/**
* Generated from platform:/resource/ca.mcgill.ecse.dslreasoner.standalone.test/queries/ca/mcgill/ecse/dslreasoner/standalone/test/yakindu/queries/yakinduPatterns.vql
*/
package ca.mcgill.ecse.dslreasoner.standalone.test.yakindu.queries;
import ca.mcgill.ecse.dslreasoner.standalone.test.yakindu.Synchronization;
import ca.mcgill.ecse.dslreasoner.standalone.test.yakindu.Vertex;
import ca.mcgill.ecse.dslreasoner.standalone.test.yakindu.queries.Transition;
import java.util.Arrays;
import java.util.Collection;
import java.util.LinkedHashSet;
import java.util.List;
import java.util.Objects;
import java.util.Optional;
import java.util.Set;
import java.util.function.Consumer;
import java.util.stream.Collectors;
import java.util.stream.Stream;
import org.apache.log4j.Logger;
import org.eclipse.emf.ecore.EClass;
import org.eclipse.viatra.query.runtime.api.IPatternMatch;
import org.eclipse.viatra.query.runtime.api.IQuerySpecification;
import org.eclipse.viatra.query.runtime.api.ViatraQueryEngine;
import org.eclipse.viatra.query.runtime.api.impl.BaseGeneratedEMFPQuery;
import org.eclipse.viatra.query.runtime.api.impl.BaseGeneratedEMFQuerySpecification;
import org.eclipse.viatra.query.runtime.api.impl.BaseMatcher;
import org.eclipse.viatra.query.runtime.api.impl.BasePatternMatch;
import org.eclipse.viatra.query.runtime.emf.types.EClassTransitiveInstancesKey;
import org.eclipse.viatra.query.runtime.emf.types.EStructuralFeatureInstancesKey;
import org.eclipse.viatra.query.runtime.matchers.backend.QueryEvaluationHint;
import org.eclipse.viatra.query.runtime.matchers.psystem.PBody;
import org.eclipse.viatra.query.runtime.matchers.psystem.PVariable;
import org.eclipse.viatra.query.runtime.matchers.psystem.annotations.PAnnotation;
import org.eclipse.viatra.query.runtime.matchers.psystem.annotations.ParameterReference;
import org.eclipse.viatra.query.runtime.matchers.psystem.basicdeferred.Equality;
import org.eclipse.viatra.query.runtime.matchers.psystem.basicdeferred.ExportedParameter;
import org.eclipse.viatra.query.runtime.matchers.psystem.basicdeferred.Inequality;
import org.eclipse.viatra.query.runtime.matchers.psystem.basicenumerables.PositivePatternCall;
import org.eclipse.viatra.query.runtime.matchers.psystem.basicenumerables.TypeConstraint;
import org.eclipse.viatra.query.runtime.matchers.psystem.queries.PParameter;
import org.eclipse.viatra.query.runtime.matchers.psystem.queries.PParameterDirection;
import org.eclipse.viatra.query.runtime.matchers.psystem.queries.PVisibility;
import org.eclipse.viatra.query.runtime.matchers.tuple.Tuple;
import org.eclipse.viatra.query.runtime.matchers.tuple.Tuples;
import org.eclipse.viatra.query.runtime.util.ViatraQueryLoggingUtil;
/**
* A pattern-specific query specification that can instantiate Matcher in a type-safe way.
*
*
Original source:
*
* {@literal @}Constraint(severity="error", message="error", key = {s})
* pattern SynchronizedIncomingInSameRegion(s : Synchronization, v1 : Vertex, v2 : Vertex) {
* find transition(t1, v1, s);
* find transition(t2, v2, s);
* t1!=t2;
* Region.vertices(r, v1);
* Region.vertices(r, v2);
* } or {
* find transition(t1, s, v1);
* find transition(t2, s, v2);
* t1!=t2;
* Region.vertices(r, v1);
* Region.vertices(r, v2);
* }
*
*
* @see Matcher
* @see Match
*
*/
@SuppressWarnings("all")
public final class SynchronizedIncomingInSameRegion extends BaseGeneratedEMFQuerySpecification {
/**
* Pattern-specific match representation of the ca.mcgill.ecse.dslreasoner.standalone.test.yakindu.queries.SynchronizedIncomingInSameRegion pattern,
* to be used in conjunction with {@link Matcher}.
*
* Class fields correspond to parameters of the pattern. Fields with value null are considered unassigned.
* Each instance is a (possibly partial) substitution of pattern parameters,
* usable to represent a match of the pattern in the result of a query,
* or to specify the bound (fixed) input parameters when issuing a query.
*
* @see Matcher
*
*/
public static abstract class Match extends BasePatternMatch {
private Synchronization fS;
private Vertex fV1;
private Vertex fV2;
private static List parameterNames = makeImmutableList("s", "v1", "v2");
private Match(final Synchronization pS, final Vertex pV1, final Vertex pV2) {
this.fS = pS;
this.fV1 = pV1;
this.fV2 = pV2;
}
@Override
public Object get(final String parameterName) {
if ("s".equals(parameterName)) return this.fS;
if ("v1".equals(parameterName)) return this.fV1;
if ("v2".equals(parameterName)) return this.fV2;
return null;
}
public Synchronization getS() {
return this.fS;
}
public Vertex getV1() {
return this.fV1;
}
public Vertex getV2() {
return this.fV2;
}
@Override
public boolean set(final String parameterName, final Object newValue) {
if (!isMutable()) throw new java.lang.UnsupportedOperationException();
if ("s".equals(parameterName) ) {
this.fS = (Synchronization) newValue;
return true;
}
if ("v1".equals(parameterName) ) {
this.fV1 = (Vertex) newValue;
return true;
}
if ("v2".equals(parameterName) ) {
this.fV2 = (Vertex) newValue;
return true;
}
return false;
}
public void setS(final Synchronization pS) {
if (!isMutable()) throw new java.lang.UnsupportedOperationException();
this.fS = pS;
}
public void setV1(final Vertex pV1) {
if (!isMutable()) throw new java.lang.UnsupportedOperationException();
this.fV1 = pV1;
}
public void setV2(final Vertex pV2) {
if (!isMutable()) throw new java.lang.UnsupportedOperationException();
this.fV2 = pV2;
}
@Override
public String patternName() {
return "ca.mcgill.ecse.dslreasoner.standalone.test.yakindu.queries.SynchronizedIncomingInSameRegion";
}
@Override
public List parameterNames() {
return SynchronizedIncomingInSameRegion.Match.parameterNames;
}
@Override
public Object[] toArray() {
return new Object[]{fS, fV1, fV2};
}
@Override
public SynchronizedIncomingInSameRegion.Match toImmutable() {
return isMutable() ? newMatch(fS, fV1, fV2) : this;
}
@Override
public String prettyPrint() {
StringBuilder result = new StringBuilder();
result.append("\"s\"=" + prettyPrintValue(fS) + ", ");
result.append("\"v1\"=" + prettyPrintValue(fV1) + ", ");
result.append("\"v2\"=" + prettyPrintValue(fV2));
return result.toString();
}
@Override
public int hashCode() {
return Objects.hash(fS, fV1, fV2);
}
@Override
public boolean equals(final Object obj) {
if (this == obj)
return true;
if (obj == null) {
return false;
}
if ((obj instanceof SynchronizedIncomingInSameRegion.Match)) {
SynchronizedIncomingInSameRegion.Match other = (SynchronizedIncomingInSameRegion.Match) obj;
return Objects.equals(fS, other.fS) && Objects.equals(fV1, other.fV1) && Objects.equals(fV2, other.fV2);
} else {
// this should be infrequent
if (!(obj instanceof IPatternMatch)) {
return false;
}
IPatternMatch otherSig = (IPatternMatch) obj;
return Objects.equals(specification(), otherSig.specification()) && Arrays.deepEquals(toArray(), otherSig.toArray());
}
}
@Override
public SynchronizedIncomingInSameRegion specification() {
return SynchronizedIncomingInSameRegion.instance();
}
/**
* Returns an empty, mutable match.
* Fields of the mutable match can be filled to create a partial match, usable as matcher input.
*
* @return the empty match.
*
*/
public static SynchronizedIncomingInSameRegion.Match newEmptyMatch() {
return new Mutable(null, null, null);
}
/**
* Returns a mutable (partial) match.
* Fields of the mutable match can be filled to create a partial match, usable as matcher input.
*
* @param pS the fixed value of pattern parameter s, or null if not bound.
* @param pV1 the fixed value of pattern parameter v1, or null if not bound.
* @param pV2 the fixed value of pattern parameter v2, or null if not bound.
* @return the new, mutable (partial) match object.
*
*/
public static SynchronizedIncomingInSameRegion.Match newMutableMatch(final Synchronization pS, final Vertex pV1, final Vertex pV2) {
return new Mutable(pS, pV1, pV2);
}
/**
* Returns a new (partial) match.
* This can be used e.g. to call the matcher with a partial match.
* The returned match will be immutable. Use {@link #newEmptyMatch()} to obtain a mutable match object.
* @param pS the fixed value of pattern parameter s, or null if not bound.
* @param pV1 the fixed value of pattern parameter v1, or null if not bound.
* @param pV2 the fixed value of pattern parameter v2, or null if not bound.
* @return the (partial) match object.
*
*/
public static SynchronizedIncomingInSameRegion.Match newMatch(final Synchronization pS, final Vertex pV1, final Vertex pV2) {
return new Immutable(pS, pV1, pV2);
}
private static final class Mutable extends SynchronizedIncomingInSameRegion.Match {
Mutable(final Synchronization pS, final Vertex pV1, final Vertex pV2) {
super(pS, pV1, pV2);
}
@Override
public boolean isMutable() {
return true;
}
}
private static final class Immutable extends SynchronizedIncomingInSameRegion.Match {
Immutable(final Synchronization pS, final Vertex pV1, final Vertex pV2) {
super(pS, pV1, pV2);
}
@Override
public boolean isMutable() {
return false;
}
}
}
/**
* Generated pattern matcher API of the ca.mcgill.ecse.dslreasoner.standalone.test.yakindu.queries.SynchronizedIncomingInSameRegion pattern,
* providing pattern-specific query methods.
*
*
Use the pattern matcher on a given model via {@link #on(ViatraQueryEngine)},
* e.g. in conjunction with {@link ViatraQueryEngine#on(QueryScope)}.
*
*
Matches of the pattern will be represented as {@link Match}.
*
*
Original source:
*
* {@literal @}Constraint(severity="error", message="error", key = {s})
* pattern SynchronizedIncomingInSameRegion(s : Synchronization, v1 : Vertex, v2 : Vertex) {
* find transition(t1, v1, s);
* find transition(t2, v2, s);
* t1!=t2;
* Region.vertices(r, v1);
* Region.vertices(r, v2);
* } or {
* find transition(t1, s, v1);
* find transition(t2, s, v2);
* t1!=t2;
* Region.vertices(r, v1);
* Region.vertices(r, v2);
* }
*
*
* @see Match
* @see SynchronizedIncomingInSameRegion
*
*/
public static class Matcher extends BaseMatcher {
/**
* Initializes the pattern matcher within an existing VIATRA Query engine.
* If the pattern matcher is already constructed in the engine, only a light-weight reference is returned.
*
* @param engine the existing VIATRA Query engine in which this matcher will be created.
* @throws ViatraQueryRuntimeException if an error occurs during pattern matcher creation
*
*/
public static SynchronizedIncomingInSameRegion.Matcher on(final ViatraQueryEngine engine) {
// check if matcher already exists
Matcher matcher = engine.getExistingMatcher(querySpecification());
if (matcher == null) {
matcher = (Matcher)engine.getMatcher(querySpecification());
}
return matcher;
}
/**
* @throws ViatraQueryRuntimeException if an error occurs during pattern matcher creation
* @return an initialized matcher
* @noreference This method is for internal matcher initialization by the framework, do not call it manually.
*
*/
public static SynchronizedIncomingInSameRegion.Matcher create() {
return new Matcher();
}
private final static int POSITION_S = 0;
private final static int POSITION_V1 = 1;
private final static int POSITION_V2 = 2;
private final static Logger LOGGER = ViatraQueryLoggingUtil.getLogger(SynchronizedIncomingInSameRegion.Matcher.class);
/**
* Initializes the pattern matcher within an existing VIATRA Query engine.
* If the pattern matcher is already constructed in the engine, only a light-weight reference is returned.
*
* @param engine the existing VIATRA Query engine in which this matcher will be created.
* @throws ViatraQueryRuntimeException if an error occurs during pattern matcher creation
*
*/
private Matcher() {
super(querySpecification());
}
/**
* Returns the set of all matches of the pattern that conform to the given fixed values of some parameters.
* @param pS the fixed value of pattern parameter s, or null if not bound.
* @param pV1 the fixed value of pattern parameter v1, or null if not bound.
* @param pV2 the fixed value of pattern parameter v2, or null if not bound.
* @return matches represented as a Match object.
*
*/
public Collection getAllMatches(final Synchronization pS, final Vertex pV1, final Vertex pV2) {
return rawStreamAllMatches(new Object[]{pS, pV1, pV2}).collect(Collectors.toSet());
}
/**
* Returns a stream of all matches of the pattern that conform to the given fixed values of some parameters.
*
* NOTE: It is important not to modify the source model while the stream is being processed.
* If the match set of the pattern changes during processing, the contents of the stream is undefined.
* In such cases, either rely on {@link #getAllMatches()} or collect the results of the stream in end-user code.
* @param pS the fixed value of pattern parameter s, or null if not bound.
* @param pV1 the fixed value of pattern parameter v1, or null if not bound.
* @param pV2 the fixed value of pattern parameter v2, or null if not bound.
* @return a stream of matches represented as a Match object.
*
*/
public Stream streamAllMatches(final Synchronization pS, final Vertex pV1, final Vertex pV2) {
return rawStreamAllMatches(new Object[]{pS, pV1, pV2});
}
/**
* Returns an arbitrarily chosen match of the pattern that conforms to the given fixed values of some parameters.
* Neither determinism nor randomness of selection is guaranteed.
* @param pS the fixed value of pattern parameter s, or null if not bound.
* @param pV1 the fixed value of pattern parameter v1, or null if not bound.
* @param pV2 the fixed value of pattern parameter v2, or null if not bound.
* @return a match represented as a Match object, or null if no match is found.
*
*/
public Optional getOneArbitraryMatch(final Synchronization pS, final Vertex pV1, final Vertex pV2) {
return rawGetOneArbitraryMatch(new Object[]{pS, pV1, pV2});
}
/**
* Indicates whether the given combination of specified pattern parameters constitute a valid pattern match,
* under any possible substitution of the unspecified parameters (if any).
* @param pS the fixed value of pattern parameter s, or null if not bound.
* @param pV1 the fixed value of pattern parameter v1, or null if not bound.
* @param pV2 the fixed value of pattern parameter v2, or null if not bound.
* @return true if the input is a valid (partial) match of the pattern.
*
*/
public boolean hasMatch(final Synchronization pS, final Vertex pV1, final Vertex pV2) {
return rawHasMatch(new Object[]{pS, pV1, pV2});
}
/**
* Returns the number of all matches of the pattern that conform to the given fixed values of some parameters.
* @param pS the fixed value of pattern parameter s, or null if not bound.
* @param pV1 the fixed value of pattern parameter v1, or null if not bound.
* @param pV2 the fixed value of pattern parameter v2, or null if not bound.
* @return the number of pattern matches found.
*
*/
public int countMatches(final Synchronization pS, final Vertex pV1, final Vertex pV2) {
return rawCountMatches(new Object[]{pS, pV1, pV2});
}
/**
* Executes the given processor on an arbitrarily chosen match of the pattern that conforms to the given fixed values of some parameters.
* Neither determinism nor randomness of selection is guaranteed.
* @param pS the fixed value of pattern parameter s, or null if not bound.
* @param pV1 the fixed value of pattern parameter v1, or null if not bound.
* @param pV2 the fixed value of pattern parameter v2, or null if not bound.
* @param processor the action that will process the selected match.
* @return true if the pattern has at least one match with the given parameter values, false if the processor was not invoked
*
*/
public boolean forOneArbitraryMatch(final Synchronization pS, final Vertex pV1, final Vertex pV2, final Consumer super SynchronizedIncomingInSameRegion.Match> processor) {
return rawForOneArbitraryMatch(new Object[]{pS, pV1, pV2}, processor);
}
/**
* Returns a new (partial) match.
* This can be used e.g. to call the matcher with a partial match.
* The returned match will be immutable. Use {@link #newEmptyMatch()} to obtain a mutable match object.
* @param pS the fixed value of pattern parameter s, or null if not bound.
* @param pV1 the fixed value of pattern parameter v1, or null if not bound.
* @param pV2 the fixed value of pattern parameter v2, or null if not bound.
* @return the (partial) match object.
*
*/
public SynchronizedIncomingInSameRegion.Match newMatch(final Synchronization pS, final Vertex pV1, final Vertex pV2) {
return SynchronizedIncomingInSameRegion.Match.newMatch(pS, pV1, pV2);
}
/**
* Retrieve the set of values that occur in matches for s.
* @return the Set of all values or empty set if there are no matches
*
*/
protected Stream rawStreamAllValuesOfs(final Object[] parameters) {
return rawStreamAllValues(POSITION_S, parameters).map(Synchronization.class::cast);
}
/**
* Retrieve the set of values that occur in matches for s.
* @return the Set of all values or empty set if there are no matches
*
*/
public Set getAllValuesOfs() {
return rawStreamAllValuesOfs(emptyArray()).collect(Collectors.toSet());
}
/**
* Retrieve the set of values that occur in matches for s.
* @return the Set of all values or empty set if there are no matches
*
*/
public Stream streamAllValuesOfs() {
return rawStreamAllValuesOfs(emptyArray());
}
/**
* Retrieve the set of values that occur in matches for s.
*
* NOTE: It is important not to modify the source model while the stream is being processed.
* If the match set of the pattern changes during processing, the contents of the stream is undefined.
* In such cases, either rely on {@link #getAllMatches()} or collect the results of the stream in end-user code.
*
* @return the Stream of all values or empty set if there are no matches
*
*/
public Stream streamAllValuesOfs(final SynchronizedIncomingInSameRegion.Match partialMatch) {
return rawStreamAllValuesOfs(partialMatch.toArray());
}
/**
* Retrieve the set of values that occur in matches for s.
*
* NOTE: It is important not to modify the source model while the stream is being processed.
* If the match set of the pattern changes during processing, the contents of the stream is undefined.
* In such cases, either rely on {@link #getAllMatches()} or collect the results of the stream in end-user code.
*
* @return the Stream of all values or empty set if there are no matches
*
*/
public Stream streamAllValuesOfs(final Vertex pV1, final Vertex pV2) {
return rawStreamAllValuesOfs(new Object[]{null, pV1, pV2});
}
/**
* Retrieve the set of values that occur in matches for s.
* @return the Set of all values or empty set if there are no matches
*
*/
public Set getAllValuesOfs(final SynchronizedIncomingInSameRegion.Match partialMatch) {
return rawStreamAllValuesOfs(partialMatch.toArray()).collect(Collectors.toSet());
}
/**
* Retrieve the set of values that occur in matches for s.
* @return the Set of all values or empty set if there are no matches
*
*/
public Set getAllValuesOfs(final Vertex pV1, final Vertex pV2) {
return rawStreamAllValuesOfs(new Object[]{null, pV1, pV2}).collect(Collectors.toSet());
}
/**
* Retrieve the set of values that occur in matches for v1.
* @return the Set of all values or empty set if there are no matches
*
*/
protected Stream rawStreamAllValuesOfv1(final Object[] parameters) {
return rawStreamAllValues(POSITION_V1, parameters).map(Vertex.class::cast);
}
/**
* Retrieve the set of values that occur in matches for v1.
* @return the Set of all values or empty set if there are no matches
*
*/
public Set getAllValuesOfv1() {
return rawStreamAllValuesOfv1(emptyArray()).collect(Collectors.toSet());
}
/**
* Retrieve the set of values that occur in matches for v1.
* @return the Set of all values or empty set if there are no matches
*
*/
public Stream streamAllValuesOfv1() {
return rawStreamAllValuesOfv1(emptyArray());
}
/**
* Retrieve the set of values that occur in matches for v1.
*
* NOTE: It is important not to modify the source model while the stream is being processed.
* If the match set of the pattern changes during processing, the contents of the stream is undefined.
* In such cases, either rely on {@link #getAllMatches()} or collect the results of the stream in end-user code.
*
* @return the Stream of all values or empty set if there are no matches
*
*/
public Stream streamAllValuesOfv1(final SynchronizedIncomingInSameRegion.Match partialMatch) {
return rawStreamAllValuesOfv1(partialMatch.toArray());
}
/**
* Retrieve the set of values that occur in matches for v1.
*
* NOTE: It is important not to modify the source model while the stream is being processed.
* If the match set of the pattern changes during processing, the contents of the stream is undefined.
* In such cases, either rely on {@link #getAllMatches()} or collect the results of the stream in end-user code.
*
* @return the Stream of all values or empty set if there are no matches
*
*/
public Stream streamAllValuesOfv1(final Synchronization pS, final Vertex pV2) {
return rawStreamAllValuesOfv1(new Object[]{pS, null, pV2});
}
/**
* Retrieve the set of values that occur in matches for v1.
* @return the Set of all values or empty set if there are no matches
*
*/
public Set getAllValuesOfv1(final SynchronizedIncomingInSameRegion.Match partialMatch) {
return rawStreamAllValuesOfv1(partialMatch.toArray()).collect(Collectors.toSet());
}
/**
* Retrieve the set of values that occur in matches for v1.
* @return the Set of all values or empty set if there are no matches
*
*/
public Set getAllValuesOfv1(final Synchronization pS, final Vertex pV2) {
return rawStreamAllValuesOfv1(new Object[]{pS, null, pV2}).collect(Collectors.toSet());
}
/**
* Retrieve the set of values that occur in matches for v2.
* @return the Set of all values or empty set if there are no matches
*
*/
protected Stream rawStreamAllValuesOfv2(final Object[] parameters) {
return rawStreamAllValues(POSITION_V2, parameters).map(Vertex.class::cast);
}
/**
* Retrieve the set of values that occur in matches for v2.
* @return the Set of all values or empty set if there are no matches
*
*/
public Set getAllValuesOfv2() {
return rawStreamAllValuesOfv2(emptyArray()).collect(Collectors.toSet());
}
/**
* Retrieve the set of values that occur in matches for v2.
* @return the Set of all values or empty set if there are no matches
*
*/
public Stream streamAllValuesOfv2() {
return rawStreamAllValuesOfv2(emptyArray());
}
/**
* Retrieve the set of values that occur in matches for v2.
*
* NOTE: It is important not to modify the source model while the stream is being processed.
* If the match set of the pattern changes during processing, the contents of the stream is undefined.
* In such cases, either rely on {@link #getAllMatches()} or collect the results of the stream in end-user code.
*
* @return the Stream of all values or empty set if there are no matches
*
*/
public Stream streamAllValuesOfv2(final SynchronizedIncomingInSameRegion.Match partialMatch) {
return rawStreamAllValuesOfv2(partialMatch.toArray());
}
/**
* Retrieve the set of values that occur in matches for v2.
*
* NOTE: It is important not to modify the source model while the stream is being processed.
* If the match set of the pattern changes during processing, the contents of the stream is undefined.
* In such cases, either rely on {@link #getAllMatches()} or collect the results of the stream in end-user code.
*
* @return the Stream of all values or empty set if there are no matches
*
*/
public Stream streamAllValuesOfv2(final Synchronization pS, final Vertex pV1) {
return rawStreamAllValuesOfv2(new Object[]{pS, pV1, null});
}
/**
* Retrieve the set of values that occur in matches for v2.
* @return the Set of all values or empty set if there are no matches
*
*/
public Set getAllValuesOfv2(final SynchronizedIncomingInSameRegion.Match partialMatch) {
return rawStreamAllValuesOfv2(partialMatch.toArray()).collect(Collectors.toSet());
}
/**
* Retrieve the set of values that occur in matches for v2.
* @return the Set of all values or empty set if there are no matches
*
*/
public Set getAllValuesOfv2(final Synchronization pS, final Vertex pV1) {
return rawStreamAllValuesOfv2(new Object[]{pS, pV1, null}).collect(Collectors.toSet());
}
@Override
protected SynchronizedIncomingInSameRegion.Match tupleToMatch(final Tuple t) {
try {
return SynchronizedIncomingInSameRegion.Match.newMatch((Synchronization) t.get(POSITION_S), (Vertex) t.get(POSITION_V1), (Vertex) t.get(POSITION_V2));
} catch(ClassCastException e) {
LOGGER.error("Element(s) in tuple not properly typed!",e);
return null;
}
}
@Override
protected SynchronizedIncomingInSameRegion.Match arrayToMatch(final Object[] match) {
try {
return SynchronizedIncomingInSameRegion.Match.newMatch((Synchronization) match[POSITION_S], (Vertex) match[POSITION_V1], (Vertex) match[POSITION_V2]);
} catch(ClassCastException e) {
LOGGER.error("Element(s) in array not properly typed!",e);
return null;
}
}
@Override
protected SynchronizedIncomingInSameRegion.Match arrayToMatchMutable(final Object[] match) {
try {
return SynchronizedIncomingInSameRegion.Match.newMutableMatch((Synchronization) match[POSITION_S], (Vertex) match[POSITION_V1], (Vertex) match[POSITION_V2]);
} catch(ClassCastException e) {
LOGGER.error("Element(s) in array not properly typed!",e);
return null;
}
}
/**
* @return the singleton instance of the query specification of this pattern
* @throws ViatraQueryRuntimeException if the pattern definition could not be loaded
*
*/
public static IQuerySpecification querySpecification() {
return SynchronizedIncomingInSameRegion.instance();
}
}
private SynchronizedIncomingInSameRegion() {
super(GeneratedPQuery.INSTANCE);
}
/**
* @return the singleton instance of the query specification
* @throws ViatraQueryRuntimeException if the pattern definition could not be loaded
*
*/
public static SynchronizedIncomingInSameRegion instance() {
try{
return LazyHolder.INSTANCE;
} catch (ExceptionInInitializerError err) {
throw processInitializerError(err);
}
}
@Override
protected SynchronizedIncomingInSameRegion.Matcher instantiate(final ViatraQueryEngine engine) {
return SynchronizedIncomingInSameRegion.Matcher.on(engine);
}
@Override
public SynchronizedIncomingInSameRegion.Matcher instantiate() {
return SynchronizedIncomingInSameRegion.Matcher.create();
}
@Override
public SynchronizedIncomingInSameRegion.Match newEmptyMatch() {
return SynchronizedIncomingInSameRegion.Match.newEmptyMatch();
}
@Override
public SynchronizedIncomingInSameRegion.Match newMatch(final Object... parameters) {
return SynchronizedIncomingInSameRegion.Match.newMatch((ca.mcgill.ecse.dslreasoner.standalone.test.yakindu.Synchronization) parameters[0], (ca.mcgill.ecse.dslreasoner.standalone.test.yakindu.Vertex) parameters[1], (ca.mcgill.ecse.dslreasoner.standalone.test.yakindu.Vertex) parameters[2]);
}
/**
* Inner class allowing the singleton instance of {@link JvmGenericType: ca.mcgill.ecse.dslreasoner.standalone.test.yakindu.queries.SynchronizedIncomingInSameRegion (visibility: PUBLIC, simpleName: SynchronizedIncomingInSameRegion, identifier: ca.mcgill.ecse.dslreasoner.standalone.test.yakindu.queries.SynchronizedIncomingInSameRegion, deprecated: ) (abstract: false, static: false, final: true, packageName: ca.mcgill.ecse.dslreasoner.standalone.test.yakindu.queries) (interface: false, strictFloatingPoint: false, anonymous: false)} to be created
* not at the class load time of the outer class,
* but rather at the first call to {@link JvmGenericType: ca.mcgill.ecse.dslreasoner.standalone.test.yakindu.queries.SynchronizedIncomingInSameRegion (visibility: PUBLIC, simpleName: SynchronizedIncomingInSameRegion, identifier: ca.mcgill.ecse.dslreasoner.standalone.test.yakindu.queries.SynchronizedIncomingInSameRegion, deprecated: ) (abstract: false, static: false, final: true, packageName: ca.mcgill.ecse.dslreasoner.standalone.test.yakindu.queries) (interface: false, strictFloatingPoint: false, anonymous: false)#instance()}.
*
* This workaround is required e.g. to support recursion.
*
*/
private static class LazyHolder {
private final static SynchronizedIncomingInSameRegion INSTANCE = new SynchronizedIncomingInSameRegion();
/**
* Statically initializes the query specification after the field {@link #INSTANCE} is assigned.
* This initialization order is required to support indirect recursion.
*
*
The static initializer is defined using a helper field to work around limitations of the code generator.
*
*/
private final static Object STATIC_INITIALIZER = ensureInitialized();
public static Object ensureInitialized() {
INSTANCE.ensureInitializedInternal();
return null;
}
}
private static class GeneratedPQuery extends BaseGeneratedEMFPQuery {
private final static SynchronizedIncomingInSameRegion.GeneratedPQuery INSTANCE = new GeneratedPQuery();
private final PParameter parameter_s = new PParameter("s", "ca.mcgill.ecse.dslreasoner.standalone.test.yakindu.Synchronization", new EClassTransitiveInstancesKey((EClass)getClassifierLiteralSafe("YakinduMetamodel", "Synchronization")), PParameterDirection.INOUT);
private final PParameter parameter_v1 = new PParameter("v1", "ca.mcgill.ecse.dslreasoner.standalone.test.yakindu.Vertex", new EClassTransitiveInstancesKey((EClass)getClassifierLiteralSafe("YakinduMetamodel", "Vertex")), PParameterDirection.INOUT);
private final PParameter parameter_v2 = new PParameter("v2", "ca.mcgill.ecse.dslreasoner.standalone.test.yakindu.Vertex", new EClassTransitiveInstancesKey((EClass)getClassifierLiteralSafe("YakinduMetamodel", "Vertex")), PParameterDirection.INOUT);
private final List parameters = Arrays.asList(parameter_s, parameter_v1, parameter_v2);
private GeneratedPQuery() {
super(PVisibility.PUBLIC);
}
@Override
public String getFullyQualifiedName() {
return "ca.mcgill.ecse.dslreasoner.standalone.test.yakindu.queries.SynchronizedIncomingInSameRegion";
}
@Override
public List getParameterNames() {
return Arrays.asList("s","v1","v2");
}
@Override
public List getParameters() {
return parameters;
}
@Override
public Set doGetContainedBodies() {
setEvaluationHints(new QueryEvaluationHint(null, QueryEvaluationHint.BackendRequirement.UNSPECIFIED));
Set bodies = new LinkedHashSet<>();
{
PBody body = new PBody(this);
PVariable var_s = body.getOrCreateVariableByName("s");
PVariable var_v1 = body.getOrCreateVariableByName("v1");
PVariable var_v2 = body.getOrCreateVariableByName("v2");
PVariable var_t1 = body.getOrCreateVariableByName("t1");
PVariable var_t2 = body.getOrCreateVariableByName("t2");
PVariable var_r = body.getOrCreateVariableByName("r");
new TypeConstraint(body, Tuples.flatTupleOf(var_s), new EClassTransitiveInstancesKey((EClass)getClassifierLiteral("YakinduMetamodel", "Synchronization")));
new TypeConstraint(body, Tuples.flatTupleOf(var_v1), new EClassTransitiveInstancesKey((EClass)getClassifierLiteral("YakinduMetamodel", "Vertex")));
new TypeConstraint(body, Tuples.flatTupleOf(var_v2), new EClassTransitiveInstancesKey((EClass)getClassifierLiteral("YakinduMetamodel", "Vertex")));
body.setSymbolicParameters(Arrays.asList(
new ExportedParameter(body, var_s, parameter_s),
new ExportedParameter(body, var_v1, parameter_v1),
new ExportedParameter(body, var_v2, parameter_v2)
));
// find transition(t1, v1, s)
new PositivePatternCall(body, Tuples.flatTupleOf(var_t1, var_v1, var_s), Transition.instance().getInternalQueryRepresentation());
// find transition(t2, v2, s)
new PositivePatternCall(body, Tuples.flatTupleOf(var_t2, var_v2, var_s), Transition.instance().getInternalQueryRepresentation());
// t1!=t2
new Inequality(body, var_t1, var_t2);
// Region.vertices(r, v1)
new TypeConstraint(body, Tuples.flatTupleOf(var_r), new EClassTransitiveInstancesKey((EClass)getClassifierLiteral("YakinduMetamodel", "Region")));
PVariable var__virtual_0_ = body.getOrCreateVariableByName(".virtual{0}");
new TypeConstraint(body, Tuples.flatTupleOf(var_r, var__virtual_0_), new EStructuralFeatureInstancesKey(getFeatureLiteral("YakinduMetamodel", "Region", "vertices")));
new TypeConstraint(body, Tuples.flatTupleOf(var__virtual_0_), new EClassTransitiveInstancesKey((EClass)getClassifierLiteral("YakinduMetamodel", "Vertex")));
new Equality(body, var__virtual_0_, var_v1);
// Region.vertices(r, v2)
new TypeConstraint(body, Tuples.flatTupleOf(var_r), new EClassTransitiveInstancesKey((EClass)getClassifierLiteral("YakinduMetamodel", "Region")));
PVariable var__virtual_1_ = body.getOrCreateVariableByName(".virtual{1}");
new TypeConstraint(body, Tuples.flatTupleOf(var_r, var__virtual_1_), new EStructuralFeatureInstancesKey(getFeatureLiteral("YakinduMetamodel", "Region", "vertices")));
new TypeConstraint(body, Tuples.flatTupleOf(var__virtual_1_), new EClassTransitiveInstancesKey((EClass)getClassifierLiteral("YakinduMetamodel", "Vertex")));
new Equality(body, var__virtual_1_, var_v2);
bodies.add(body);
}
{
PBody body = new PBody(this);
PVariable var_s = body.getOrCreateVariableByName("s");
PVariable var_v1 = body.getOrCreateVariableByName("v1");
PVariable var_v2 = body.getOrCreateVariableByName("v2");
PVariable var_t1 = body.getOrCreateVariableByName("t1");
PVariable var_t2 = body.getOrCreateVariableByName("t2");
PVariable var_r = body.getOrCreateVariableByName("r");
new TypeConstraint(body, Tuples.flatTupleOf(var_s), new EClassTransitiveInstancesKey((EClass)getClassifierLiteral("YakinduMetamodel", "Synchronization")));
new TypeConstraint(body, Tuples.flatTupleOf(var_v1), new EClassTransitiveInstancesKey((EClass)getClassifierLiteral("YakinduMetamodel", "Vertex")));
new TypeConstraint(body, Tuples.flatTupleOf(var_v2), new EClassTransitiveInstancesKey((EClass)getClassifierLiteral("YakinduMetamodel", "Vertex")));
body.setSymbolicParameters(Arrays.asList(
new ExportedParameter(body, var_s, parameter_s),
new ExportedParameter(body, var_v1, parameter_v1),
new ExportedParameter(body, var_v2, parameter_v2)
));
// find transition(t1, s, v1)
new PositivePatternCall(body, Tuples.flatTupleOf(var_t1, var_s, var_v1), Transition.instance().getInternalQueryRepresentation());
// find transition(t2, s, v2)
new PositivePatternCall(body, Tuples.flatTupleOf(var_t2, var_s, var_v2), Transition.instance().getInternalQueryRepresentation());
// t1!=t2
new Inequality(body, var_t1, var_t2);
// Region.vertices(r, v1)
new TypeConstraint(body, Tuples.flatTupleOf(var_r), new EClassTransitiveInstancesKey((EClass)getClassifierLiteral("YakinduMetamodel", "Region")));
PVariable var__virtual_0_ = body.getOrCreateVariableByName(".virtual{0}");
new TypeConstraint(body, Tuples.flatTupleOf(var_r, var__virtual_0_), new EStructuralFeatureInstancesKey(getFeatureLiteral("YakinduMetamodel", "Region", "vertices")));
new TypeConstraint(body, Tuples.flatTupleOf(var__virtual_0_), new EClassTransitiveInstancesKey((EClass)getClassifierLiteral("YakinduMetamodel", "Vertex")));
new Equality(body, var__virtual_0_, var_v1);
// Region.vertices(r, v2)
new TypeConstraint(body, Tuples.flatTupleOf(var_r), new EClassTransitiveInstancesKey((EClass)getClassifierLiteral("YakinduMetamodel", "Region")));
PVariable var__virtual_1_ = body.getOrCreateVariableByName(".virtual{1}");
new TypeConstraint(body, Tuples.flatTupleOf(var_r, var__virtual_1_), new EStructuralFeatureInstancesKey(getFeatureLiteral("YakinduMetamodel", "Region", "vertices")));
new TypeConstraint(body, Tuples.flatTupleOf(var__virtual_1_), new EClassTransitiveInstancesKey((EClass)getClassifierLiteral("YakinduMetamodel", "Vertex")));
new Equality(body, var__virtual_1_, var_v2);
bodies.add(body);
}
{
PAnnotation annotation = new PAnnotation("Constraint");
annotation.addAttribute("severity", "error");
annotation.addAttribute("message", "error");
annotation.addAttribute("key", Arrays.asList(new Object[] {
new ParameterReference("s")
}));
addAnnotation(annotation);
}
return bodies;
}
}
}