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APE is a command line tool and an API for the automated exploration of possible computational pipelines (workflows) from large collections of computational tools.

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package nl.uu.cs.ape.models.sltlxStruc;

import java.util.HashSet;
import java.util.Set;

import nl.uu.cs.ape.automaton.State;
import nl.uu.cs.ape.automaton.StateInterface;
import nl.uu.cs.ape.utils.APEUtils;
import nl.uu.cs.ape.models.Pair;
import nl.uu.cs.ape.models.enums.AtomType;
import nl.uu.cs.ape.models.enums.AtomVarType;
import nl.uu.cs.ape.models.logic.constructs.PredicateLabel;
import nl.uu.cs.ape.solver.minisat.SATSynthesisEngine;

/***
 * The {@code State} class is used to represent a variable for type states. The
 * variable only represents states from the type automatons, excluding the
 * module automaton states.
 * 

* Labeling of the automaton is provided in * /APE/res/WorkflowAutomaton_Implementation.png. * * @author Vedran Kasalica */ public class SLTLxVariable implements StateInterface, PredicateLabel { /** Unique name of the type state variable */ private final String variableID; /** * Create new type state variable. * * @param variableName - Unique variable name */ public SLTLxVariable(String variableName) { super(); this.variableID = variableName; } /** * @return the variableID */ public String getVariableName() { return variableID; } @Override public int hashCode() { final int prime = 31; int result = 1; result = prime * result + ((variableID == null) ? 0 : variableID.hashCode()); return result; } @Override public boolean equals(Object obj) { if (this == obj) return true; if (obj == null) return false; if (getClass() != obj.getClass()) return false; SLTLxVariable other = (SLTLxVariable) obj; if (variableID == null) { if (other.variableID != null) return false; } else if (!variableID.equals(other.variableID)) return false; return true; } @Override public String getPredicateID() { return variableID; } public int compareTo(PredicateLabel other) { return this.getPredicateID().compareTo(other.getPredicateID()); } @Override public String getPredicateLabel() { return variableID; } @Override public String getPredicateLongLabel() { return variableID; } /** * Get the set of clauses that enforce substitution of the variable under the * existential * quantification for the given set of memory states. * * @param stateNo - current state in the SLTLx model * @param synthesisEngine - synthesis engine * @return Set of clauses that encode the possible variable substitution. */ public Set getExistentialCNFEncoding(int stateNo, SLTLxVariableSubstitutionCollection variableSubstitutions, SATSynthesisEngine synthesisEngine) { Set varRefs = new HashSet<>(); for (State state : variableSubstitutions.getVariableDomain(this)) { SLTLxAtomVar currAtomVar = new SLTLxAtomVar(AtomVarType.VAR_VALUE, state, this); SLTLxAtom currIsEmptyState = new SLTLxAtom(state.getWorkflowStateType(), synthesisEngine.getEmptyType(), state); varRefs.add(new SLTLxConjunction(currAtomVar, new SLTLxNegation(currIsEmptyState))); } SLTLxDisjunction allVars = new SLTLxDisjunction(varRefs); return allVars.getCNFEncoding(stateNo, variableSubstitutions, synthesisEngine); } /** * Get the set of clauses that enforce substitution of the variable under the * universal * quantification for the given set of states. In addition, the encoding ensures * that the * usage of variables in atoms will imply usage of the corresponding states as * well (mimicking substitution).
*
* * IMPORTANT: This method should be call after the bound sub-formula was * visited (the corresponding CNF was generated), * in order to ensure that all occurrences of the variable were taken into * account. * * @param stateNo - current state in the SLTLx model * @param synthesisEngine - synthesis engine * @return Set of clauses that encode the possible variable substitution. */ public Set getUniversalCNFEncoding(int stateNo, SLTLxVariableSubstitutionCollection variableSubstitutions, SATSynthesisEngine synthesisEngine) { /** Setting up the domain of the variable. */ Set varRefs = new HashSet<>(); for (State state : variableSubstitutions.getVariableDomain(this)) { SLTLxAtomVar currAtomVar = new SLTLxAtomVar(AtomVarType.VAR_VALUE, state, this); SLTLxAtom currIsEmptyState = new SLTLxAtom(state.getWorkflowStateType(), synthesisEngine.getEmptyType(), state); varRefs.add(new SLTLxXOR(currAtomVar, currIsEmptyState)); } SLTLxConjunction allVars = new SLTLxConjunction(varRefs); return allVars.getCNFEncoding(stateNo, variableSubstitutions, synthesisEngine); } /** * The encoding ensures that the variable substitution preserves the properties * of the data objects, * i.e., if a variable X substitutes state S, the two have to satisfy the same * properties.
* e.g., (VAL(?x,a) => (P(?x) <=> P(a)) *
*
* * IMPORTANT: This method should be call after the bound sub-formula was * visited (the corresponding CNF was generated), * in order to ensure that all the occurrences of the variable were taken into * account. * * @param stateNo - current state in the SLTLx model * @param synthesisEngine - synthesis engine * @return Set of clauses that encode the possible variable substitution. */ public Set getVariableSubstitutionToPreserveProperties(int stateNo, SLTLxVariableSubstitutionCollection variableSubstitutions, SATSynthesisEngine synthesisEngine) { Set allFacts = new HashSet<>(); SLTLxVariableOccurrenceCollection varOccurrences = synthesisEngine.getVariableUsage(); /** * Introduce rules to enforce substitution over unary predicates. * E.g., Val(?x,s1) => (P(?x) <=> P(s1)) */ allFacts.addAll(generateDataPropertySubstitutionRules(this, variableSubstitutions, varOccurrences)); /** * Introduce rules to enforce substitution over binary predicates * * E.g., Val(?x,s1) & Val(?y,s2) => (IS_V(?x,?y) <=> IS(s1,s2)) * * ..in all the variable pairs where the current variable occurs. */ varOccurrences.getPairsContainingVarAsArg(this).forEach( pair -> allFacts.addAll(generateBinarySubstitutionRules(pair, variableSubstitutions, varOccurrences))); SLTLxConjunction andFacts = new SLTLxConjunction(allFacts); return andFacts.getCNFEncoding(stateNo, variableSubstitutions, synthesisEngine); } /** * Generate the rules that enforce substitution over the data properties.
* e.g., (VAL(?x,a) => (P(?x) <=> P(a)) * * @param variable - the variable that will be substituted * @param variableSubstitutions - collection of substitutions for each variable * @param varOccurrences - collection that tracks occurrences of * variables * @return Set of formulas that represent the encoding of the rules */ private static Set generateDataPropertySubstitutionRules(SLTLxVariable variable, SLTLxVariableSubstitutionCollection variableSubstitutions, SLTLxVariableOccurrenceCollection varOccurrences) { Set allFacts = new HashSet<>(); /** * Introduce rules to enforce substitution over unary predicates when needed. * e.g., (VAL(?x,a) => (P(?x) <=> P(a)) */ for (State varState : variableSubstitutions.getVariableDomain(variable)) { for (PredicateLabel usedPred : varOccurrences.getDataTypes(variable)) { /* (VAL(?x,a) => (P(?x) <=> P(a)) */ allFacts.add(new SLTLxImplication( new SLTLxAtomVar( AtomVarType.VAR_VALUE, varState, variable), new SLTLxEquivalence( new SLTLxAtomVar( AtomVarType.TYPE_V, usedPred, variable), new SLTLxAtom( AtomType.MEMORY_TYPE, usedPred, varState)))); } for (State usedPred : varOccurrences.getMemoryReferences(variable)) { /* (VAL(?x,a) => (P(?x) <=> P(a)) */ allFacts.add(new SLTLxImplication( new SLTLxAtomVar( AtomVarType.VAR_VALUE, varState, variable), new SLTLxEquivalence( new SLTLxAtomVar( AtomVarType.MEM_TYPE_REF_V, usedPred, variable), new SLTLxAtom( AtomType.MEM_TYPE_REFERENCE, varState, usedPred)))); } } return allFacts; } /** * Generate the rules that enforce substitution over binary predicates.
* e.g., VAL(?x,a) & VAL(?y,b) => (R_v(x,y) <=> R(a,b)) * * @param pair - a pair of variables that will be substituted * @param variableSubstitutions - collection of substitutions for each variable * @param varOccurrences - collection that tracks occurrences of * variables * @return Set of formulas that represent the encoding of the rules */ private static Set generateBinarySubstitutionRules(Pair pair, SLTLxVariableSubstitutionCollection variableSubstitutions, SLTLxVariableOccurrenceCollection varOccurrences) { Set allFacts = new HashSet<>(); SLTLxVariable var1 = pair.getFirst(); SLTLxVariable var2 = pair.getSecond(); /* * Skip the pair if one of the variables is not in the scope (the rules were * implemented already). */ if (variableSubstitutions.getVariableDomain(var1) == null || variableSubstitutions.getVariableDomain(var2) == null) { return allFacts; } for (AtomVarType atomVarType : varOccurrences.getBinaryPredicates(pair)) { AtomType atomType = inferAtomType(atomVarType); if (atomType == null) continue; for (State var1State : variableSubstitutions.getVariableDomain(var1)) { for (State var2State : variableSubstitutions.getVariableDomain(var2)) { /* VAL(?x,a) & VAL(?y,b) => (P(?x,?y) <=> P(a,b)) */ allFacts.add(new SLTLxImplication( new SLTLxConjunction( new SLTLxAtomVar( AtomVarType.VAR_VALUE, var1State, var1), new SLTLxAtomVar( AtomVarType.VAR_VALUE, var2State, var2)), new SLTLxEquivalence( new SLTLxAtomVar( atomVarType, var1, var2), new SLTLxAtom( atomType, var1State, var2State)))); } } } return allFacts; } /** * When a constant is substituting a variable, infer type of the new atom based * on the type of the one * containing the variable. * * @param atomVarType - type of the atom containing a variable * @return Type of the new atom as long as the substitution is applicable, * {@code null} otherwise. */ private static AtomType inferAtomType(AtomVarType atomVarType) { if (atomVarType.equals(AtomVarType.VAR_EQUIVALENCE)) { return AtomType.IDENTITY_RELATION; } else if (atomVarType.equals(AtomVarType.R_RELATION_V)) { return AtomType.R_RELATION; } else if (atomVarType.equals(AtomVarType.MEM_TYPE_REF_V)) { return AtomType.MEM_TYPE_REFERENCE; } else { return null; } } /** * Get set of states that correspond to the domain of the variable. The states * include all the existing data objects * including those that will be the output of the next operation. * * @param stateNo - current state in the SLTLx model * @param synthesisEngine * @return */ public static Set getVariableDomain(int stateNo, SATSynthesisEngine synthesisEngine) { Set variableDomain = new HashSet<>(); /** * Domain includes the objects generated by the next tool, * and thus we use the next state to get the domain of the variable. */ int nextStateNo = stateNo + 1; for (State state : synthesisEngine.getTypeAutomaton().getAllMemoryStatesUntilBlockNo(nextStateNo)) { variableDomain.add(state); } return variableDomain; } public Set getVariableMutualExclusion(int stateNo, SLTLxVariableSubstitutionCollection variableMapping, SATSynthesisEngine synthesisEngine) { Set allClauses = new HashSet<>(); /** * Domain includes the objects generated by the next tool, * and thus we use the next state to get the domain of the variable. */ int nextStateNo = stateNo + 1; Set> statePairs = APEUtils .getUniquePairs(synthesisEngine.getTypeAutomaton().getAllMemoryStatesUntilBlockNo(nextStateNo)); statePairs.forEach(statePair -> { allClauses.addAll( new SLTLxNegatedConjunction( new SLTLxAtomVar( AtomVarType.VAR_VALUE, statePair.getFirst(), this), new SLTLxAtomVar( AtomVarType.VAR_VALUE, statePair.getSecond(), this)) .getCNFEncoding(stateNo, variableMapping, synthesisEngine)); }); return allClauses; } }





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