private String[] toSentence(ArrayList<Word> words) {
String[] sent = new String[words.size()];
for (int k = 0; k < words.size(); k++) {
sent[k] = words.get(k).getValue();
}
return sent;
}
public static ArrayList<TaggedWord> StopWordRemoval(ArrayList<TaggedWord> taggedWords) {
ArrayList<TaggedWord> newList = new ArrayList<TaggedWord>();
try {
String path = "data/nltk_stoplist.txt";
File textFile = new File(path);
BufferedReader br = new BufferedReader(new FileReader(textFile));
String stopwordsLine = br.readLine();
br.close();
String[] stopwords = stopwordsLine.split(",");
HashMap<String, String> stopwordsDict = new HashMap<String, String>();
for (int i = 0; i < stopwords.length; i++) {
stopwordsDict.put(stopwords[i], stopwords[i]);
}
for (int i = 0; i < taggedWords.size(); i++) {
String word = taggedWords.get(i).word();
String posTag = taggedWords.get(i).tag();
if (!stopwordsDict.containsKey(word.toLowerCase())) {
String newWord, newPosTag;
newWord = word;
newPosTag = posTag;
newList.add(new TaggedWord(newWord, newPosTag));
}
}
} catch (Exception ex) {
ex.printStackTrace();
}
return newList;
}
private String findSynonym(ArrayList<Word> sentence, int indexToReplace /*<Word wordIn>*/) {
/**
* Takes in one String of a word, hopefully only one word(will truncate after space), and
* searches for a suitable synonym
*
* <p>*
*/
String output = "";
// String word;
// word=wordIn.getString();
String word = sentence.get(indexToReplace).getValue();
Synset[] synsets = database.getSynsets(word);
synonyms.clear();
if (synsets.length > 0) {
for (int i = 0; i < synsets.length; i++) {
String[] wordForms = synsets[i].getWordForms();
for (int j = 0; j < wordForms.length; j++) {
if (wordForms[j].contains(" ")) {
System.out.println(wordForms[j]);
} else if (!wordForms[j].equals(word)) synonyms.add(wordForms[j]);
}
}
// FIND IF PLURAL OR NO HERE
/////////////////////////// ###########################////////////////////
Collections.sort(synonyms, myLengthComparator);
// synonyms is now sorted as longest first
// now we have a list of all the terms that can replace the word.
// We need to check them in the lexical analyzer
// System.out.println("kkkk");
if (synonyms.size() == 0) return word;
while (!LexicalAnalyzer(sentence, indexToReplace, synonyms.get(0))) {
// System.out.println("1");
synonyms.remove(0);
if (synonyms.size() == 0) return word; // did not find synonym
if (synonyms.get(0).length() <= word.length()) {
return word;
// do not replace word, synonyms are shorter
}
}
////////////// ############# PLACEHOLDER CODE
if (synonyms.size() > 0) output = synonyms.get(0);
else output = word;
///////////// ################# PLACEHOLDER CODE
} else { // There are no other known synonyms in our wordnet database.
output = word;
}
return output;
}
private boolean LexicalAnalyzer(ArrayList<Word> words, int index, String newWord) {
String[] sent = toSentence(words);
/// lexical analyzer
List<CoreLabel> rawWords = Sentence.toCoreLabelList(sent);
Tree parse = lp.apply(rawWords);
// PrintStream outa = new PrintStream(new FileOutputStream("output1.txt"));
// System.setOut(outa);
// System.out.println("KKKKKKK");
// parse.pennPrint();
String oldTree = parse.toString();
// String oldTree=baos.toString();
// System.setOut(new PrintStream(new FileOutputStream(FileDescriptor.out)));
// System.out.println(oldTree);
words.get(index).setNewValue(newWord);
sent = toSentence(words);
rawWords = Sentence.toCoreLabelList(sent);
parse = lp.apply(rawWords);
// PrintStream outb = new PrintStream(new FileOutputStream("output2.txt"));
// System.setOut(outb);
// parse.pennPrint();
String newTree = parse.toString();
oldTree = oldTree.replaceAll(words.get(index).getOrigValue() + "[)]", newWord + ")");
// System.setOut(new PrintStream(new FileOutputStream(FileDescriptor.out)));
System.out.println(oldTree + "\n" + newTree);
// System.out.println(oldTree.equals(newTree));
if (oldTree.equals(newTree)) {
if (index == 0) {
String str = words.get(index).getNewValue();
String cap = str.substring(0, 1).toUpperCase() + str.substring(1);
words.get(index).setNewValue(cap);
}
return true;
} else {
words.get(index).setNewValue(null);
return false;
}
/* catch (FileNotFoundException e) {
// TODO Auto-generated catch block
e.printStackTrace();
return false;
} catch (IOException e) {
// TODO Auto-generated catch block
e.printStackTrace();
return false;
}*/
// return true;
}
public static ArrayList<ArrayList<TaggedWord>> getPhrasesNaive(
String sentence, LexicalizedParser lp, AbstractSequenceClassifier<CoreLabel> classifier) {
ArrayList<ArrayList<TaggedWord>> newList = new ArrayList<ArrayList<TaggedWord>>();
ArrayList<TaggedWord> taggedWords = StanfordNER.parse(sentence, lp, classifier);
HashMap<String, String> phraseBoundaries = new HashMap<String, String>();
phraseBoundaries.put(",", ",");
phraseBoundaries.put("\"", "\"");
phraseBoundaries.put("''", "''");
phraseBoundaries.put("``", "``");
phraseBoundaries.put("--", "--");
// List<Tree> leaves = parse.getLeaves();
ArrayList<TaggedWord> temp = new ArrayList<TaggedWord>();
int index = 0;
while (index < taggedWords.size()) {
if ((phraseBoundaries.containsKey(taggedWords.get(index).word()))) {
if (temp.size() > 0) {
// System.out.println(temp);
ArrayList<TaggedWord> tempCopy = new ArrayList<TaggedWord>(temp);
newList.add(Preprocess(tempCopy));
}
temp.clear();
} else {
// System.out.println(taggedWords.get(index).toString());
temp.add(taggedWords.get(index));
}
index += 1;
}
if (temp.size() > 0) {
ArrayList<TaggedWord> tempCopy = new ArrayList<TaggedWord>(temp);
newList.add(Preprocess(tempCopy));
}
// System.out.println(newList);
return newList;
}
public static double LexicalSimilarityScoreMin(
ArrayList<TaggedWord> taggedWords1,
ArrayList<TaggedWord> taggedWords2,
DISCOSimilarity discoRAM,
LexicalizedParser lp) {
// System.out.println(taggedWords1.size() + "," + taggedWords2.size());
// array of edge weights with default weight 0
int length1 = taggedWords1.size();
int length2 = taggedWords2.size();
int arrSize = Math.max(length1, length2);
double[][] array = new double[arrSize][arrSize];
for (int i = 0; i < arrSize; i++) {
for (int j = 0; j < arrSize; j++) {
array[i][j] = 0;
}
}
for (int i = 0; i < length1; i++) {
for (int j = 0; j < length2; j++) {
String word1 = taggedWords1.get(i).word();
String word2 = taggedWords2.get(j).word();
double edgeWeight = 0;
// LSA Similarity
// edgeWeight = LSASimilarity.LSAWordSimilarity(word1, word2);
// DISCO Similarity
// DISCOSimilarity discoObj = new DISCOSimilarity();
try {
if (word1.compareToIgnoreCase(word2) == 0) edgeWeight = 1;
else {
edgeWeight = discoRAM.similarity2(word1, word2);
// edgeWeight = LSASimilarity.LSAWordSimilarity(word1, word2);
}
} catch (Exception ex) {
ex.printStackTrace();
}
array[i][j] = edgeWeight;
}
}
// System.out.println("Hungarian starts " + arrSize);
double finalScore;
String sumType = "max";
int minLength = Math.min(length1, length2);
finalScore = HungarianAlgorithm.hgAlgorithm(array, sumType) / minLength * 5;
// finalScore = HungarianAlgorithm.hgAlgorithm(array, sumType)/arrSize * 5;
return finalScore;
}
public ArrayList<String> getNounsFromSentence(String sentence) {
ArrayList<TaggedWord> tw = parseSentenceTD(sentence);
ArrayList<String> nouns = new ArrayList<String>();
for (TaggedWord t : tw) {
if (t.tag().startsWith("N")) {
nouns.add(t.value());
}
}
return nouns;
}
public ArrayList<String> getPairsFromSentence(String sentence) {
Collection<TypedDependency> tdl = parseSentenceTDL(sentence);
ArrayList<String> pairs = new ArrayList<String>();
for (TypedDependency td : tdl) {
StringBuilder sb = new StringBuilder();
sb.append(td.gov().originalText());
sb.append(" ");
sb.append(td.dep().originalText());
pairs.add(sb.toString());
}
return pairs;
}
public static ArrayList<TaggedWord> PreprocessPhrase(ArrayList<TaggedWord> taggedWords) {
ArrayList<TaggedWord> newList = new ArrayList<TaggedWord>();
taggedWords = Preprocess(taggedWords);
for (int i = 0; i < taggedWords.size(); i++) {
String posTag = taggedWords.get(i).tag();
if (posTag.length() >= 2) {
String reducedTag = posTag.substring(0, 2);
if (reducedTag.equals("CD") || reducedTag.equals("NN") || reducedTag.equals("VB")) {
newList.add(taggedWords.get(i));
}
}
}
return newList;
}
public static ArrayList<ArrayList<TaggedWord>> getPhrases(Tree parse, int phraseSizeLimit) {
ArrayList<ArrayList<TaggedWord>> newList = new ArrayList<ArrayList<TaggedWord>>();
List<Tree> leaves = parse.getLeaves();
if (leaves.size() <= phraseSizeLimit) {
// ArrayList<TaggedWord> phraseElements = PreprocessPhrase(parse.taggedYield());
ArrayList<TaggedWord> phraseElements = Preprocess(parse.taggedYield());
if (phraseElements.size() > 0) newList.add(phraseElements);
} else {
Tree[] childrenNodes = parse.children();
for (int i = 0; i < childrenNodes.length; i++) {
Tree currentParse = childrenNodes[i];
newList.addAll(getPhrases(currentParse, phraseSizeLimit));
}
}
return newList;
}
public static void main(String args[]) {
// String sentence1 = "A large bird standing on a table picks up a plastic glass
// containing liquid and places it in a bowl of something.";
// String sentence2 = "A bird picks up a plastic cup containing a liquid with it's beak
// and puts the cup into a bowl.";
// LexicalizedParser lp = new LexicalizedParser("englishPCFG.ser.gz");
// LeskWSD tm = new LeskWSD(lp);
// WordNetSimilarity ws = new WordNetSimilarity();
//
// System.out.println(LexicalSimilarityScoreWordNet(sentence1, sentence2, tm, lp, ws));
String sentence =
"The broader Standard & Poor's 500 Index <.SPX> shed 2.38 points, or 0.24 percent, at 995.10.";
LexicalizedParser lp = new LexicalizedParser("englishPCFG.ser.gz");
Tree parse = lp.apply(sentence);
ArrayList<TaggedWord> taggedWords = parse.taggedYield();
taggedWords = Preprocess(taggedWords);
for (int i = 0; i < taggedWords.size(); i++) System.out.println(taggedWords.get(i).word());
}
public static double BestWordMatchEdgeWeight(
ArrayList<TaggedWord> taggedWords1,
ArrayList<TaggedWord> taggedWords2,
DISCOSimilarity discoRAM) {
double bestMatchScore = 0;
for (int i = 0; i < taggedWords1.size(); i++) {
String word1 = taggedWords1.get(i).word();
for (int j = 0; j < taggedWords2.size(); j++) {
String word2 = taggedWords2.get(j).word();
double currentScore;
if (word1.equals(word2)) currentScore = 1;
else currentScore = discoRAM.similarity2(word1, word2);
if (currentScore > bestMatchScore) bestMatchScore = currentScore;
}
}
return bestMatchScore;
}
public static ArrayList<TaggedWord> Preprocess(ArrayList<TaggedWord> taggedWords) {
ArrayList<TaggedWord> newList = new ArrayList<TaggedWord>();
String[] punctuationsAndSpecialCharacters = {
",", ".", "?", "!", ":", ";", "\"", "-", "--", "'", "-LRB-", "-RRB-", "''", "``", "&"
}; // , "/", "\\", "<", ">", "#", "&", "*", "(", ")", "{", "}", "[", "]", "~", "|"};
HashMap<String, String> punctuationMarks = new HashMap<String, String>();
for (int i = 0; i < punctuationsAndSpecialCharacters.length; i++) {
punctuationMarks.put(
punctuationsAndSpecialCharacters[i], punctuationsAndSpecialCharacters[i]);
}
for (int i = 0; i < taggedWords.size(); i++) {
String word = taggedWords.get(i).word();
String posTag = taggedWords.get(i).tag();
if (!punctuationMarks.containsKey(word)) {
if (!(posTag.length() > 2 && posTag.substring(0, 3).equals("NNP"))) {
word = Morphology.lemmaStatic(word, posTag, true);
word = word.replace('-', ' ');
}
String newWord, newPosTag;
if (word.equals("n't")) newWord = "not";
else if (word.equals("'s")) newWord = "is";
else if (word.equals("'ll")) newWord = "will";
else if (word.equals("'m") || word.equals("m")) newWord = "am";
else if (word.equals("im")) newWord = "am";
else newWord = word;
newPosTag = posTag;
newList.add(new TaggedWord(newWord, newPosTag));
}
}
newList = StopWordRemoval(newList);
return newList;
}
public static void main(String[] args) {
ParseEssay p = new ParseEssay();
ArrayList<Word> sent = new ArrayList<Word>();
sent.add(new Word("These", "o")); // fake POS o and p
sent.add(new Word("are", "o"));
sent.add(new Word("balls", "p"));
ArrayList<String> pars = new ArrayList<String>();
pars.add("p");
System.out.println(p.overhaulSentence(sent, pars));
}
public static double LexicalSimilarityScoreWordNet(
String sentence1, String sentence2, LeskWSD tm, LexicalizedParser lp, WordNetSimilarity ws) {
ArrayList<TaggedWord> taggedWordsPrev1 = Preprocess(StanfordParse(sentence1, lp));
ArrayList<TaggedWord> taggedWordsPrev2 = Preprocess(StanfordParse(sentence2, lp));
ArrayList<TaggedWord> taggedWords1 = new ArrayList<TaggedWord>();
ArrayList<TaggedWord> taggedWords2 = new ArrayList<TaggedWord>();
WordNetSense[] sensesPrev1 = tm.LeskJWI(sentence1);
WordNetSense[] sensesPrev2 = tm.LeskJWI(sentence2);
// System.out.println("Senses found!");
ArrayList<WordNetSense> senses1 = new ArrayList<WordNetSense>();
ArrayList<WordNetSense> senses2 = new ArrayList<WordNetSense>();
for (int i = 0; i < taggedWordsPrev1.size(); i++) {
String word = taggedWordsPrev1.get(i).word();
String posTag = taggedWordsPrev1.get(i).tag();
if (posTag.length() >= 2 && posTag.substring(0, 2).equals("NN")) {
taggedWords1.add(new TaggedWord(word, "NN"));
senses1.add(sensesPrev1[i]);
} else if (posTag.length() >= 2 && posTag.substring(0, 2).equals("VB")) {
taggedWords1.add(new TaggedWord(word, "VB"));
senses1.add(sensesPrev1[i]);
}
}
for (int i = 0; i < taggedWordsPrev2.size(); i++) {
String word = taggedWordsPrev2.get(i).word();
String posTag = taggedWordsPrev2.get(i).tag();
if (posTag.length() >= 2 && posTag.substring(0, 2).equals("NN")) {
taggedWords2.add(new TaggedWord(word, "NN"));
senses2.add(sensesPrev2[i]);
} else if (posTag.length() >= 2 && posTag.substring(0, 2).equals("VB")) {
taggedWords2.add(new TaggedWord(word, "VB"));
senses2.add(sensesPrev2[i]);
}
}
// System.out.println(taggedWords1.size() + "," + taggedWords2.size());
// array of edge weights with default weight 0
int length1 = taggedWords1.size();
int length2 = taggedWords2.size();
int arrSize = Math.max(length1, length2);
double[][] array = new double[arrSize][arrSize];
for (int i = 0; i < arrSize; i++) {
for (int j = 0; j < arrSize; j++) {
array[i][j] = 0;
}
}
for (int i = 0; i < length1; i++) {
for (int j = 0; j < length2; j++) {
String word1 = taggedWords1.get(i).word();
String posTag1 = taggedWords1.get(i).tag();
String word2 = taggedWords2.get(j).word();
String posTag2 = taggedWords2.get(j).tag();
double edgeWeight = 0;
// LSA Similarity
// edgeWeight = LSASimilarity.LSAWordSimilarity(word1, word2);
// DISCO Similarity
// DISCOSimilarity discoObj = new DISCOSimilarity();
try {
if (word1.compareToIgnoreCase(word2) == 0) edgeWeight = 1;
else {
// edgeWeight = ws.wuPalmerSimilarity(senses1.get(i), senses2.get(j));
edgeWeight = ws.linSimilarity(senses1.get(i), senses2.get(j));
}
} catch (Exception ex) {
ex.printStackTrace();
}
array[i][j] = edgeWeight;
}
}
// System.out.println("Hungarian starts " + arrSize);
double finalScore;
String sumType = "max";
int minLength = Math.min(length1, length2);
// finalScore = HungarianAlgorithm.hgAlgorithm(array, sumType)/minLength * 5;
if (arrSize == 0) finalScore = 0;
else finalScore = HungarianAlgorithm.hgAlgorithm(array, sumType) / arrSize * 5;
return finalScore;
}
public static double LexicalSimilarityScoreMax(
ArrayList<TaggedWord> taggedWords1,
ArrayList<TaggedWord> taggedWords2,
DISCOSimilarity discoRAM,
LexicalizedParser lp) {
// System.out.println(taggedWords1.size() + "," + taggedWords2.size());
// array of edge weights with default weight 0
int length1 = taggedWords1.size();
int length2 = taggedWords2.size();
int arrSize = Math.max(length1, length2);
double[][] array = new double[arrSize][arrSize];
for (int i = 0; i < arrSize; i++) {
for (int j = 0; j < arrSize; j++) {
array[i][j] = 0;
}
}
for (int i = 0; i < length1; i++) {
for (int j = 0; j < length2; j++) {
String word1 = taggedWords1.get(i).word();
String posTag1 = taggedWords1.get(i).tag();
String word2 = taggedWords2.get(j).word();
String posTag2 = taggedWords2.get(j).tag();
ArrayList<TaggedWord> newList1 = new ArrayList<TaggedWord>();
if (posTag1.length() >= 3 && posTag1.substring(0, 3).equals("NNP")) {
newList1.add(taggedWords1.get(i));
} else {
String[] words = word1.split(" ");
for (int k = 0; k < words.length; k++) newList1.add(new TaggedWord(words[k], posTag1));
}
ArrayList<TaggedWord> newList2 = new ArrayList<TaggedWord>();
if (posTag2.length() >= 3 && posTag2.substring(0, 3).equals("NNP")) {
newList2.add(taggedWords2.get(j));
} else {
String[] words = word2.split(" ");
for (int k = 0; k < words.length; k++) newList2.add(new TaggedWord(words[k], posTag2));
}
double edgeWeight = LexicalSimilarityScoreMin(newList1, newList2, discoRAM, lp);
array[i][j] = edgeWeight;
}
}
// System.out.println("Hungarian starts " + arrSize);
double finalScore;
String sumType = "max";
// int minLength = Math.min(length1, length2);
// finalScore = HungarianAlgorithm.hgAlgorithm(array, sumType)/minLength * 5;
finalScore = HungarianAlgorithm.hgAlgorithm(array, sumType) / arrSize * 5;
return finalScore;
}
public HashMap<String,ArrayList<TreeData>> parseAllDocs() throws IOException{
String grammar = "./jsan_resources/englishPCFG.ser.gz";
String[] options = { "-maxLength", "120", "-retainTmpSubcategories" };
// LexicalizedParser lp = new LexicalizedParser(grammar, options);
LexicalizedParser lp = new LexicalizedParser()
TreebankLanguagePack tlp = new PennTreebankLanguagePack();
GrammaticalStructureFactory gsf = tlp.grammaticalStructureFactory();
Iterable<List<? extends HasWord>> sentences;
ArrayList<HashMap<String,ArrayList<String>>> everything = new ArrayList<HashMap<String,ArrayList<String>>>(3);
everything.add(0,otherSampleStrings);
everything.add(1,authorSampleStrings);
everything.add(2,toModifyStrings);
Iterator<HashMap<String,ArrayList<String>>> everythingIter = everything.iterator();
int docTypeNumber = -1; // 0 for otherSampleStrings, 1 for authorSampleStrings, 2 for toModifyStrings
int numLoaded = 0;
while(everythingIter.hasNext()){
docTypeNumber++;
HashMap<String,ArrayList<String>> currentSampleStrings = docPathFinder();
Set<String> currentDocStrings = currentSampleStrings.keySet();
Iterator<String> docStrIter = currentDocStrings.iterator();
String docID;
ArrayList<String> sentenceTokens;
allTreeProcessors[docTypeNumber] = new TreeProcessor();
allTreeProcessors[docTypeNumber].clearLoadedTreeDataMaps();
numLoaded=0;
while(docStrIter.hasNext()){
docID = docStrIter.next();
sentenceTokens = currentSampleStrings.get(docID);
if(sentenceTokens == null){
allTreeProcessors[docTypeNumber].loadTreeDataMap(docID, GRAMMAR_DIR, false);
numLoaded++;
continue;
}
//System.out.println(sentenceTokens.size()+", strIter.hasNext? -> "+strIter.hasNext());
numSentences = sentenceTokens.size();
//initialize(numSentences);
Iterator<String> sentIter = sentenceTokens.iterator();
List<List<? extends HasWord>> tmp = new ArrayList<List<? extends HasWord>>();
String tempSent;
while(sentIter.hasNext()){
tempSent = sentIter.next();
Tokenizer<? extends HasWord> toke = tlp.getTokenizerFactory().getTokenizer(new StringReader(tempSent));
List<? extends HasWord> sentenceTokenized = toke.tokenize();
tmp.add(sentenceTokenized);
}
sentences = tmp;
//int numDone = 0;
TreeProcessor.singleDocMap.clear();
boolean willSaveResults = true;
for (List<? extends HasWord> sentence : sentences) {
Tree parse = lp.apply(sentence);
//parse.pennPrint();
//System.out.println(parse.treeSkeletonCopy().toString());
//System.out.println(parse.taggedYield());
//System.out.println();
//printSubTrees(parse);
//TreeContainer.recurseTree(parse,"breadth");
allTreeProcessors[docTypeNumber].processTree(parse, 0, willSaveResults);
//System.out.println(tc.processedTrees.toString().replaceAll("\\]\\], \\(","\\]\\]\n\\("));
//numDone++;
//System.out.println("sent "+numDone+" of "+numSentences+" done ");
//System.out.println(tc.processedTrees.toString());
//in.nextLine();
//TreeContainer.recurseTree(parse, "depth");
//in.nextLine();
//addTree(parse);
//GrammaticalStructure gs = gsf.newGrammaticalStructure(parse);//TODO: LOOK AT THIS
//Collection tdl = gs.typedDependenciesCCprocessed(true);
//System.out.println(tdl);
//System.out.println();
}
if(willSaveResults == true)
ObjectIO.writeObject(TreeProcessor.singleDocMap,docID, GRAMMAR_DIR);
//System.out.println("After all sents: ");
//System.out.println(tc.processedTrees.toString().replaceAll("\\]\\], \\(","\\]\\]\n\\("));
//String sent3 = "This is one last test!";
//Tree parse3 = lp.apply(sent3);
//parse3.pennPrint();
//System.out.println("After sorting and writing:");
//System.out.println(tc.processedTrees.toString().replaceAll("\\]\\], \\(","\\]\\]\n\\("));
//Scanner in = new Scanner(System.in);
//System.out.println("First one done.");
//in.nextLine();
//viewTrees();
}
//TreeProcessor.writeTreeDataToCSV(sortedTD,docID);
allTreeProcessors[docTypeNumber].unmergedMaps = new ArrayList<HashMap<String,TreeData>>(numLoaded+1);
}
int i= 0;
allParsedAndOrdered.clear();
String[] docTypes = new String[]{"otherSample","authorSample","toModify"};
for(i=0; i < 3; i++){
allTreeProcessors[i].unmergedMaps.add(allTreeProcessors[i].processedTrees);
allTreeProcessors[i].unmergedMaps.addAll(allTreeProcessors[i].loadedTreeDataMaps);
allTreeProcessors[i].mergeTreeDataLists(allTreeProcessors[i].unmergedMaps);
allParsedAndOrdered.put(docTypes[i],allTreeProcessors[i].sortTreeData(allTreeProcessors[i].mergedMap));
}
//ArrayList<TreeData> sortedTD = TreeContainer.sortTreeData(TreeContainer.allProcessedTrees);
//TreeContainer.writeTreeDataToCSV(sortedTD,"ALL_AUTHORS");
return allParsedAndOrdered;
}
