use of com.joliciel.talismane.machineLearning.features.RuntimeEnvironment in project talismane by joliciel-informatique.
the class PosTagFeatureTester method onNextPosTagSequence.
@Override
public void onNextPosTagSequence(PosTagSequence posTagSequence) throws TalismaneException {
PosTagSequence currentHistory = new PosTagSequence(posTagSequence.getTokenSequence());
for (PosTaggedToken posTaggedToken : posTagSequence) {
if (testWords.contains(posTaggedToken.getToken().getAnalyisText().toLowerCase())) {
StringBuilder sb = new StringBuilder();
boolean foundToken = false;
for (PosTaggedToken taggedToken : posTagSequence) {
if (taggedToken.equals(posTaggedToken)) {
sb.append(" [" + taggedToken.getToken().getOriginalText().replace(' ', '_') + "/" + taggedToken.getTag().toString() + "]");
foundToken = true;
} else if (foundToken) {
sb.append(" " + taggedToken.getToken().getOriginalText().replace(' ', '_'));
} else {
sb.append(" " + taggedToken.getToken().getOriginalText().replace(' ', '_') + "/" + taggedToken.getTag().toString());
}
}
LOG.debug(sb.toString());
String classification = posTaggedToken.getTag().getCode();
PosTaggerContext context = new PosTaggerContextImpl(posTaggedToken.getToken(), currentHistory);
List<FeatureResult<?>> posTagFeatureResults = new ArrayList<FeatureResult<?>>();
for (PosTaggerFeature<?> posTaggerFeature : posTaggerFeatures) {
RuntimeEnvironment env = new RuntimeEnvironment();
FeatureResult<?> featureResult = posTaggerFeature.check(context, env);
if (featureResult != null)
posTagFeatureResults.add(featureResult);
}
if (LOG.isTraceEnabled()) {
LOG.trace("Token: " + posTaggedToken.getToken().getAnalyisText());
for (FeatureResult<?> result : posTagFeatureResults) {
LOG.trace(result.toString());
}
}
for (FeatureResult<?> featureResult : posTagFeatureResults) {
Map<String, List<String>> classificationMap = featureResultMap.get(featureResult.toString());
if (classificationMap == null) {
classificationMap = new TreeMap<String, List<String>>();
featureResultMap.put(featureResult.toString(), classificationMap);
}
List<String> sentences = classificationMap.get(classification);
if (sentences == null) {
sentences = new ArrayList<String>();
classificationMap.put(classification, sentences);
}
sentences.add(sb.toString());
}
}
currentHistory.addPosTaggedToken(posTaggedToken);
}
}
use of com.joliciel.talismane.machineLearning.features.RuntimeEnvironment in project talismane by joliciel-informatique.
the class ParseFeatureTester method onNextParseConfiguration.
@Override
public void onNextParseConfiguration(ParseConfiguration parseConfiguration) throws TalismaneException {
ParseConfiguration currentConfiguration = new ParseConfiguration(parseConfiguration.getPosTagSequence());
for (Transition transition : parseConfiguration.getTransitions()) {
StringBuilder sb = new StringBuilder();
for (PosTaggedToken taggedToken : currentConfiguration.getPosTagSequence()) {
if (taggedToken.equals(currentConfiguration.getStack().getFirst())) {
sb.append(" #[" + taggedToken.getToken().getOriginalText().replace(' ', '_') + "/" + taggedToken.getTag().toString() + "]#");
} else if (taggedToken.equals(currentConfiguration.getBuffer().getFirst())) {
sb.append(" #[" + taggedToken.getToken().getOriginalText().replace(' ', '_') + "/" + taggedToken.getTag().toString() + "]#");
} else {
sb.append(" " + taggedToken.getToken().getOriginalText().replace(' ', '_') + "/" + taggedToken.getTag().toString());
}
}
sb.append(" ## Line: " + parseConfiguration.getSentence().getStartLineNumber());
if (LOG.isTraceEnabled())
LOG.trace(sb.toString());
List<FeatureResult<?>> parseFeatureResults = new ArrayList<FeatureResult<?>>();
for (ParseConfigurationFeature<?> parseFeature : parseFeatures) {
RuntimeEnvironment env = new RuntimeEnvironment();
FeatureResult<?> featureResult = parseFeature.check(currentConfiguration, env);
if (featureResult != null) {
parseFeatureResults.add(featureResult);
if (LOG.isTraceEnabled()) {
LOG.trace(featureResult.toString());
}
}
}
String classification = transition.getCode();
for (FeatureResult<?> featureResult : parseFeatureResults) {
Map<String, List<String>> classificationMap = featureResultMap.get(featureResult.toString());
if (classificationMap == null) {
classificationMap = new TreeMap<String, List<String>>();
featureResultMap.put(featureResult.toString(), classificationMap);
}
List<String> sentences = classificationMap.get(classification);
if (sentences == null) {
sentences = new ArrayList<String>();
classificationMap.put(classification, sentences);
}
sentences.add(sb.toString());
}
// apply the transition and up the index
currentConfiguration = new ParseConfiguration(currentConfiguration);
transition.apply(currentConfiguration);
}
}
use of com.joliciel.talismane.machineLearning.features.RuntimeEnvironment in project talismane by joliciel-informatique.
the class ForwardStatisticalPosTagger method tagSentence.
@Override
public List<PosTagSequence> tagSentence(List<TokenSequence> input) throws TalismaneException, IOException {
List<TokenSequence> tokenSequences = null;
if (this.propagateTokeniserBeam) {
tokenSequences = input;
} else {
tokenSequences = new ArrayList<>(1);
tokenSequences.add(input.get(0));
}
int sentenceLength = tokenSequences.get(0).getSentence().getText().length();
TreeMap<Double, PriorityQueue<PosTagSequence>> heaps = new TreeMap<Double, PriorityQueue<PosTagSequence>>();
PriorityQueue<PosTagSequence> heap0 = new PriorityQueue<PosTagSequence>();
for (TokenSequence tokenSequence : tokenSequences) {
// add an empty PosTagSequence for each token sequence
PosTagSequence emptySequence = new PosTagSequence(tokenSequence);
emptySequence.setScoringStrategy(decisionMaker.getDefaultScoringStrategy());
heap0.add(emptySequence);
}
heaps.put(0.0, heap0);
PriorityQueue<PosTagSequence> finalHeap = null;
while (heaps.size() > 0) {
Entry<Double, PriorityQueue<PosTagSequence>> heapEntry = heaps.pollFirstEntry();
if (LOG.isTraceEnabled()) {
LOG.trace("heap key: " + heapEntry.getKey() + ", sentence length: " + sentenceLength);
}
if (heapEntry.getKey() == sentenceLength) {
finalHeap = heapEntry.getValue();
break;
}
PriorityQueue<PosTagSequence> previousHeap = heapEntry.getValue();
// limit the breadth to K
int maxSequences = previousHeap.size() > this.beamWidth ? this.beamWidth : previousHeap.size();
for (int j = 0; j < maxSequences; j++) {
PosTagSequence history = previousHeap.poll();
Token token = history.getNextToken();
if (LOG.isTraceEnabled()) {
LOG.trace("#### Next history ( " + heapEntry.getKey() + "): " + history.toString());
LOG.trace("Prob: " + df.format(history.getScore()));
LOG.trace("Token: " + token.getText());
StringBuilder sb = new StringBuilder();
for (Token oneToken : history.getTokenSequence().listWithWhiteSpace()) {
if (oneToken.equals(token))
sb.append("[" + oneToken + "]");
else
sb.append(oneToken);
}
LOG.trace(sb.toString());
}
PosTaggerContext context = new PosTaggerContextImpl(token, history);
List<Decision> decisions = new ArrayList<Decision>();
boolean ruleApplied = false;
// assigned?
if (token.getAttributes().containsKey(PosTagger.POS_TAG_ATTRIBUTE)) {
StringAttribute posTagCodeAttribute = (StringAttribute) token.getAttributes().get(PosTagger.POS_TAG_ATTRIBUTE);
String posTagCode = posTagCodeAttribute.getValue();
Decision positiveRuleDecision = new Decision(posTagCode);
decisions.add(positiveRuleDecision);
positiveRuleDecision.addAuthority("tokenAttribute");
ruleApplied = true;
if (LOG.isTraceEnabled()) {
LOG.trace("Token has attribute \"" + PosTagger.POS_TAG_ATTRIBUTE + "\". Setting posTag to: " + posTagCode);
}
}
// test the positive rules on the current token
if (!ruleApplied) {
if (posTaggerPositiveRules != null) {
for (PosTaggerRule rule : posTaggerPositiveRules) {
if (LOG.isTraceEnabled()) {
LOG.trace("Checking rule: " + rule.getCondition().getName());
}
RuntimeEnvironment env = new RuntimeEnvironment();
FeatureResult<Boolean> ruleResult = rule.getCondition().check(context, env);
if (ruleResult != null && ruleResult.getOutcome()) {
Decision positiveRuleDecision = new Decision(rule.getTag().getCode());
decisions.add(positiveRuleDecision);
positiveRuleDecision.addAuthority(rule.getCondition().getName());
ruleApplied = true;
if (LOG.isTraceEnabled()) {
LOG.trace("Rule applies. Setting posTag to: " + rule.getTag().getCode());
}
break;
}
}
}
}
if (!ruleApplied) {
// test the features on the current token
List<FeatureResult<?>> featureResults = new ArrayList<FeatureResult<?>>();
for (PosTaggerFeature<?> posTaggerFeature : posTaggerFeatures) {
RuntimeEnvironment env = new RuntimeEnvironment();
FeatureResult<?> featureResult = posTaggerFeature.check(context, env);
if (featureResult != null)
featureResults.add(featureResult);
}
if (LOG.isTraceEnabled()) {
SortedSet<String> featureResultSet = featureResults.stream().map(f -> f.toString()).collect(Collectors.toCollection(() -> new TreeSet<String>()));
for (String featureResultString : featureResultSet) {
LOG.trace(featureResultString);
}
}
// evaluate the feature results using the maxent model
decisions = this.decisionMaker.decide(featureResults);
for (ClassificationObserver observer : this.observers) {
observer.onAnalyse(token, featureResults, decisions);
}
// apply the negative rules
Set<String> eliminatedPosTags = new TreeSet<String>();
if (posTaggerNegativeRules != null) {
for (PosTaggerRule rule : posTaggerNegativeRules) {
if (LOG.isTraceEnabled()) {
LOG.trace("Checking negative rule: " + rule.getCondition().getName());
}
RuntimeEnvironment env = new RuntimeEnvironment();
FeatureResult<Boolean> ruleResult = rule.getCondition().check(context, env);
if (ruleResult != null && ruleResult.getOutcome()) {
eliminatedPosTags.add(rule.getTag().getCode());
if (LOG.isTraceEnabled()) {
LOG.trace("Rule applies. Eliminating posTag: " + rule.getTag().getCode());
}
}
}
if (eliminatedPosTags.size() > 0) {
List<Decision> decisionShortList = new ArrayList<Decision>();
for (Decision decision : decisions) {
if (!eliminatedPosTags.contains(decision.getOutcome())) {
decisionShortList.add(decision);
} else {
LOG.trace("Eliminating decision: " + decision.toString());
}
}
if (decisionShortList.size() > 0) {
decisions = decisionShortList;
} else {
LOG.debug("All decisions eliminated! Restoring original decisions.");
}
}
}
// is this a known word in the lexicon?
if (LOG.isTraceEnabled()) {
String posTags = "";
for (PosTag onePosTag : token.getPossiblePosTags()) {
posTags += onePosTag.getCode() + ",";
}
LOG.trace("Token: " + token.getText() + ". PosTags: " + posTags);
}
List<Decision> decisionShortList = new ArrayList<Decision>();
for (Decision decision : decisions) {
if (decision.getProbability() >= MIN_PROB_TO_STORE) {
decisionShortList.add(decision);
}
}
if (decisionShortList.size() > 0) {
decisions = decisionShortList;
}
}
// outcome provided by MaxEnt
for (Decision decision : decisions) {
if (LOG.isTraceEnabled())
LOG.trace("Outcome: " + decision.getOutcome() + ", " + decision.getProbability());
PosTaggedToken posTaggedToken = new PosTaggedToken(token, decision, this.sessionId);
PosTagSequence sequence = new PosTagSequence(history);
sequence.addPosTaggedToken(posTaggedToken);
if (decision.isStatistical())
sequence.addDecision(decision);
double heapIndex = token.getEndIndex();
// it from regular ones
if (token.getStartIndex() == token.getEndIndex())
heapIndex += 0.5;
// if it's the last token, make sure we end
if (token.getIndex() == sequence.getTokenSequence().size() - 1)
heapIndex = sentenceLength;
if (LOG.isTraceEnabled())
LOG.trace("Heap index: " + heapIndex);
PriorityQueue<PosTagSequence> heap = heaps.get(heapIndex);
if (heap == null) {
heap = new PriorityQueue<PosTagSequence>();
heaps.put(heapIndex, heap);
}
heap.add(sequence);
}
// next outcome for this token
}
// next history
}
// next atomic index
// return the best sequence on the heap
List<PosTagSequence> sequences = new ArrayList<PosTagSequence>();
int i = 0;
while (!finalHeap.isEmpty()) {
// clone the pos tag sequences to ensure they don't share any underlying
// data (e.g. token sequences)
sequences.add(finalHeap.poll().clonePosTagSequence());
i++;
if (i >= this.getBeamWidth())
break;
}
// apply post-processing filters
if (LOG.isDebugEnabled()) {
LOG.debug("####Final postag sequences:");
int j = 1;
for (PosTagSequence sequence : sequences) {
if (LOG.isDebugEnabled()) {
LOG.debug("Sequence " + (j++) + ", score=" + df.format(sequence.getScore()));
LOG.debug("Sequence: " + sequence);
}
}
}
return sequences;
}
use of com.joliciel.talismane.machineLearning.features.RuntimeEnvironment in project talismane by joliciel-informatique.
the class PatternTokeniser method tokeniseInternal.
@Override
protected List<TokenisedAtomicTokenSequence> tokeniseInternal(TokenSequence initialSequence, Sentence sentence) throws TalismaneException, IOException {
List<TokenisedAtomicTokenSequence> sequences;
// Assign each separator its default value
List<TokeniserOutcome> defaultOutcomes = this.tokeniserPatternManager.getDefaultOutcomes(initialSequence);
List<Decision> defaultDecisions = new ArrayList<Decision>(defaultOutcomes.size());
for (TokeniserOutcome outcome : defaultOutcomes) {
Decision tokeniserDecision = new Decision(outcome.name());
tokeniserDecision.addAuthority("_" + this.getClass().getSimpleName());
tokeniserDecision.addAuthority("_" + "DefaultDecision");
defaultDecisions.add(tokeniserDecision);
}
// For each test pattern, see if anything in the sentence matches it
if (this.decisionMaker != null) {
List<TokenPatternMatchSequence> matchingSequences = new ArrayList<TokenPatternMatchSequence>();
Map<Token, Set<TokenPatternMatchSequence>> tokenMatchSequenceMap = new HashMap<Token, Set<TokenPatternMatchSequence>>();
Map<TokenPatternMatchSequence, TokenPatternMatch> primaryMatchMap = new HashMap<TokenPatternMatchSequence, TokenPatternMatch>();
Set<Token> matchedTokens = new HashSet<Token>();
for (TokenPattern parsedPattern : this.getTokeniserPatternManager().getParsedTestPatterns()) {
List<TokenPatternMatchSequence> matchesForThisPattern = parsedPattern.match(initialSequence);
for (TokenPatternMatchSequence matchSequence : matchesForThisPattern) {
if (matchSequence.getTokensToCheck().size() > 0) {
matchingSequences.add(matchSequence);
matchedTokens.addAll(matchSequence.getTokensToCheck());
TokenPatternMatch primaryMatch = null;
Token token = matchSequence.getTokensToCheck().get(0);
Set<TokenPatternMatchSequence> matchSequences = tokenMatchSequenceMap.get(token);
if (matchSequences == null) {
matchSequences = new TreeSet<TokenPatternMatchSequence>();
tokenMatchSequenceMap.put(token, matchSequences);
}
matchSequences.add(matchSequence);
for (TokenPatternMatch patternMatch : matchSequence.getTokenPatternMatches()) {
if (patternMatch.getToken().equals(token)) {
primaryMatch = patternMatch;
break;
}
}
if (LOG.isTraceEnabled()) {
LOG.trace("Found match: " + primaryMatch);
}
primaryMatchMap.put(matchSequence, primaryMatch);
}
}
}
// we want to create the n most likely token sequences
// the sequence has to correspond to a token pattern
Map<TokenPatternMatchSequence, List<Decision>> matchSequenceDecisionMap = new HashMap<TokenPatternMatchSequence, List<Decision>>();
for (TokenPatternMatchSequence matchSequence : matchingSequences) {
TokenPatternMatch match = primaryMatchMap.get(matchSequence);
LOG.debug("next pattern match: " + match.toString());
List<FeatureResult<?>> tokenFeatureResults = new ArrayList<FeatureResult<?>>();
for (TokenPatternMatchFeature<?> feature : features) {
RuntimeEnvironment env = new RuntimeEnvironment();
FeatureResult<?> featureResult = feature.check(match, env);
if (featureResult != null) {
tokenFeatureResults.add(featureResult);
}
}
if (LOG.isTraceEnabled()) {
SortedSet<String> featureResultSet = tokenFeatureResults.stream().map(f -> f.toString()).collect(Collectors.toCollection(() -> new TreeSet<String>()));
for (String featureResultString : featureResultSet) {
LOG.trace(featureResultString);
}
}
List<Decision> decisions = this.decisionMaker.decide(tokenFeatureResults);
for (ClassificationObserver observer : this.observers) observer.onAnalyse(match.getToken(), tokenFeatureResults, decisions);
for (Decision decision : decisions) {
decision.addAuthority("_" + this.getClass().getSimpleName());
decision.addAuthority("_" + "Patterns");
decision.addAuthority(match.getPattern().getName());
}
matchSequenceDecisionMap.put(matchSequence, decisions);
}
// initially create a heap with a single, empty sequence
PriorityQueue<TokenisedAtomicTokenSequence> heap = new PriorityQueue<TokenisedAtomicTokenSequence>();
TokenisedAtomicTokenSequence emptySequence = new TokenisedAtomicTokenSequence(sentence, 0, this.getSessionId());
heap.add(emptySequence);
for (int i = 0; i < initialSequence.listWithWhiteSpace().size(); i++) {
Token token = initialSequence.listWithWhiteSpace().get(i);
if (LOG.isTraceEnabled()) {
LOG.trace("Token : \"" + token.getAnalyisText() + "\"");
}
// build a new heap for this iteration
PriorityQueue<TokenisedAtomicTokenSequence> previousHeap = heap;
heap = new PriorityQueue<TokenisedAtomicTokenSequence>();
if (i == 0) {
// first token is always "separate" from the outside world
Decision decision = new Decision(TokeniserOutcome.SEPARATE.name());
decision.addAuthority("_" + this.getClass().getSimpleName());
decision.addAuthority("_" + "DefaultDecision");
TaggedToken<TokeniserOutcome> taggedToken = new TaggedToken<>(token, decision, TokeniserOutcome.valueOf(decision.getOutcome()));
TokenisedAtomicTokenSequence newSequence = new TokenisedAtomicTokenSequence(emptySequence);
newSequence.add(taggedToken);
heap.add(newSequence);
continue;
}
// limit the heap breadth to K
int maxSequences = previousHeap.size() > this.getBeamWidth() ? this.getBeamWidth() : previousHeap.size();
for (int j = 0; j < maxSequences; j++) {
TokenisedAtomicTokenSequence history = previousHeap.poll();
// Find the separating & non-separating decisions
if (history.size() > i) {
// token already added as part of a sequence
// introduced by another token
heap.add(history);
} else if (tokenMatchSequenceMap.containsKey(token)) {
// token begins one or more match sequences
// these are ordered from shortest to longest (via
// TreeSet)
List<TokenPatternMatchSequence> matchSequences = new ArrayList<TokenPatternMatchSequence>(tokenMatchSequenceMap.get(token));
// Since sequences P1..Pn contain each other,
// there can be exactly matchSequences.size()
// consistent solutions
// Assume the default is separate
// 0: all separate
// 1: join P1, separate rest
// 2: join P2, separate rest
// ...
// n: join Pn
// We need to add each of these to the heap
// by taking the product of all probabilities
// consistent with each solution
// The probabities for each solution are (j=join,
// s=separate)
// All separate: s1 x s2 x ... x sn
// P1: j1 x s2 x ... x sn
// P2: j1 x j2 x ... x sn
// ...
// Pn: j1 x j2 x ... x jn
// Any solution of the form s1 x j2 would be
// inconsistent, and is not considered
// If Pi and Pj start and end on the exact same
// token, then the solution for both is
// Pi: j1 x ... x ji x jj x sj+1 ... x sn
// Pj: j1 x ... x ji x jj x sj+1 ... x sn
// Note of course that we're never likely to have
// more than two Ps here,
// but we need a solution for more just to be sure
// to be sure
TokeniserOutcome defaultOutcome = TokeniserOutcome.valueOf(defaultDecisions.get(token.getIndexWithWhiteSpace()).getOutcome());
TokeniserOutcome otherOutcome = null;
if (defaultOutcome == TokeniserOutcome.SEPARATE)
otherOutcome = TokeniserOutcome.JOIN;
else
otherOutcome = TokeniserOutcome.SEPARATE;
double[] decisionProbs = new double[matchSequences.size() + 1];
for (int k = 0; k < decisionProbs.length; k++) decisionProbs[k] = 1;
// Note: k0 = default decision (e.g. separate all),
// k1=first pattern
// p1 = first pattern
int p = 1;
int prevEndIndex = -1;
for (TokenPatternMatchSequence matchSequence : matchSequences) {
int endIndex = matchSequence.getTokensToCheck().get(matchSequence.getTokensToCheck().size() - 1).getEndIndex();
List<Decision> decisions = matchSequenceDecisionMap.get(matchSequence);
for (Decision decision : decisions) {
for (int k = 0; k < decisionProbs.length; k++) {
if (decision.getOutcome().equals(defaultOutcome.name())) {
// e.g. separate in most cases
if (k < p && endIndex > prevEndIndex)
decisionProbs[k] *= decision.getProbability();
else if (k + 1 < p && endIndex <= prevEndIndex)
decisionProbs[k] *= decision.getProbability();
} else {
// e.g. join in most cases
if (k >= p && endIndex > prevEndIndex)
decisionProbs[k] *= decision.getProbability();
else if (k + 1 >= p && endIndex <= prevEndIndex)
decisionProbs[k] *= decision.getProbability();
}
}
// next k
}
// next decision (only 2 of these)
prevEndIndex = endIndex;
p++;
}
// transform to probability distribution
double sumProbs = 0;
for (int k = 0; k < decisionProbs.length; k++) sumProbs += decisionProbs[k];
if (sumProbs > 0)
for (int k = 0; k < decisionProbs.length; k++) decisionProbs[k] /= sumProbs;
// Apply default decision
// Since this is the default decision for all tokens
// in the sequence, we don't add the other tokens
// for now,
// so as to allow them
// to get examined one at a time, just in case one
// of them starts its own separate sequence
Decision defaultDecision = new Decision(defaultOutcome.name(), decisionProbs[0]);
defaultDecision.addAuthority("_" + this.getClass().getSimpleName());
defaultDecision.addAuthority("_" + "Patterns");
for (TokenPatternMatchSequence matchSequence : matchSequences) {
defaultDecision.addAuthority(matchSequence.getTokenPattern().getName());
}
TaggedToken<TokeniserOutcome> defaultTaggedToken = new TaggedToken<>(token, defaultDecision, TokeniserOutcome.valueOf(defaultDecision.getOutcome()));
TokenisedAtomicTokenSequence defaultSequence = new TokenisedAtomicTokenSequence(history);
defaultSequence.add(defaultTaggedToken);
defaultSequence.addDecision(defaultDecision);
heap.add(defaultSequence);
// Apply one non-default decision per match sequence
for (int k = 0; k < matchSequences.size(); k++) {
TokenPatternMatchSequence matchSequence = matchSequences.get(k);
double prob = decisionProbs[k + 1];
Decision decision = new Decision(otherOutcome.name(), prob);
decision.addAuthority("_" + this.getClass().getSimpleName());
decision.addAuthority("_" + "Patterns");
decision.addAuthority(matchSequence.getTokenPattern().getName());
TaggedToken<TokeniserOutcome> taggedToken = new TaggedToken<>(token, decision, TokeniserOutcome.valueOf(decision.getOutcome()));
TokenisedAtomicTokenSequence newSequence = new TokenisedAtomicTokenSequence(history);
newSequence.add(taggedToken);
newSequence.addDecision(decision);
// in this sequence to the solution
for (Token tokenInSequence : matchSequence.getTokensToCheck()) {
if (tokenInSequence.equals(token)) {
continue;
}
Decision decisionInSequence = new Decision(decision.getOutcome());
decisionInSequence.addAuthority("_" + this.getClass().getSimpleName());
decisionInSequence.addAuthority("_" + "DecisionInSequence");
decisionInSequence.addAuthority("_" + "DecisionInSequence_non_default");
decisionInSequence.addAuthority("_" + "Patterns");
TaggedToken<TokeniserOutcome> taggedTokenInSequence = new TaggedToken<>(tokenInSequence, decisionInSequence, TokeniserOutcome.valueOf(decisionInSequence.getOutcome()));
newSequence.add(taggedTokenInSequence);
}
heap.add(newSequence);
}
// next sequence
} else {
// token doesn't start match sequence, and hasn't
// already been added to the current sequence
Decision decision = defaultDecisions.get(i);
if (matchedTokens.contains(token)) {
decision = new Decision(decision.getOutcome());
decision.addAuthority("_" + this.getClass().getSimpleName());
decision.addAuthority("_" + "DecisionInSequence");
decision.addAuthority("_" + "DecisionInSequence_default");
decision.addAuthority("_" + "Patterns");
}
TaggedToken<TokeniserOutcome> taggedToken = new TaggedToken<>(token, decision, TokeniserOutcome.valueOf(decision.getOutcome()));
TokenisedAtomicTokenSequence newSequence = new TokenisedAtomicTokenSequence(history);
newSequence.add(taggedToken);
heap.add(newSequence);
}
}
// next sequence in the old heap
}
// next token
sequences = new ArrayList<TokenisedAtomicTokenSequence>();
int k = 0;
while (!heap.isEmpty()) {
sequences.add(heap.poll());
k++;
if (k >= this.getBeamWidth())
break;
}
} else {
sequences = new ArrayList<TokenisedAtomicTokenSequence>();
TokenisedAtomicTokenSequence defaultSequence = new TokenisedAtomicTokenSequence(sentence, 0, this.getSessionId());
int i = 0;
for (Token token : initialSequence.listWithWhiteSpace()) {
Decision decision = defaultDecisions.get(i++);
TaggedToken<TokeniserOutcome> taggedToken = new TaggedToken<>(token, decision, TokeniserOutcome.valueOf(decision.getOutcome()));
defaultSequence.add(taggedToken);
}
sequences.add(defaultSequence);
}
// have decision maker?
return sequences;
}
use of com.joliciel.talismane.machineLearning.features.RuntimeEnvironment in project talismane by joliciel-informatique.
the class CombinedLexicalAttributesTest method testCheckInternalMultipleEntries.
@Test
public void testCheckInternalMultipleEntries() throws Exception {
System.setProperty("config.file", "src/test/resources/testWithLex.conf");
ConfigFactory.invalidateCaches();
final Config config = ConfigFactory.load();
final String sessionId = "test";
Sentence sentence = new Sentence("je demande", sessionId);
TokenSequence tokenSequence = new TokenSequence(sentence, sessionId);
Token token = new Token("demande", tokenSequence, 1, "je ".length(), "je demande".length(), sessionId);
Decision decision = new Decision("V", 1.0);
final PosTaggedToken posTaggedToken = new PosTaggedToken(token, decision, sessionId);
PosTaggedTokenAddressFunction<PosTaggerContext> addressFunction = new AbstractPosTaggedTokenAddressFunction() {
@Override
protected FeatureResult<PosTaggedTokenWrapper> checkInternal(PosTaggerContext context, RuntimeEnvironment env) {
return this.generateResult(posTaggedToken);
}
};
StringLiteralFeature<PosTaggedTokenWrapper> person = new StringLiteralFeature<>(LexicalAttribute.Person.name());
CombinedLexicalAttributesFeature<PosTaggerContext> feature = new CombinedLexicalAttributesFeature<>(addressFunction, person);
PosTagSequence history = new PosTagSequence(tokenSequence);
PosTaggerContext context = new PosTaggerContextImpl(token, history);
RuntimeEnvironment env = new RuntimeEnvironment();
FeatureResult<String> featureResult = feature.checkInternal(context, env);
String outcome = featureResult.getOutcome();
System.out.println(outcome);
assertEquals("1;3", outcome);
}
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