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source: src/main/java/weka/associations/gsp/Sequence.java @ 21

Last change on this file since 21 was 4, checked in by gnappo, 14 years ago
Import di weka.
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1	/*
2	* This program is free software; you can redistribute it and/or modify
3	* it under the terms of the GNU General Public License as published by
4	* the Free Software Foundation; either version 2 of the License, or
5	* (at your option) any later version.
6	*
7	* This program is distributed in the hope that it will be useful,
8	* but WITHOUT ANY WARRANTY; without even the implied warranty of
9	* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
10	* GNU General Public License for more details.
11	*
12	* You should have received a copy of the GNU General Public License
13	* along with this program; if not, write to the Free Software
14	* Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
15	*/
16
17	/*
18	* Sequence.java
19	* Copyright (C) 2007 Sebastian Beer
20	*
21	*/
22
23	package weka.associations.gsp;
24
25	import weka.core.FastVector;
26	import weka.core.Instances;
27	import weka.core.RevisionHandler;
28	import weka.core.RevisionUtils;
29
30	import java.io.Serializable;
31	import java.util.Enumeration;
32
33	/**
34	* Class representing a sequence of elements/itemsets.
35	*
36	* @author Sebastian Beer
37	* @version $Revision: 1.2 $
38	*/
39	public class Sequence
40	implements Cloneable, Serializable, RevisionHandler {
41
42	/** for serialization */
43	private static final long serialVersionUID = -5001018056339156390L;
44
45	/** the support count of the Sequence */
46	protected int m_SupportCount;
47
48	/** ordered list of the comprised elements/itemsets */
49	protected FastVector m_Elements;
50
51	/**
52	* Constructor.
53	*/
54	public Sequence() {
55	m_SupportCount = 0;
56	m_Elements = new FastVector();
57	}
58
59	/**
60	* Constructor accepting a set of elements as parameter.
61	*
62	* @param elements the Elements of the Sequence
63	*/
64	public Sequence(FastVector elements) {
65	m_SupportCount = 0;
66	m_Elements = elements;
67	}
68
69	/**
70	* Constructor accepting an int value as parameter to set the support count.
71	*
72	* @param supportCount the support count to set
73	*/
74	public Sequence(int supportCount) {
75	m_SupportCount = supportCount;
76	m_Elements = new FastVector();
77	}
78
79	/**
80	* Generates all possible candidate k-Sequences and prunes the ones that
81	* contain an infrequent (k-1)-Sequence.
82	*
83	* @param kMinusOneSequences the set of (k-1)-Sequences, used for verification
84	* @return the generated set of k-candidates
85	* @throws CloneNotSupportedException
86	*/
87	public static FastVector aprioriGen(FastVector kMinusOneSequences) throws CloneNotSupportedException {
88	FastVector allCandidates = generateKCandidates(kMinusOneSequences);
89	FastVector prunedCandidates = pruneCadidates(allCandidates, kMinusOneSequences);
90
91	return prunedCandidates;
92	}
93
94	/**
95	* Deletes Sequences of a given set which don't meet the minimum support
96	* count threshold.
97	*
98	* @param sequences the set Sequences to be checked
99	* @param minSupportCount the minimum support count
100	* @return the set of Sequences after deleting
101	*/
102	public static FastVector deleteInfrequentSequences(FastVector sequences, long minSupportCount) {
103	FastVector deletedSequences = new FastVector();
104	Enumeration seqEnum = sequences.elements();
105
106	while (seqEnum.hasMoreElements()) {
107	Sequence currentSeq = (Sequence) seqEnum.nextElement();
108	long curSupportCount = currentSeq.getSupportCount();
109
110	if (curSupportCount >= minSupportCount) {
111	deletedSequences.addElement(currentSeq);
112	}
113	}
114	return deletedSequences;
115	}
116
117	/**
118	* Generates candidate k-Sequences on the basis of a given (k-1)-Sequence set.
119	*
120	* @param kMinusOneSequences the set of (k-1)-Sequences
121	* @return the set of candidate k-Sequences
122	* @throws CloneNotSupportedException
123	*/
124	protected static FastVector generateKCandidates(FastVector kMinusOneSequences) throws CloneNotSupportedException {
125	FastVector candidates = new FastVector();
126	FastVector mergeResult = new FastVector();
127
128	for (int i = 0; i < kMinusOneSequences.size(); i++) {
129	for (int j = 0; j < kMinusOneSequences.size(); j++) {
130	Sequence originalSeq1 = (Sequence) kMinusOneSequences.elementAt(i);
131	Sequence seq1 = originalSeq1.clone();
132	Sequence originalSeq2 = (Sequence) kMinusOneSequences.elementAt(j);
133	Sequence seq2 = originalSeq2.clone();
134	Sequence subseq1 = seq1.deleteEvent("first");
135	Sequence subseq2 = seq2.deleteEvent("last");
136
137	if (subseq1.equals(subseq2)) {
138	//seq1 and seq2 are 1-sequences
139	if ((subseq1.getElements().size() == 0) && (subseq2.getElements().size() == 0)) {
140	if (i >= j) {
141	mergeResult = merge(seq1, seq2, true, true);
142	} else {
143	mergeResult = merge(seq1, seq2, true, false);
144	}
145	//seq1 and seq2 are k-sequences
146	} else {
147	mergeResult = merge(seq1, seq2, false, false);
148	}
149	candidates.appendElements(mergeResult);
150	}
151	}
152	}
153	return candidates;
154	}
155
156	/**
157	* Merges two Sequences in the course of candidate generation. Differentiates
158	* between merging 1-Sequences and k-Sequences, k > 1.
159	*
160	* @param seq1 Sequence at first position
161	* @param seq2 Sequence at second position
162	* @param oneElements true, if 1-Elements should be merged, else false
163	* @param mergeElements true, if two 1-Elements were not already merged
164	* (regardless of their position), else false
165	* @return set of resulting Sequences
166	*/
167	protected static FastVector merge(Sequence seq1, Sequence seq2, boolean oneElements, boolean mergeElements) {
168	FastVector mergeResult = new FastVector();
169
170	//merge 1-sequences
171	if (oneElements) {
172	Element element1 = (Element) seq1.getElements().firstElement();
173	Element element2 = (Element) seq2.getElements().firstElement();
174	Element element3 = null;
175	if (mergeElements) {
176	for (int i = 0; i < element1.getEvents().length; i++) {
177	if (element1.getEvents()[i] > -1) {
178	if (element2.getEvents()[i] > -1) {
179	break;
180	} else {
181	element3 = Element.merge(element1, element2);
182	}
183	}
184	}
185	}
186	FastVector newElements1 = new FastVector();
187	//generate <{x}{y}>
188	newElements1.addElement(element1);
189	newElements1.addElement(element2);
190	mergeResult.addElement(new Sequence(newElements1));
191	//generate <{x,y}>
192	if (element3 != null) {
193	FastVector newElements2 = new FastVector();
194	newElements2.addElement(element3);
195	mergeResult.addElement(new Sequence(newElements2));
196	}
197
198	return mergeResult;
199	//merge k-sequences, k > 1
200	} else {
201	Element lastElementSeq1 = (Element) seq1.getElements().lastElement();
202	Element lastElementSeq2 = (Element) seq2.getElements().lastElement();
203	Sequence resultSeq = new Sequence();
204	FastVector resultSeqElements = resultSeq.getElements();
205
206	//if last two events/items belong to the same element/itemset
207	if (lastElementSeq2.containsOverOneEvent()) {
208	for (int i = 0; i < (seq1.getElements().size()-1); i++) {
209	resultSeqElements.addElement(seq1.getElements().elementAt(i));
210	}
211	resultSeqElements.addElement(Element.merge(lastElementSeq1, lastElementSeq2));
212	mergeResult.addElement(resultSeq);
213
214	return mergeResult;
215	//if last two events/items belong to different elements/itemsets
216	} else {
217	for (int i = 0; i < (seq1.getElements().size()); i++) {
218	resultSeqElements.addElement(seq1.getElements().elementAt(i));
219	}
220	resultSeqElements.addElement(lastElementSeq2);
221	mergeResult.addElement(resultSeq);
222
223	return mergeResult;
224	}
225	}
226	}
227
228	/**
229	* Converts a set of 1-Elements into a set of 1-Sequences.
230	*
231	* @param elements the set of 1-Elements
232	* @return the set of 1-Sequences
233	*/
234	public static FastVector oneElementsToSequences(FastVector elements) {
235	FastVector sequences = new FastVector();
236	Enumeration elementEnum = elements.elements();
237
238	while (elementEnum.hasMoreElements()) {
239	Sequence seq = new Sequence();
240	FastVector seqElements = seq.getElements();
241	seqElements.addElement(elementEnum.nextElement());
242	sequences.addElement(seq);
243	}
244	return sequences;
245	}
246
247	/**
248	* Prints a set of Sequences as String output.
249	*
250	* @param setOfSequences the set of sequences
251	*/
252	public static void printSetOfSequences(FastVector setOfSequences) {
253	Enumeration seqEnum = setOfSequences.elements();
254	int i = 1;
255
256	while(seqEnum.hasMoreElements()) {
257	Sequence seq = (Sequence) seqEnum.nextElement();
258	System.out.print("[" + i++ + "]" + " " + seq.toString());
259	}
260	}
261
262	/**
263	* Prunes a k-Sequence of a given candidate set if one of its (k-1)-Sequences
264	* is infrequent.
265	*
266	* @param allCandidates the set of all potential k-Sequences
267	* @param kMinusOneSequences the set of (k-1)-Sequences for verification
268	* @return the set of the pruned candidates
269	*/
270	protected static FastVector pruneCadidates(FastVector allCandidates, FastVector kMinusOneSequences) {
271	FastVector prunedCandidates = new FastVector();
272	boolean isFrequent;
273	//for each candidate
274	for (int i = 0; i < allCandidates.size(); i++) {
275	Sequence candidate = (Sequence) allCandidates.elementAt(i);
276	isFrequent = true;
277	FastVector canElements = candidate.getElements();
278	//generate each possible (k-1)-sequence and verify if it's frequent
279	for (int j = 0; j < canElements.size(); j++) {
280	if(isFrequent) {
281	Element origElement = (Element) canElements.elementAt(j);
282	int[] origEvents = origElement.getEvents();
283
284	for (int k = 0; k < origEvents.length; k++) {
285	if (origEvents[k] > -1) {
286	int helpEvent = origEvents[k];
287	origEvents[k] = -1;
288
289	if (origElement.isEmpty()) {
290	canElements.removeElementAt(j);
291	//check if the (k-1)-sequence is contained in the set of kMinusOneSequences
292	int containedAt = kMinusOneSequences.indexOf(candidate);
293	if (containedAt != -1) {
294	origEvents[k] = helpEvent;
295	canElements.insertElementAt(origElement, j);
296	break;
297	} else {
298	isFrequent = false;
299	break;
300	}
301	} else {
302	//check if the (k-1)-sequence is contained in the set of kMinusOneSequences
303	int containedAt = kMinusOneSequences.indexOf(candidate);
304	if (containedAt != -1) {
305	origEvents[k] = helpEvent;
306	continue;
307	} else {
308	isFrequent = false;
309	break;
310	}
311	}
312	}
313	}
314	} else {
315	break;
316	}
317	}
318	if (isFrequent) {
319	prunedCandidates.addElement(candidate);
320	}
321	}
322	return prunedCandidates;
323	}
324
325	/**
326	* Returns a String representation of a set of Sequences where the numeric
327	* value of each event/item is represented by its respective nominal value.
328	*
329	* @param setOfSequences the set of Sequences
330	* @param dataSet the corresponding data set containing the header
331	* information
332	* @param filterAttributes the attributes to filter out
333	* @return the String representation
334	*/
335	public static String setOfSequencesToString(FastVector setOfSequences, Instances dataSet, FastVector filterAttributes) {
336	StringBuffer resString = new StringBuffer();
337	Enumeration SequencesEnum = setOfSequences.elements();
338	int i = 1;
339	boolean printSeq;
340
341	while(SequencesEnum.hasMoreElements()) {
342	Sequence seq = (Sequence) SequencesEnum.nextElement();
343	Integer filterAttr = (Integer) filterAttributes.elementAt(0);
344	printSeq = true;
345
346	if (filterAttr.intValue() != -1) {
347	for (int j=0; j < filterAttributes.size(); j++) {
348	filterAttr = (Integer) filterAttributes.elementAt(j);
349	FastVector seqElements = seq.getElements();
350
351	if (printSeq) {
352	for (int k=0; k < seqElements.size(); k++) {
353	Element currentElement = (Element) seqElements.elementAt(k);
354	int[] currentEvents = currentElement.getEvents();
355
356	if (currentEvents[filterAttr.intValue()] != -1) {
357	continue;
358	} else {
359	printSeq = false;
360	break;
361	}
362	}
363	}
364	}
365	}
366	if (printSeq) {
367	resString.append("[" + i++ + "]" + " " + seq.toNominalString(dataSet));
368	}
369	}
370	return resString.toString();
371	}
372
373	/**
374	* Updates the support count of a set of Sequence candidates according to a
375	* given set of data sequences.
376	*
377	* @param candidates the set of candidates
378	* @param dataSequences the set of data sequences
379	*/
380	public static void updateSupportCount(FastVector candidates, FastVector dataSequences) {
381	Enumeration canEnumeration = candidates.elements();
382
383	while(canEnumeration.hasMoreElements()){
384	Enumeration dataSeqEnumeration = dataSequences.elements();
385	Sequence candidate = (Sequence) canEnumeration.nextElement();
386
387	while(dataSeqEnumeration.hasMoreElements()) {
388	Instances dataSequence = (Instances) dataSeqEnumeration.nextElement();
389
390	if (candidate.isSubsequenceOf(dataSequence)) {
391	candidate.setSupportCount(candidate.getSupportCount() + 1);
392	}
393	}
394	}
395	}
396
397	/**
398	* Returns a deep clone of a Sequence.
399	*
400	* @return the cloned Sequence
401	*/
402	public Sequence clone() {
403	try {
404	Sequence clone = (Sequence) super.clone();
405
406	clone.setSupportCount(m_SupportCount);
407	FastVector cloneElements = new FastVector(m_Elements.size());
408
409	for (int i = 0; i < m_Elements.size(); i++) {
410	Element helpElement = (Element) m_Elements.elementAt(i);
411	cloneElements.addElement(helpElement.clone());
412	}
413	clone.setElements(cloneElements);
414
415	return clone;
416	} catch (CloneNotSupportedException exc) {
417	exc.printStackTrace();
418	}
419	return null;
420	}
421
422	/**
423	* Deletes either the first or the last event/item of a Sequence. If the
424	* deleted event/item is the only value in the Element, it is removed, as well.
425	*
426	* @param position the position of the event/item (first or last)
427	* @return the Sequence with either the first or the last
428	* event/item deleted
429	*/
430	protected Sequence deleteEvent(String position) {
431	Sequence cloneSeq = clone();
432
433	if (position.equals("first")) {
434	Element element = (Element) cloneSeq.getElements().firstElement();
435	element.deleteEvent("first");
436	if (element.isEmpty()) {
437	cloneSeq.getElements().removeElementAt(0);
438	}
439	return cloneSeq;
440	}
441	if (position.equals("last")) {
442	Element element = (Element) cloneSeq.getElements().lastElement();
443	element.deleteEvent("last");
444	if (element.isEmpty()) {
445	cloneSeq.getElements().removeElementAt(m_Elements.size()-1);
446	}
447	return cloneSeq;
448	}
449	return null;
450	}
451
452	/**
453	* Checks if two Sequences are equal.
454	*
455	* @return true, if the two Sequences are equal, else false
456	*/
457	public boolean equals(Object obj) {
458	Sequence seq2 = (Sequence) obj;
459	FastVector seq2Elements = seq2.getElements();
460
461	for (int i = 0; i < m_Elements.size(); i++) {
462	Element thisElement = (Element) m_Elements.elementAt(i);
463	Element seq2Element = (Element) seq2Elements.elementAt(i);
464	if (!thisElement.equals(seq2Element)) {
465	return false;
466	}
467	}
468	return true;
469	}
470
471	/**
472	* Returns the Elements of the Sequence.
473	*
474	* @return the Elements
475	*/
476	protected FastVector getElements() {
477	return m_Elements;
478	}
479
480	/**
481	* Returns the support count of the Sequence.
482	*
483	* @return the support count
484	*/
485	protected int getSupportCount() {
486	return m_SupportCount;
487	}
488
489	/**
490	* Checks if the Sequence is subsequence of a given data sequence.
491	*
492	* @param dataSequence the data sequence to verify against
493	* @return true, if the Sequnce is subsequence of the data
494	* sequence, else false
495	*/
496	protected boolean isSubsequenceOf(Instances dataSequence) {
497	FastVector elements = getElements();
498	Enumeration elementEnum = elements.elements();
499	Element curElement = (Element) elementEnum.nextElement();
500
501	for (int i = 0; i < dataSequence.numInstances(); i++) {
502	if (curElement.isContainedBy(dataSequence.instance(i))) {
503	if (!elementEnum.hasMoreElements()) {
504	return true;
505	} else {
506	curElement = (Element) elementEnum.nextElement();
507	continue;
508	}
509	}
510	}
511	return false;
512	}
513
514	/**
515	* Sets the Elements of the Sequence.
516	*
517	* @param elements the Elements to set
518	*/
519	protected void setElements(FastVector elements) {
520	m_Elements = elements;
521	}
522
523	/**
524	* Sets the support count of the Sequence.
525	*
526	* @param supportCount the support count to set
527	*/
528	protected void setSupportCount(int supportCount) {
529	m_SupportCount = supportCount;
530	}
531
532	/**
533	* Returns a String representation of a Sequences where the numeric value
534	* of each event/item is represented by its respective nominal value.
535	*
536	* @param dataSet the corresponding data set containing the header
537	* information
538	* @return the String representation
539	*/
540	public String toNominalString(Instances dataSet) {
541	String result = "";
542
543	result += "<";
544
545	for (int i = 0; i < m_Elements.size(); i++) {
546	Element element = (Element) m_Elements.elementAt(i);
547	result += element.toNominalString(dataSet);
548	}
549	result += "> (" + getSupportCount() + ")\n";
550
551	return result;
552	}
553
554	/**
555	* Returns a String representation of a Sequence.
556	*
557	* @return the String representation
558	*/
559	public String toString() {
560	String result = "";
561
562	result += "Sequence Output\n";
563	result += "------------------------------\n";
564	result += "Support Count: " + getSupportCount() + "\n";
565	result += "contained elements/itemsets:\n";
566
567	for (int i = 0; i < m_Elements.size(); i++) {
568	Element element = (Element) m_Elements.elementAt(i);
569	result += element.toString();
570	}
571	result += "\n\n";
572
573	return result;
574	}
575
576	/**
577	* Returns the revision string.
578	*
579	* @return the revision
580	*/
581	public String getRevision() {
582	return RevisionUtils.extract("$Revision: 1.2 $");
583	}
584	}

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