Example 51 with Term
use of nars.language.Term in project opennars by opennars.
the class SyllogisticRules method conditionalDedInd.
/**
* {<(&&, S1, S2, S3) ==> P>, S1} |- <(&&, S2, S3) ==> P> {<(&&, S2, S3) ==>
* P>, <S1 ==> S2>} |- <(&&, S1, S3) ==> P> {<(&&, S1, S3) ==> P>, <S1 ==>
* S2>} |- <(&&, S2, S3) ==> P>
*
* @param premise1 The conditional premise
* @param index The location of the shared term in the condition of premise1
* @param premise2 The premise which, or part of which, appears in the
* condition of premise1
* @param side The location of the shared term in premise2: 0 for subject, 1
* for predicate, -1 for the whole term
* @param nal Reference to the memory
*/
static void conditionalDedInd(Sentence premise1Sentence, Implication premise1, short index, Term premise2, int side, DerivationContext nal) {
Task task = nal.getCurrentTask();
Sentence taskSentence = task.sentence;
Sentence belief = nal.getCurrentBelief();
boolean deduction = (side != 0);
boolean conditionalTask = Variables.hasSubstitute(Symbols.VAR_INDEPENDENT, premise2, belief.term);
Term commonComponent;
Term newComponent = null;
if (side == 0) {
commonComponent = ((Statement) premise2).getSubject();
newComponent = ((Statement) premise2).getPredicate();
} else if (side == 1) {
commonComponent = ((Statement) premise2).getPredicate();
newComponent = ((Statement) premise2).getSubject();
} else {
commonComponent = premise2;
}
Term subj = premise1.getSubject();
if (!(subj instanceof Conjunction)) {
return;
}
Conjunction oldCondition = (Conjunction) subj;
int index2 = Terms.indexOf(oldCondition.term, commonComponent);
if (index2 >= 0) {
index = (short) index2;
} else {
Term[] u = new Term[] { premise1, premise2 };
boolean match = Variables.unify(Symbols.VAR_INDEPENDENT, oldCondition.term[index], commonComponent, u);
premise1 = (Implication) u[0];
premise2 = u[1];
if (!match && (commonComponent.getClass() == oldCondition.getClass())) {
CompoundTerm compoundCommonComponent = ((CompoundTerm) commonComponent);
if ((oldCondition.term.length > index) && (compoundCommonComponent.term.length > index)) {
// assumption: { was missing
u = new Term[] { premise1, premise2 };
match = Variables.unify(Symbols.VAR_INDEPENDENT, oldCondition.term[index], compoundCommonComponent.term[index], u);
premise1 = (Implication) u[0];
premise2 = u[1];
}
}
if (!match) {
return;
}
}
int conjunctionOrder = subj.getTemporalOrder();
if (conjunctionOrder == ORDER_FORWARD) {
if (index > 0) {
return;
}
if ((side == 0) && (premise2.getTemporalOrder() == ORDER_FORWARD)) {
return;
}
if ((side == 1) && (premise2.getTemporalOrder() == ORDER_BACKWARD)) {
return;
}
}
Term newCondition;
if (oldCondition.equals(commonComponent)) {
newCondition = null;
} else {
newCondition = oldCondition.setComponent(index, newComponent, nal.mem());
}
Term content;
long delta = 0;
long mintime = 0;
long maxtime = 0;
boolean predictedEvent = false;
if (newCondition != null) {
if (newCondition instanceof Interval) {
content = premise1.getPredicate();
delta = ((Interval) newCondition).time;
if (taskSentence.getOccurenceTime() != Stamp.ETERNAL) {
mintime = taskSentence.getOccurenceTime() + ((Interval) newCondition).time - 1;
maxtime = taskSentence.getOccurenceTime() + ((Interval) newCondition).time + 2;
predictedEvent = true;
}
} else {
while ((newCondition instanceof Conjunction) && (((CompoundTerm) newCondition).term[0] instanceof Interval)) {
Interval interval = (Interval) ((CompoundTerm) newCondition).term[0];
delta += interval.time;
newCondition = ((CompoundTerm) newCondition).setComponent(0, null, nal.mem());
}
content = Statement.make(premise1, newCondition, premise1.getPredicate(), premise1.getTemporalOrder());
}
} else {
content = premise1.getPredicate();
}
if (content == null)
return;
long occurrence_time = nal.getTheNewStamp().getOccurrenceTime();
if (delta != 0) {
long baseTime = taskSentence.getOccurenceTime();
if (baseTime != Stamp.ETERNAL) {
baseTime += delta;
occurrence_time = baseTime;
}
}
TruthValue truth1 = taskSentence.truth;
TruthValue truth2 = belief.truth;
TruthValue truth = null;
BudgetValue budget;
if (taskSentence.isQuestion() || taskSentence.isQuest()) {
budget = BudgetFunctions.backwardWeak(truth2, nal);
} else {
if (taskSentence.isGoal()) {
if (conditionalTask) {
truth = TruthFunctions.desireWeak(truth1, truth2);
} else if (deduction) {
truth = TruthFunctions.desireInd(truth1, truth2);
} else {
truth = TruthFunctions.desireDed(truth1, truth2);
}
} else {
if (deduction) {
truth = TruthFunctions.deduction(truth1, truth2);
} else if (conditionalTask) {
truth = TruthFunctions.induction(truth2, truth1);
} else {
truth = TruthFunctions.induction(truth1, truth2);
}
}
budget = BudgetFunctions.forward(truth, nal);
}
nal.getTheNewStamp().setOccurrenceTime(occurrence_time);
// (allow overlap) when deduction on judgment
List<Task> ret = nal.doublePremiseTask(content, truth, budget, false, taskSentence.isJudgment() && deduction);
if (!nal.evidentalOverlap && ret != null && ret.size() > 0) {
if (predictedEvent && taskSentence.isJudgment() && truth != null && truth.getExpectation() > Parameters.DEFAULT_CONFIRMATION_EXPECTATION && !premise1Sentence.stamp.alreadyAnticipatedNegConfirmation) {
premise1Sentence.stamp.alreadyAnticipatedNegConfirmation = true;
ConceptProcessing.generatePotentialNegConfirmation(nal, premise1Sentence, budget, mintime, maxtime, 1);
}
}
}
Also used :
CompoundTerm(nars.language.CompoundTerm)
BudgetValue(nars.entity.BudgetValue)
Task(nars.entity.Task)
Statement(nars.language.Statement)
CompoundTerm(nars.language.CompoundTerm)
Term(nars.language.Term)
TruthValue(nars.entity.TruthValue)
Conjunction(nars.language.Conjunction)
Sentence(nars.entity.Sentence)
Interval(nars.language.Interval)
Example 52 with Term
use of nars.language.Term in project opennars by opennars.
the class SyllogisticRules method conditionalAna.
/**
* {<(&&, S1, S2, S3) <=> P>, S1} |- <(&&, S2, S3) <=> P> {<(&&, S2, S3) <=> P>,
* <S1 ==> S2>} |- <(&&, S1, S3) <=> P> {<(&&, S1, S3) <=> P>, <S1 ==>
*
* @param premise1 The equivalence premise
* @param index The location of the shared term in the condition of premise1
* @param premise2 The premise which, or part of which, appears in the
* condition of premise1
* @param side The location of the shared term in premise2: 0 for subject, 1
* for predicate, -1 for the whole term
* @param nal Reference to the memory
*/
static void conditionalAna(Equivalence premise1, short index, Term premise2, int side, DerivationContext nal) {
Task task = nal.getCurrentTask();
Sentence taskSentence = task.sentence;
Sentence belief = nal.getCurrentBelief();
boolean conditionalTask = Variables.hasSubstitute(Symbols.VAR_INDEPENDENT, premise2, belief.term);
Term commonComponent;
Term newComponent = null;
if (side == 0) {
commonComponent = ((Statement) premise2).getSubject();
newComponent = ((Statement) premise2).getPredicate();
} else if (side == 1) {
commonComponent = ((Statement) premise2).getPredicate();
newComponent = ((Statement) premise2).getSubject();
} else {
commonComponent = premise2;
}
Term tm = premise1.getSubject();
if (!(tm instanceof Conjunction)) {
return;
}
Conjunction oldCondition = (Conjunction) tm;
Term[] u = new Term[] { premise1, premise2 };
boolean match = Variables.unify(Symbols.VAR_DEPENDENT, oldCondition.term[index], commonComponent, u);
premise1 = (Equivalence) u[0];
premise2 = u[1];
if (!match && (commonComponent.getClass() == oldCondition.getClass())) {
u = new Term[] { premise1, premise2 };
match = Variables.unify(Symbols.VAR_DEPENDENT, oldCondition.term[index], ((CompoundTerm) commonComponent).term[index], u);
premise1 = (Equivalence) u[0];
premise2 = u[1];
}
if (!match) {
return;
}
int conjunctionOrder = oldCondition.getTemporalOrder();
if (conjunctionOrder == ORDER_FORWARD) {
if (index > 0) {
return;
}
if ((side == 0) && (premise2.getTemporalOrder() == ORDER_FORWARD)) {
return;
}
if ((side == 1) && (premise2.getTemporalOrder() == ORDER_BACKWARD)) {
return;
}
}
Term newCondition;
if (oldCondition.equals(commonComponent)) {
newCondition = null;
} else {
newCondition = oldCondition.setComponent(index, newComponent, nal.mem());
}
Term content;
if (newCondition != null) {
content = Statement.make(premise1, newCondition, premise1.getPredicate(), premise1.getTemporalOrder());
} else {
content = premise1.getPredicate();
}
if (content == null)
return;
TruthValue truth1 = taskSentence.truth;
TruthValue truth2 = belief.truth;
TruthValue truth = null;
BudgetValue budget;
if (taskSentence.isQuestion() || taskSentence.isQuest()) {
budget = BudgetFunctions.backwardWeak(truth2, nal);
} else {
if (taskSentence.isGoal()) {
if (conditionalTask) {
truth = TruthFunctions.desireWeak(truth1, truth2);
} else {
truth = TruthFunctions.desireDed(truth1, truth2);
}
} else {
if (conditionalTask) {
truth = TruthFunctions.comparison(truth1, truth2);
} else {
truth = TruthFunctions.analogy(truth1, truth2);
}
}
budget = BudgetFunctions.forward(truth, nal);
}
// (allow overlap) when !conditionalTask on judgment
nal.doublePremiseTask(content, truth, budget, false, taskSentence.isJudgment() && !conditionalTask);
}
Also used :
BudgetValue(nars.entity.BudgetValue)
Task(nars.entity.Task)
Statement(nars.language.Statement)
TruthValue(nars.entity.TruthValue)
Conjunction(nars.language.Conjunction)
CompoundTerm(nars.language.CompoundTerm)
Term(nars.language.Term)
Sentence(nars.entity.Sentence)
Example 53 with Term
use of nars.language.Term in project opennars by opennars.
the class SyllogisticRules method detachment.
static void detachment(Sentence mainSentence, Sentence subSentence, int side, boolean checkTermAgain, DerivationContext nal) {
Statement statement = (Statement) mainSentence.term;
if (!(statement instanceof Implication) && !(statement instanceof Equivalence)) {
return;
}
Term subject = statement.getSubject();
Term predicate = statement.getPredicate();
Term content;
Term term = subSentence.term;
if ((side == 0) && (!checkTermAgain || term.equals(subject))) {
content = predicate;
} else if ((side == 1) && (!checkTermAgain || term.equals(predicate))) {
content = subject;
} else {
return;
}
if ((content instanceof Statement) && ((Statement) content).invalid()) {
return;
}
Sentence taskSentence = nal.getCurrentTask().sentence;
Sentence beliefSentence = nal.getCurrentBelief();
if (beliefSentence == null)
return;
int order = statement.getTemporalOrder();
long occurrence_time = nal.getTheNewStamp().getOccurrenceTime();
if ((order != ORDER_NONE) && (order != ORDER_INVALID)) {
long baseTime = subSentence.getOccurenceTime();
if (baseTime == Stamp.ETERNAL) {
// =/> always should produce events
baseTime = nal.getTime();
}
long inc = order * Parameters.DURATION;
occurrence_time = (side == 0) ? baseTime + inc : baseTime - inc;
}
TruthValue beliefTruth = beliefSentence.truth;
TruthValue truth1 = mainSentence.truth;
TruthValue truth2 = subSentence.truth;
TruthValue truth = null;
boolean strong = false;
BudgetValue budget;
if (taskSentence.isQuestion()) {
if (statement instanceof Equivalence) {
budget = BudgetFunctions.backward(beliefTruth, nal);
} else if (side == 0) {
budget = BudgetFunctions.backwardWeak(beliefTruth, nal);
} else {
budget = BudgetFunctions.backward(beliefTruth, nal);
}
} else if (taskSentence.isQuest()) {
if (statement instanceof Equivalence) {
budget = BudgetFunctions.backwardWeak(beliefTruth, nal);
} else if (side == 0) {
budget = BudgetFunctions.backward(beliefTruth, nal);
} else {
budget = BudgetFunctions.backwardWeak(beliefTruth, nal);
}
} else {
if (taskSentence.isGoal()) {
if (statement instanceof Equivalence) {
truth = TruthFunctions.desireStrong(truth1, truth2);
// not for goals anymore
strong = true;
} else if (side == 0) {
truth = TruthFunctions.desireInd(truth1, truth2);
} else {
truth = TruthFunctions.desireDed(truth1, truth2);
// not for goals anymore
strong = true;
}
} else {
// isJudgment
if (statement instanceof Equivalence) {
truth = TruthFunctions.analogy(truth2, truth1);
strong = true;
} else if (side == 0) {
truth = TruthFunctions.deduction(truth1, truth2);
strong = true;
} else {
truth = TruthFunctions.abduction(truth2, truth1);
}
}
budget = BudgetFunctions.forward(truth, nal);
}
if (!Variables.indepVarUsedInvalid(content)) {
boolean allowOverlap = taskSentence.isJudgment() && strong;
nal.getTheNewStamp().setOccurrenceTime(occurrence_time);
// (strong) when strong on judgement
nal.doublePremiseTask(content, truth, budget, false, allowOverlap);
}
}
Also used :
BudgetValue(nars.entity.BudgetValue)
Equivalence(nars.language.Equivalence)
Statement(nars.language.Statement)
TruthValue(nars.entity.TruthValue)
CompoundTerm(nars.language.CompoundTerm)
Term(nars.language.Term)
Implication(nars.language.Implication)
Sentence(nars.entity.Sentence)
Example 54 with Term
use of nars.language.Term in project opennars by opennars.
the class TemporalRules method temporalInduction.
// TODO maybe split &/ case into own function
public static List<Task> temporalInduction(final Sentence s1, final Sentence s2, final nars.control.DerivationContext nal, boolean SucceedingEventsInduction, boolean addToMemory, boolean allowSequence) {
if ((s1.truth == null) || (s2.truth == null) || s1.punctuation != Symbols.JUDGMENT_MARK || s2.punctuation != Symbols.JUDGMENT_MARK || s1.isEternal() || s2.isEternal())
return Collections.EMPTY_LIST;
Term t1 = s1.term;
Term t2 = s2.term;
boolean deriveSequenceOnly = (!addToMemory) || Statement.invalidStatement(t1, t2, true);
if (Statement.invalidStatement(t1, t2, false))
return Collections.EMPTY_LIST;
Term t11 = null;
Term t22 = null;
if (!deriveSequenceOnly && termForTemporalInduction(t1) && termForTemporalInduction(t2)) {
Statement ss1 = (Statement) t1;
Statement ss2 = (Statement) t2;
Variable var1 = new Variable("$0");
Variable var2 = new Variable("$1");
if (ss2.containsTermRecursively(ss1.getSubject())) {
HashMap<Term, Term> subs = new HashMap();
subs.put(ss1.getSubject(), var1);
if (ss2.containsTermRecursively(ss1.getPredicate())) {
subs.put(ss1.getPredicate(), var2);
}
t11 = ss1.applySubstitute(subs);
t22 = ss2.applySubstitute(subs);
}
if (ss1.containsTermRecursively(ss2.getSubject())) {
HashMap<Term, Term> subs = new HashMap();
subs.put(ss2.getSubject(), var1);
if (ss1.containsTermRecursively(ss2.getPredicate())) {
subs.put(ss2.getPredicate(), var2);
}
t11 = ss1.applySubstitute(subs);
t22 = ss2.applySubstitute(subs);
}
// allow also temporal induction on operator arguments:
if (ss2 instanceof Operation ^ ss1 instanceof Operation) {
if (ss2 instanceof Operation && !(ss2.getSubject() instanceof Variable)) {
// it is an operation, let's look if one of the arguments is same as the subject of the other term
Term comp = ss1.getSubject();
Term ss2_term = ((Operation) ss2).getSubject();
boolean applicableVariableType = !(comp instanceof Variable && ((Variable) comp).hasVarIndep());
if (ss2_term instanceof Product) {
Product ss2_prod = (Product) ss2_term;
if (applicableVariableType && Terms.contains(ss2_prod.term, comp)) {
// only if there is one and it isnt a variable already
Term[] ars = ss2_prod.cloneTermsReplacing(comp, var1);
t11 = Statement.make(ss1, var1, ss1.getPredicate());
Operation op = (Operation) Operation.make(new Product(ars), ss2.getPredicate());
t22 = op;
}
}
}
if (ss1 instanceof Operation && !(ss1.getSubject() instanceof Variable)) {
// it is an operation, let's look if one of the arguments is same as the subject of the other term
Term comp = ss2.getSubject();
Term ss1_term = ((Operation) ss1).getSubject();
boolean applicableVariableType = !(comp instanceof Variable && ((Variable) comp).hasVarIndep());
if (ss1_term instanceof Product) {
Product ss1_prod = (Product) ss1_term;
if (applicableVariableType && Terms.contains(ss1_prod.term, comp)) {
// only if there is one and it isnt a variable already
Term[] ars = ss1_prod.cloneTermsReplacing(comp, var1);
t22 = Statement.make(ss2, var1, ss2.getPredicate());
Operation op = (Operation) Operation.make(new Product(ars), ss1.getPredicate());
t11 = op;
}
}
}
}
}
int durationCycles = Parameters.DURATION;
long time1 = s1.getOccurenceTime();
long time2 = s2.getOccurenceTime();
long timeDiff = time2 - time1;
Interval interval = null;
if (!concurrent(time1, time2, durationCycles)) {
interval = new Interval(Math.abs(timeDiff));
if (timeDiff > 0) {
t1 = Conjunction.make(t1, interval, ORDER_FORWARD);
if (t11 != null) {
t11 = Conjunction.make(t11, interval, ORDER_FORWARD);
}
} else {
t2 = Conjunction.make(t2, interval, ORDER_FORWARD);
if (t22 != null) {
t22 = Conjunction.make(t22, interval, ORDER_FORWARD);
}
}
}
int order = order(timeDiff, durationCycles);
TruthValue givenTruth1 = s1.truth;
TruthValue givenTruth2 = s2.truth;
// This code adds a penalty for large time distance (TODO probably revise)
Sentence s3 = s2.projection(s1.getOccurenceTime(), nal.memory.time());
givenTruth2 = s3.truth;
// Truth and priority calculations
TruthValue truth1 = TruthFunctions.induction(givenTruth1, givenTruth2);
TruthValue truth2 = TruthFunctions.induction(givenTruth2, givenTruth1);
TruthValue truth3 = TruthFunctions.comparison(givenTruth1, givenTruth2);
TruthValue truth4 = TruthFunctions.intersection(givenTruth1, givenTruth2);
BudgetValue budget1 = BudgetFunctions.forward(truth1, nal);
budget1.setPriority(budget1.getPriority() * Parameters.TEMPORAL_INDUCTION_PRIORITY_PENALTY);
BudgetValue budget2 = BudgetFunctions.forward(truth2, nal);
budget2.setPriority(budget2.getPriority() * Parameters.TEMPORAL_INDUCTION_PRIORITY_PENALTY);
BudgetValue budget3 = BudgetFunctions.forward(truth3, nal);
budget3.setPriority(budget3.getPriority() * Parameters.TEMPORAL_INDUCTION_PRIORITY_PENALTY);
// this one is sequence in sequenceBag, no need to reduce here
BudgetValue budget4 = BudgetFunctions.forward(truth4, nal);
Statement statement1 = Implication.make(t1, t2, order);
Statement statement2 = Implication.make(t2, t1, reverseOrder(order));
Statement statement3 = Equivalence.make(t1, t2, order);
Term statement4 = null;
switch(order) {
case TemporalRules.ORDER_FORWARD:
statement4 = Conjunction.make(t1, interval, s2.term, order);
break;
case TemporalRules.ORDER_BACKWARD:
statement4 = Conjunction.make(s2.term, interval, t1, reverseOrder(order));
break;
default:
statement4 = Conjunction.make(t1, s2.term, order);
break;
}
// "Perception Variable Introduction Rule" - https://groups.google.com/forum/#!topic/open-nars/uoJBa8j7ryE
if (!deriveSequenceOnly && statement2 != null) {
// there is no general form
// ok then it may be the (&/ =/> case which
// is discussed here: https://groups.google.com/forum/#!topic/open-nars/uoJBa8j7ryE
Statement st = statement2;
if (st.getPredicate() instanceof Inheritance && (st.getSubject() instanceof Conjunction || st.getSubject() instanceof Operation)) {
Term precon = (Term) st.getSubject();
Inheritance consequence = (Inheritance) st.getPredicate();
Term pred = consequence.getPredicate();
Term sub = consequence.getSubject();
// look if subject is contained in precon:
boolean SubsSub = precon.containsTermRecursively(sub);
boolean SubsPred = precon.containsTermRecursively(pred);
Variable v1 = new Variable("$91");
Variable v2 = new Variable("$92");
HashMap<Term, Term> app = new HashMap<Term, Term>();
if (SubsSub || SubsPred) {
if (SubsSub)
app.put(sub, v1);
if (SubsPred)
app.put(pred, v2);
Term res = ((CompoundTerm) statement2).applySubstitute(app);
if (res != null) {
// ok we applied it, all we have to do now is to use it
t22 = ((Statement) res).getSubject();
t11 = ((Statement) res).getPredicate();
}
}
}
}
List<Task> success = new ArrayList<Task>();
if (!deriveSequenceOnly && t11 != null && t22 != null) {
Statement statement11 = Implication.make(t11, t22, order);
Statement statement22 = Implication.make(t22, t11, reverseOrder(order));
Statement statement33 = Equivalence.make(t11, t22, order);
if (!tooMuchTemporalStatements(statement11)) {
List<Task> t = nal.doublePremiseTask(statement11, truth1, budget1, true, false);
if (t != null) {
success.addAll(t);
}
}
if (!tooMuchTemporalStatements(statement22)) {
List<Task> t = nal.doublePremiseTask(statement22, truth2, budget2, true, false);
if (t != null) {
success.addAll(t);
}
}
if (!tooMuchTemporalStatements(statement33)) {
List<Task> t = nal.doublePremiseTask(statement33, truth3, budget3, true, false);
if (t != null) {
success.addAll(t);
}
}
}
if (!deriveSequenceOnly && !tooMuchTemporalStatements(statement1)) {
List<Task> t = nal.doublePremiseTask(statement1, truth1, budget1, true, false);
if (t != null) {
success.addAll(t);
for (Task task : t) {
// we assume here that this function is used for observable events currently
task.setObservablePrediction(true);
}
}
}
if (!deriveSequenceOnly && !tooMuchTemporalStatements(statement2)) {
List<Task> t = nal.doublePremiseTask(statement2, truth2, budget2, true, false);
if (t != null) {
success.addAll(t);
for (Task task : t) {
// we assume here that this function is used for observable events currently
task.setObservablePrediction(true);
}
}
}
if (!deriveSequenceOnly && !tooMuchTemporalStatements(statement3)) {
List<Task> t = nal.doublePremiseTask(statement3, truth3, budget3, true, false);
if (t != null) {
for (Task task : t) {
// we assume here that this function is used for observable events currently
task.setObservablePrediction(true);
}
success.addAll(t);
}
}
if (!tooMuchTemporalStatements(statement4)) {
if (!allowSequence) {
return success;
}
List<Task> tl = nal.doublePremiseTask(statement4, truth4, budget4, true, false, addToMemory);
if (tl != null) {
for (Task t : tl) {
// fill sequenceTask buffer due to the new derived sequence
if (addToMemory && t.sentence.isJudgment() && !t.sentence.isEternal() && t.sentence.term instanceof Conjunction && ((Conjunction) t.sentence.term).getTemporalOrder() != TemporalRules.ORDER_NONE && ((Conjunction) t.sentence.term).getTemporalOrder() != TemporalRules.ORDER_INVALID) {
TemporalInferenceControl.addToSequenceTasks(nal, t);
}
success.add(t);
}
}
}
return success;
}
Also used :
BudgetValue(nars.entity.BudgetValue)
CompoundTerm(nars.language.CompoundTerm)
Task(nars.entity.Task)
Variable(nars.language.Variable)
HashMap(java.util.HashMap)
Statement(nars.language.Statement)
Inheritance(nars.language.Inheritance)
ArrayList(java.util.ArrayList)
Product(nars.language.Product)
CompoundTerm(nars.language.CompoundTerm)
Term(nars.language.Term)
Operation(nars.operator.Operation)
TruthValue(nars.entity.TruthValue)
Conjunction(nars.language.Conjunction)
Sentence(nars.entity.Sentence)
Interval(nars.language.Interval)
Example 55 with Term
use of nars.language.Term in project opennars by opennars.
the class Concept method linkToTask.
/**
* Link to a new task from all relevant concepts for continued processing in
* the near future for unspecified time.
* <p>
* The only method that calls the TaskLink constructor.
*
* @param task The task to be linked
* @param content The content of the task
*/
public void linkToTask(final Task task, DerivationContext cont) {
final BudgetValue taskBudget = task.budget;
insertTaskLink(new TaskLink(task, null, taskBudget, Parameters.TERM_LINK_RECORD_LENGTH), // link type: SELF
cont);
if (!(term instanceof CompoundTerm)) {
return;
}
if (termLinkTemplates.isEmpty()) {
return;
}
final BudgetValue subBudget = distributeAmongLinks(taskBudget, termLinkTemplates.size());
if (subBudget.aboveThreshold()) {
for (int t = 0; t < termLinkTemplates.size(); t++) {
TermLink termLink = termLinkTemplates.get(t);
if (termLink.type == TermLink.TEMPORAL)
continue;
Term componentTerm = termLink.target;
Concept componentConcept = memory.conceptualize(subBudget, componentTerm);
if (componentConcept != null) {
componentConcept.insertTaskLink(new TaskLink(task, termLink, subBudget, Parameters.TERM_LINK_RECORD_LENGTH), cont);
}
}
// recursively insert TermLink
buildTermLinks(taskBudget);
}
}
Also used :
CompoundTerm(nars.language.CompoundTerm)
CompoundTerm(nars.language.CompoundTerm)
Term(nars.language.Term)
Aggregations
Term (nars.language.Term)109
CompoundTerm (nars.language.CompoundTerm)66
BudgetValue (nars.entity.BudgetValue)48
TruthValue (nars.entity.TruthValue)46
Sentence (nars.entity.Sentence)40
Task (nars.entity.Task)37
Statement (nars.language.Statement)28
Conjunction (nars.language.Conjunction)20
Inheritance (nars.language.Inheritance)19
Stamp (nars.entity.Stamp)17
Concept (nars.entity.Concept)14
Implication (nars.language.Implication)13
Product (nars.language.Product)11
NAR (nars.main.NAR)9
Interval (nars.language.Interval)8
Test (org.junit.Test)8
HashMap (java.util.HashMap)7
SetExt (nars.language.SetExt)7
SetInt (nars.language.SetInt)7
Variable (nars.language.Variable)7
