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510 lines
25 KiB
510 lines
25 KiB
package net.yacy.data;
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import java.io.IOException;
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import java.util.Collection;
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import java.util.Collections;
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import java.util.Comparator;
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import java.util.ConcurrentModificationException;
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import java.util.Iterator;
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import java.util.LinkedHashSet;
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import java.util.List;
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import java.util.Map;
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import java.util.Set;
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import java.util.SortedSet;
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import java.util.TreeSet;
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import org.apache.solr.client.solrj.SolrQuery;
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import org.apache.solr.client.solrj.response.QueryResponse;
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import org.apache.solr.common.SolrException;
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import net.yacy.cora.sorting.ClusteredScoreMap;
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import net.yacy.cora.sorting.OrderedScoreMap;
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import net.yacy.cora.sorting.ReversibleScoreMap;
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import net.yacy.cora.util.CommonPattern;
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import net.yacy.cora.util.ConcurrentLog;
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import net.yacy.cora.util.StringBuilderComparator;
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import net.yacy.document.LibraryProvider;
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import net.yacy.search.index.Segment;
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import net.yacy.search.schema.CollectionSchema;
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/**
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* People make mistakes when they type words.
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* The most common mistakes are the four categories listed below:
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* <ol>
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* <li>Changing one letter: bat / cat;</li>
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* <li>Adding one letter: bat / boat;</li>
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* <li>Deleting one letter: frog / fog; or</li>
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* <li>Reversing two consecutive letters: two / tow.</li>
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* </ol>
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* DidYouMean provides producer threads, that feed a blocking queue with word variations according to
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* the above mentioned four categories. Consumer threads check then the generated word variations against a term index.
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* Only words contained in the term index are return by the getSuggestion method.<p/>
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* @author apfelmaennchen
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* @author orbiter (extensions for multi-language support + multi-word suggestions)
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*/
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public class DidYouMean {
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private static final int MinimumInputWordLength = 2;
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private static final int MinimumOutputWordLength = 4;
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private static final char[] ALPHABET_LATIN = {
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'a','b','c','d','e','f','g','h','i','j','k','l','m','n','o','p',
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'q','r','s','t','u','v','w','x','y','z',
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'\u00df',
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'\u00e0','\u00e1','\u00e2','\u00e3','\u00e4','\u00e5','\u00e6','\u00e7',
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'\u00e8','\u00e9','\u00ea','\u00eb','\u00ec','\u00ed','\u00ee','\u00ef',
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'\u00f0','\u00f1','\u00f2','\u00f3','\u00f4','\u00f5','\u00f6',
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'\u00f8','\u00f9','\u00fa','\u00fb','\u00fc','\u00fd','\u00fe','\u00ff'};
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private static final char[] ALPHABET_KANJI = new char[512]; // \u3400-\u34ff + \u4e00-\u4eff
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private static final char[] ALPHABET_HIRAGANA = new char[96]; // \u3040-\u309F
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private static final char[] ALPHABET_KATAKANA = new char[96]; // \u30A0-\u30FF
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private static final char[] ALPHABET_CJK_UNIFIED_IDEOGRAPHS_Part1 = new char[5376]; // \u4E00-\u62FF
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private static final char[] ALPHABET_CJK_UNIFIED_IDEOGRAPHS_Part2 = new char[5376]; // \u6300-\u77FF
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private static final char[] ALPHABET_CJK_UNIFIED_IDEOGRAPHS_Part3 = new char[5376]; // \u7800-\u8CFF
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private static final char[] ALPHABET_CJK_UNIFIED_IDEOGRAPHS_Part4 = new char[4864]; // \u8D00-\u9FFF
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static {
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// this is very experimental: a very small subset of Kanji
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for (char a = '\u3400'; a <= '\u34ff'; a++) ALPHABET_KANJI[0xff & (a - '\u3400')] = a;
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for (char a = '\u4e00'; a <= '\u4eff'; a++) ALPHABET_KANJI[0xff & (a - '\u4e00') + 256] = a;
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for (char a = '\u3040'; a <= '\u309F'; a++) ALPHABET_HIRAGANA[0xff & (a - '\u3040')] = a;
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for (char a = '\u30A0'; a <= '\u30FF'; a++) ALPHABET_KATAKANA[0xff & (a - '\u30A0')] = a;
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for (char a = '\u4E00'; a <= '\u62FF'; a++) ALPHABET_CJK_UNIFIED_IDEOGRAPHS_Part1[0xff & (a - '\u4E00')] = a;
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for (char a = '\u6300'; a <= '\u77FF'; a++) ALPHABET_CJK_UNIFIED_IDEOGRAPHS_Part2[0xff & (a - '\u6300')] = a;
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for (char a = '\u7800'; a <= '\u8CFF'; a++) ALPHABET_CJK_UNIFIED_IDEOGRAPHS_Part3[0xff & (a - '\u7800')] = a;
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for (char a = '\u8D00'; a <= '\u9FFF'; a++) ALPHABET_CJK_UNIFIED_IDEOGRAPHS_Part4[0xff & (a - '\u8D00')] = a;
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}
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private static final char[][] ALPHABETS = {
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ALPHABET_LATIN, ALPHABET_KANJI, ALPHABET_HIRAGANA, ALPHABET_KATAKANA,
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ALPHABET_CJK_UNIFIED_IDEOGRAPHS_Part1, ALPHABET_CJK_UNIFIED_IDEOGRAPHS_Part2, ALPHABET_CJK_UNIFIED_IDEOGRAPHS_Part3, ALPHABET_CJK_UNIFIED_IDEOGRAPHS_Part4};
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public static final int AVAILABLE_CPU = Runtime.getRuntime().availableProcessors();
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private static final wordLengthComparator WORD_LENGTH_COMPARATOR = new wordLengthComparator();
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private final Segment segment;
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private final StringBuilder word;
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private final boolean endsWithSpace;
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private final int wordLen;
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private long timeLimit;
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private final SortedSet<StringBuilder> resultSet;
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private char[] alphabet;
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private boolean more;
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/**
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* @param index a termIndex - most likely retrieved from a switchboard object.
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* @param sort true/false - sorts the resulting TreeSet by index.count(); <b>Warning:</b> this causes heavy i/o.
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*/
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public DidYouMean(final Segment segment, final String word0) {
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this.endsWithSpace = word0.length() > 0 && word0.charAt(word0.length() - 1) == ' ';
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this.word = new StringBuilder(word0.trim());
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this.resultSet = Collections.synchronizedSortedSet(new TreeSet<StringBuilder>(new headMatchingComparator(this.word, WORD_LENGTH_COMPARATOR)));
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this.wordLen = this.word.length();
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this.segment = segment;
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this.more = segment.connectedRWI() && segment.RWICount() > 0; // with RWIs connected the guessing is super-fast
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// identify language
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if (this.word.length() > 0) {
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char testchar = this.word.charAt(0);
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if (testchar >= 'A' && testchar <= 'Z') testchar = (char) (testchar + 32);
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boolean alphafound = false;
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alphatest: for (final char[] alpha: ALPHABETS) {
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if (isAlphabet(alpha, testchar)) {
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this.alphabet = new char[alpha.length];
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System.arraycopy(alpha, 0, this.alphabet, 0, alpha.length);
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alphafound = true;
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break alphatest;
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}
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}
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if (!alphafound && testchar < 'A') {
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this.alphabet = new char[ALPHABET_LATIN.length];
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System.arraycopy(ALPHABET_LATIN, 0, this.alphabet, 0, ALPHABET_LATIN.length);
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alphafound = true;
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}
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if (!alphafound) {
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// generate generic alphabet using simply a character block of 256 characters
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final int firstchar = (0xff & (testchar / 256)) * 256;
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final int lastchar = firstchar + 255;
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this.alphabet = new char[256];
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// test this with /suggest.json?q=%EF%BD%84
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for (int a = firstchar; a <= lastchar; a++) {
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this.alphabet[0xff & (a - firstchar)] = (char) a;
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}
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}
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}
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}
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private static final boolean isAlphabet(final char[] alpha, final char testchar) {
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for (final char a: alpha) {
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if (a == testchar) {
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return true;
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}
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}
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return false;
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}
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public void reset() {
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this.resultSet.clear();
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}
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/**
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* get suggestions for a given word. The result is first ordered using a term size ordering,
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* and a subset of the result is sorted again with a IO-intensive order based on the index size
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* @param word0
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* @param timeout
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* @param preSortSelection the number of words that participate in the IO-intensive sort
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* @return
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*/
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public Collection<StringBuilder> getSuggestions(final long timeout, final int preSortSelection) {
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if (this.word.length() < MinimumInputWordLength) {
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return this.resultSet; // return nothing if input is too short
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}
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final long startTime = System.currentTimeMillis();
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final long timelimit = startTime + timeout;
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int lastIndexOfSpace = this.word.lastIndexOf(" ");
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final Collection<StringBuilder> preSorted;
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if (lastIndexOfSpace > 0) {
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// several words
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preSorted = getSuggestions(this.word.substring(0, lastIndexOfSpace), this.word.substring(lastIndexOfSpace + 1), timeout, preSortSelection, this.segment);
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} else {
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if (this.endsWithSpace) {
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preSorted = getSuggestions(this.word.toString(), "", timeout, preSortSelection, this.segment);
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} else {
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preSorted = getSuggestions(timeout);
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}
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}
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final ReversibleScoreMap<StringBuilder> scored = new ClusteredScoreMap<StringBuilder>(StringBuilderComparator.CASE_INSENSITIVE_ORDER);
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LinkedHashSet<StringBuilder> countSorted = new LinkedHashSet<StringBuilder>();
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if (this.more) {
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final int wc = this.segment.getWordCountGuess(this.word.toString()); // all counts must be greater than this
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try {
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for (final StringBuilder s: preSorted) {
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if (System.currentTimeMillis() > timelimit) break;
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if (!(scored.sizeSmaller(2 * preSortSelection))) break;
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String s0 = s.toString();
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int wcg = s0.indexOf(' ') > 0 ? s0.length() * 100 : this.segment.getWordCountGuess(s0);
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if (wcg > wc) scored.inc(s, wcg);
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}
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} catch (final ConcurrentModificationException e) {
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}
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Iterator<StringBuilder> i = scored.keys(false);
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while (i.hasNext()) countSorted.add(i.next());
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} else {
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try {
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for (final StringBuilder s: preSorted) {
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if (StringBuilderComparator.CASE_INSENSITIVE_ORDER.startsWith(s, this.word) ||
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StringBuilderComparator.CASE_INSENSITIVE_ORDER.endsWith(this.word, s)) countSorted.add(this.word);
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}
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for (final StringBuilder s: preSorted) {
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if (!StringBuilderComparator.CASE_INSENSITIVE_ORDER.equals(s, this.word)) countSorted.add(s);
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}
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} catch (final ConcurrentModificationException e) {
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}
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}
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// finished
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ConcurrentLog.info("DidYouMean", "found " + preSorted.size() + " unsorted terms, returned " + countSorted.size() + " sorted suggestions; execution time: "
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+ (System.currentTimeMillis() - startTime) + "ms");
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return countSorted;
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}
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/**
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* return a string that is a suggestion list for the list of given words
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* @param head - the sequence of words before the last space in the sequence, fixed (not to be corrected); possibly empty
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* @param tail - the word after the last space, possibly empty or misspelled
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* @param timeout for operation
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* @param preSortSelection - number of suggestions to be computed
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* @return
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*/
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private static Collection<StringBuilder> getSuggestions(final String head, final String tail, final long timeout, final int preSortSelection, final Segment segment) {
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final SortedSet<StringBuilder> result = new TreeSet<StringBuilder>(StringBuilderComparator.CASE_INSENSITIVE_ORDER);
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int count = 30;
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final SolrQuery solrQuery = new SolrQuery();
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solrQuery.setParam("defType", "edismax");
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solrQuery.setFacet(false);
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String q = "", fq = "";
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if (head.length() == 0 && tail.length() > 0) {
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// head == "", tail != "" -> only one word was entered, no space at end
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q = CollectionSchema.title.getSolrFieldName() + ":\"" + tail + "\"^1000.0 " + CollectionSchema.text_t.getSolrFieldName() + ":" + tail + "~";
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fq = null;
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}
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if (head.length() > 0 && tail.length() == 0) {
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// head != "", tail == "" -> only one word was entered and ends on space
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q = CollectionSchema.title.getSolrFieldName() + ":\"" + head + " \"^1000.0 " + CollectionSchema.text_t.getSolrFieldName() + ":\"" + head + " \"";
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fq = CollectionSchema.text_t.getSolrFieldName() + ":\"" + head + " \"";
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}
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if (head.length() > 0 && tail.length() > 0) {
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// head != "", tail != "" -> several words were entered, last one is in tail, everything before in head.
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q = CollectionSchema.text_t.getSolrFieldName() + ":(" + head + " " + tail + ")~"; // for a fuzzy search we cannot apply fuzzyness on the tail only
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fq = CollectionSchema.text_t.getSolrFieldName() + ":\"" + head + "\"";
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}
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solrQuery.setQuery(q);
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if (head.length() > 0 && fq != null) solrQuery.setFilterQueries(fq);
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solrQuery.setStart(0);
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solrQuery.setRows(count);
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solrQuery.setHighlight(true);
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//solrQuery.setHighlightFragsize(head.length() + tail.length() + 180);
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solrQuery.setHighlightSimplePre("<b>");
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solrQuery.setHighlightSimplePost("</b>");
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solrQuery.setHighlightSnippets(5);
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//solrQuery.addHighlightField(CollectionSchema.title.getSolrFieldName());
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solrQuery.addHighlightField(CollectionSchema.text_t.getSolrFieldName());
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solrQuery.setFields(); // no fields wanted! only snippets
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OrderedScoreMap<String> snippets = new OrderedScoreMap<String>(null);
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try {
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QueryResponse response = segment.fulltext().getDefaultConnector().getResponseByParams(solrQuery);
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/*
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SolrQuery query = new SolrQuery();
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query.setRequestHandler("/suggest");
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//query.setQueryType(suggestHandler);
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query.setQuery((head + " " + tail).trim());
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Map<String,String> params = new HashMap<String,String>();
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params.put(CommonParams.ROWS,Integer.toString(count));
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params.put(SpellingParams.SPELLCHECK_PREFIX + "field",dictionary);
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params.put(SpellingParams.SPELLCHECK_PREFIX + "dictionary",dictionary);
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params.put(SpellingParams.SPELLCHECK_ONLY_MORE_POPULAR,Boolean.toString(onlyMorePopular));
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params.put(SpellingParams.SPELLCHECK_MAX_COLLATION_TRIES,Integer.toString(1));
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params.put(SpellingParams.SPELLCHECK_COLLATE_EXTENDED_RESULTS,Boolean.toString(collate));
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params.put(SpellingParams.SPELLCHECK_COLLATE,Boolean.toString(collate));
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query.add(new MapSolrParams(params));
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response = segment.fulltext().getDefaultConnector().getResponseByParams(query);
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SpellCheckResponse spellCheckResponse = response.getSpellCheckResponse();
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if (spellCheckResponse != null) {
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Map<String,Suggestion> suggestionMapInternal = spellCheckResponse.getSuggestionMap();
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if (suggestionMapInternal != null) {
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Map<String, Suggestion> suggestionMap = spellCheckResponse.getSuggestionMap();
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}
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if (spellCheckResponse.getCollatedResult() != null) {
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String collatedResult = spellCheckResponse.getCollatedResult().trim();
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}
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List<Suggestion> suggestions=spellCheckResponse.getSuggestions();
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if (suggestions.size() != 0) {
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StringBuffer sb=new StringBuffer();
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for (Suggestion suggestion : suggestions) {
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sb.append(suggestion.getSuggestions().get(0)).append(" ");
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}
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String spellCheckProposal = sb.toString().trim();
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}
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}
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*/
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Map<String, Map<String, List<String>>> rawsnippets = response.getHighlighting(); // a map from the urlhash to a map with key=field and value = list of snippets
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if (rawsnippets != null) {
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for (Map<String, List<String>> re: rawsnippets.values()) {
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for (List<String> sl: re.values()) {
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for (String s: sl) {
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// the suggestion for the tail is in the snippet
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s = s.replaceAll("</b> <b>", " ");
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int snippetOpen = s.indexOf("<b>");
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int snippetClose = s.indexOf("</b>");
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if (snippetOpen >= 0 && snippetClose > snippetOpen) {
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String snippet = s.substring(snippetOpen + 3, snippetClose);
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String afterSnippet = s.substring(snippetClose + 4).trim();
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s = snippet + (afterSnippet.length() > 0 ? " " + afterSnippet : "");
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for (int i = 0; i < s.length(); i++) {char c = s.charAt(i); if (c < 'A') s = s.replace(c, ' ');} // remove funny symbols
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s = s.replaceAll("<b>", " ").replaceAll("</b>", " ").replaceAll(" ", " ").trim(); // wipe superfluous whitespace
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String[] sx = CommonPattern.SPACE.split(s);
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StringBuilder sb = new StringBuilder(s.length());
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for (String x: sx) if (x.length() > 1 && sb.length() < 28) sb.append(x).append(' '); else break;
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s = sb.toString().trim();
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if (s.length() > 0) snippets.inc(s, count--);
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}
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}
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}
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}
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}
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} catch (SolrException e) {
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e.printStackTrace();
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} catch (IOException e) {
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e.printStackTrace();
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}
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// delete all snippets which occur double-times, i.e. one that is a substring of another: remove longer snippet
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Iterator<String> si = snippets.keys(false);
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while (si.hasNext()) {
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String testsnippet = si.next().toLowerCase();
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if (testsnippet.length() > head.length() + tail.length() + 1) {
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Iterator<String> sin = snippets.keys(false);
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while (sin.hasNext()) {
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String snippetx = sin.next();
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if (snippetx.length() != testsnippet.length() && snippetx.toLowerCase().startsWith(testsnippet)) {
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snippets.delete(snippetx);
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}
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}
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}
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}
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si = snippets.keys(false);
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while (si.hasNext() && result.size() < preSortSelection) {
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result.add(new StringBuilder(si.next()));
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}
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return result;
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}
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/**
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* This method triggers the producer and consumer threads of the DidYouMean object.
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* @param word a String with a single word
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* @param timeout execution time in ms.
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* @return a Set<String> with word variations contained in term index.
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*/
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private Collection<StringBuilder> getSuggestions(final long timeout) {
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final long startTime = System.currentTimeMillis();
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this.timeLimit = startTime + timeout;
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Thread[] producers = null;
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if (this.more) {
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// create and start producers
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// the CPU load to create the guessed words is very low, but the testing
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// against the library may be CPU intensive. Since it is possible to test
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// words in the library concurrently, it is a good idea to start separate threads
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producers = new Thread[4];
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producers[0] = new ChangingOneLetter();
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producers[1] = new AddingOneLetter();
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producers[2] = new DeletingOneLetter();
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producers[3] = new ReversingTwoConsecutiveLetters();
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for (final Thread t: producers) {
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t.start();
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}
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}
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test(this.word);
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this.resultSet.addAll(getSuggestions("", this.word.toString(), timeout, 10, this.segment));
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if (this.more) {
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// finish the producer
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for (final Thread t: producers) {
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long wait = this.timeLimit - System.currentTimeMillis();
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if (wait > 0) try {
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t.join(wait);
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} catch (final InterruptedException e) {}
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}
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}
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// we don't want the given word in the result
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this.resultSet.remove(this.word);
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return this.resultSet;
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}
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private void test(final StringBuilder s) {
|
|
final Set<StringBuilder> libr = LibraryProvider.dymLib.recommend(s);
|
|
libr.addAll(LibraryProvider.geoLoc.recommend(s));
|
|
for (final StringBuilder t: libr) {
|
|
if (t.length() >= MinimumOutputWordLength) this.resultSet.add(t);
|
|
}
|
|
}
|
|
|
|
/**
|
|
* DidYouMean's producer thread that changes one letter (e.g. bat/cat) for a given term
|
|
* based on the given alphabet and puts it on the blocking queue, to be 'consumed' by a consumer thread.<p/>
|
|
* <b>Note:</b> the loop runs (alphabet.length * len) tests.
|
|
*/
|
|
public class ChangingOneLetter extends Thread {
|
|
@Override
|
|
public void run() {
|
|
char m;
|
|
for (int i = 0; i < DidYouMean.this.wordLen; i++) {
|
|
m = DidYouMean.this.word.charAt(i);
|
|
for (final char c: DidYouMean.this.alphabet) {
|
|
if (m != c) {
|
|
final StringBuilder ts = new StringBuilder(DidYouMean.this.word.length() + 1).append(DidYouMean.this.word.substring(0, i)).append(c).append(DidYouMean.this.word.substring(i + 1));
|
|
test(ts);
|
|
}
|
|
if (System.currentTimeMillis() > DidYouMean.this.timeLimit) return;
|
|
}
|
|
}
|
|
}
|
|
}
|
|
|
|
/**
|
|
* DidYouMean's producer thread that deletes extra letters (e.g. frog/fog) for a given term
|
|
* and puts it on the blocking queue, to be 'consumed' by a consumer thread.<p/>
|
|
* <b>Note:</b> the loop runs (len) tests.
|
|
*/
|
|
private class DeletingOneLetter extends Thread {
|
|
@Override
|
|
public void run() {
|
|
for (int i = 0; i < DidYouMean.this.wordLen; i++) {
|
|
final StringBuilder ts = new StringBuilder(DidYouMean.this.word.length() + 1).append(DidYouMean.this.word.substring(0, i)).append(DidYouMean.this.word.substring(i + 1));
|
|
test(ts);
|
|
if (System.currentTimeMillis() > DidYouMean.this.timeLimit) return;
|
|
}
|
|
}
|
|
}
|
|
|
|
/**
|
|
* DidYouMean's producer thread that adds missing letters (e.g. bat/boat) for a given term
|
|
* based on the given alphabet and puts it on the blocking queue, to be 'consumed' by a consumer thread.<p/>
|
|
* <b>Note:</b> the loop runs (alphabet.length * len) tests.
|
|
*/
|
|
private class AddingOneLetter extends Thread {
|
|
@Override
|
|
public void run() {
|
|
for (int i = 0; i <= DidYouMean.this.wordLen; i++) {
|
|
for (final char c: DidYouMean.this.alphabet) {
|
|
final StringBuilder ts = new StringBuilder(DidYouMean.this.word.length() + 1).append(DidYouMean.this.word.substring(0, i)).append(c).append(DidYouMean.this.word.substring(i));
|
|
test(ts);
|
|
if (System.currentTimeMillis() > DidYouMean.this.timeLimit) return;
|
|
}
|
|
}
|
|
}
|
|
}
|
|
|
|
/**
|
|
* DidYouMean's producer thread that reverses any two consecutive letters (e.g. two/tow) for a given term
|
|
* and puts it on the blocking queue, to be 'consumed' by a consumer thread.<p/>
|
|
* <b>Note:</b> the loop runs (len-1) tests.
|
|
*/
|
|
private class ReversingTwoConsecutiveLetters extends Thread {
|
|
@Override
|
|
public void run() {
|
|
for (int i = 0; i < DidYouMean.this.wordLen - 1; i++) {
|
|
final StringBuilder ts = new StringBuilder(DidYouMean.this.word.length() + 1).append(DidYouMean.this.word.substring(0, i)).append(DidYouMean.this.word.charAt(i + 1)).append(DidYouMean.this.word.charAt(i)).append(DidYouMean.this.word.substring(i + 2));
|
|
test(ts);
|
|
if (System.currentTimeMillis() > DidYouMean.this.timeLimit) return;
|
|
}
|
|
}
|
|
}
|
|
|
|
/**
|
|
* wordLengthComparator is used by DidYouMean to order terms by the term length
|
|
* This is the default order if the indexSizeComparator is not used
|
|
*/
|
|
private static class wordLengthComparator implements Comparator<StringBuilder> {
|
|
@Override
|
|
public int compare(final StringBuilder o1, final StringBuilder o2) {
|
|
final int i1 = o1.length();
|
|
final int i2 = o2.length();
|
|
if (i1 == i2) {
|
|
return StringBuilderComparator.CASE_INSENSITIVE_ORDER.compare(o1, o2);
|
|
}
|
|
return (i1 < i2) ? 1 : -1; // '<' is correct, because the longest word shall be first
|
|
}
|
|
}
|
|
|
|
/**
|
|
* headMatchingComparator is used to sort results in such a way that words that match with the given words are sorted first
|
|
*/
|
|
private static class headMatchingComparator implements Comparator<StringBuilder> {
|
|
private final StringBuilder head;
|
|
private final Comparator<StringBuilder> secondaryComparator;
|
|
public headMatchingComparator(final StringBuilder head, final Comparator<StringBuilder> secondaryComparator) {
|
|
this.head = head;
|
|
this.secondaryComparator = secondaryComparator;
|
|
}
|
|
|
|
@Override
|
|
public int compare(final StringBuilder o1, final StringBuilder o2) {
|
|
final boolean o1m = StringBuilderComparator.CASE_INSENSITIVE_ORDER.startsWith(o1, this.head);
|
|
final boolean o2m = StringBuilderComparator.CASE_INSENSITIVE_ORDER.startsWith(o2, this.head);
|
|
if ((o1m && o2m) || (!o1m && !o2m)) {
|
|
return this.secondaryComparator.compare(o1, o2);
|
|
}
|
|
return o1m ? -1 : 1;
|
|
}
|
|
}
|
|
|
|
}
|
|
|
|
|
|
|