bool deserializing) : base(deserializing) { }
52	private OneR(OneR original, Cloner cloner)
53	: base(original, cloner) {
54	}
55	public OneR()
56	: base() {
57	Parameters.Add(new ValueParameter<IntValue>("MinBucketSize", "Minimum size of a bucket for numerical values. (Except for the rightmost bucket)", new IntValue(6)));
58	Parameters.Add(new ValueParameter<IRandom>("Random", "Random number generator", new FastRandom()));
59	Problem = new ClassificationProblem();
60	}
61
62	public override IDeepCloneable Clone(Cloner cloner) {
63	return new OneR(this, cloner);
64	}
65
66	protected override void Run() {
67	int blub = MinBucketSizeParameter.Value.Value;
68	Console.WriteLine(blub);
69	IRandom bla = RandomParameter.Value;
70	Console.WriteLine(bla);
71	var solution = CreateOneRSolution(Problem.ProblemData, MinBucketSizeParameter.Value.Value, RandomParameter.Value);
72	Results.Add(new Result("OneR solution", "The 1R classifier.", solution));
73	}
74
75	public static IClassificationSolution CreateOneRSolution(IClassificationProblemData problemData, int minBucketSize, IRandom random) {
76	Dataset dataset = problemData.Dataset;
77	var trainingIndices = problemData.TrainingIndices;
78	int rowCount = trainingIndices.Count();
79	string target = problemData.TargetVariable;
80	var inputVariables = problemData.AllowedInputVariables.ToArray();
81	var classValues = problemData.ClassValues.ToArray();
82	double dominatingClass;
83
84	string bestVariable = null;
85	Dictionary<double, double> bestSplits = null;
86	double missingValuesClass = double.NaN;
87	int correctClassified = 0;
88
89	for (int variable = 0; variable < inputVariables.Length; variable++) {
90	var inputVariableValues = dataset.GetDoubleValues(inputVariables[variable], trainingIndices).ToArray();
91	var classValuesInDataset = dataset.GetDoubleValues(target, trainingIndices).ToArray();
92
93	int curCorrectClassified = 0;
94	Dictionary<double, int> classCount = PrepareClassCountDictionary(classValues);
95	Array.Sort(inputVariableValues, classValuesInDataset);
96	double curSplit = Double.NegativeInfinity;
97	Dictionary<double, double> splits = new Dictionary<double, double>();
98	bool newBucket = true;
99	bool done = false;
100	int curRow = 0;
101
102	if (curRow < inputVariableValues.Length && Double.IsNaN(inputVariableValues[curRow])) {
103	while (curRow < inputVariableValues.Length && Double.IsNaN(inputVariableValues[curRow])) {
104	classCount[classValuesInDataset[curRow]] += 1;
105	curRow++;
106	}
107	if (ExistsDominatingClass(classCount, out dominatingClass)) {
108	missingValuesClass = dominatingClass;
109	} else {
110	missingValuesClass = GetRandomMaxClass(classCount, random);
111	}
112	correctClassified += classCount[missingValuesClass];
113	classCount = PrepareClassCountDictionary(classValues);
114	}
115	while (curRow < inputVariableValues.Length) {
116	if (newBucket) {
117	for (int i = 0; i < minBucketSize && curRow + i < inputVariableValues.Length; i++) {
118	classCount[classValuesInDataset[curRow + i]] += 1;
119	}
120	curRow += minBucketSize;
121	if (curRow >= inputVariableValues.Length) {
122	break;
123	}
124	curSplit = inputVariableValues[curRow];
125	curRow = SetCurRowToEndOfSplit(curRow, inputVariableValues, classValuesInDataset, classCount, curSplit);
126	newBucket = false;
127	}
128
129	if (ExistsDominatingClass(classCount, out dominatingClass)) {
130	while (curRow + 1 < classValuesInDataset.Length &&
131	IsNextSplitStillDominatingClass(curRow, inputVariableValues, classValuesInDataset, curSplit, dominatingClass)) {
132	curRow++;
133	curSplit = inputVariableValues[curRow];
134	classCount[classValuesInDataset[curRow]] += 1;
135	curRow = SetCurRowToEndOfSplit(curRow, inputVariableValues, classValuesInDataset, classCount, curSplit);
136	}
137
138	curCorrectClassified += classCount[dominatingClass];
139	done = curRow >= inputVariableValues.Length - 1;
140
141	if (done) {
142	curSplit = Double.PositiveInfinity;
143	splits.Add(curSplit, dominatingClass);
144	break;
145	}
146
147	curRow++;
148	//intervals exclude end
149	curSplit = inputVariableValues[curRow];
150	splits.Add(curSplit, dominatingClass);
151
152	//intervals include start
153	curSplit = inputVariableValues[curRow];
154	classCount = PrepareClassCountDictionary(classValues);
155	newBucket = true;
156	} else {
157	curSplit = inputVariableValues[curRow];
158	classCount[classValuesInDataset[curRow]] += 1;
159	curRow = SetCurRowToEndOfSplit(curRow, inputVariableValues, classValuesInDataset, classCount, curSplit);
160	}
161	}
162
163	if (!done) {
164	curSplit = Double.PositiveInfinity;
165	double randomClass = GetRandomMaxClass(classCount, random);
166	splits.Add(curSplit, randomClass);
167
168	curCorrectClassified += classCount[randomClass];
169	}
170
171	if (curCorrectClassified > correctClassified) {
172	bestVariable = inputVariables[variable];
173	bestSplits = splits;
174	}
175	}
176
177	//merge intervals to simplify symbolic expression tree
178	Dictionary<double, double> mergedSplits = MergeSplits(bestSplits);
179
180	var model = new OneRClassificationModel(bestVariable, mergedSplits.Keys.ToArray(), mergedSplits.Values.ToArray(), missingValuesClass);
181	var solution = new OneRClassificationSolution(model, (IClassificationProblemData)problemData.Clone());
182
183	return solution;
184	}
185
186	private static double GetRandomMaxClass(Dictionary<double, int> classCount, IRandom random) {
187	IList<double> possibleClasses = new List<double>();
188	int max = 0;
189	foreach (var item in classCount) {
190	if (max < item.Value) {
191	max = item.Value;
192	possibleClasses = new List<double>();
193	possibleClasses.Add(item.Key);
194	} else if (max == item.Value) {
195	possibleClasses.Add(item.Key);
196	}
197	}
198	int classindex = random.Next(possibleClasses.Count);
199	return possibleClasses[classindex];
200	}
201
202	private static bool IsNextSplitStillDominatingClass(int curRow, double[] inputVariableValues, double[] classValuesInDataset, double curSplit, double dominatingClass) {
203	if (curRow >= classValuesInDataset.Length) {
204	return false;
205	}
206	double nextSplit = inputVariableValues[curRow + 1];
207	int i = 1;
208	while (curRow + i < classValuesInDataset.Length
209	&& inputVariableValues[curRow + i] == nextSplit
210	&& classValuesInDataset[curRow + i] == dominatingClass) {
211	i++;
212	}
213	if (curRow + i >= classValuesInDataset.Length) {
214	return true;
215	}
216	if (inputVariableValues[curRow + i] != nextSplit) {
217	return true;
218	}
219	// the next split would also contain values of a class which
220	// is not dominating (classValuesInDataset[curRow + i] != dominatingClass)
221	return false;
222	}
223
224	// needed if variable contains the same value several times
225	private static int SetCurRowToEndOfSplit(int curRow, double[] inputVariableValues, double[] classValuesInDataset, Dictionary<double, int> classCount, double curSplit) {
226	while (curRow + 1 < inputVariableValues.Length && inputVariableValues[curRow + 1] == curSplit) {
227	curRow++;
228	classCount[classValuesInDataset[curRow]] += 1;
229	}
230	return curRow;
231	}
232
233	private static Dictionary<double, double> MergeSplits(Dictionary<double, double> bestSplits) {
234	Dictionary<double, double> mergedSplits = new Dictionary<double, double>();
235	double nextSplit, nextClass;
236	nextSplit = nextClass = double.NaN;
237	foreach (var item in bestSplits) {
238	if (Double.IsNaN(nextSplit)) {
239	nextSplit = item.Key;
240	nextClass = item.Value;
241	} else {
242	if (nextClass == item.Value) {
243	nextSplit = item.Key;
244	} else {
245	mergedSplits.Add(nextSplit, nextClass);
246	nextSplit = item.Key;
247	nextClass = item.Value;
248	}
249	}
250	}
251	mergedSplits.Add(nextSplit, nextClass);
252	return mergedSplits;
253	}
254
255	private static bool ExistsDominatingClass(Dictionary<double, int> classCount, out double dominatingClass) {
256	bool dominating = false;
257	int count = 0;
258	dominatingClass = double.NaN;
259	foreach (var item in classCount) {
260	if (item.Value > count) {
261	dominatingClass = item.Key;
262	count = item.Value;
263	dominating = true;
264	} else if (item.Value == count) {
265	dominatingClass = double.NaN;
266	dominating = false;
267	}
268	}
269	return dominating;
270	}
271
272	private static Dictionary<double, int> PrepareClassCountDictionary(double[] classValues) {
273	Dictionary<double, int> classCount = new Dictionary<double, int>();
274	for (int i = 0; i < classValues.Length; i++) {
275	classCount[classValues[i]] = 0;
276	}
277	return classCount;
278	}
279	}
280	}

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