Merge mit Unify und Bytecode

This commit is contained in:
JanUlrich 2016-03-22 15:13:51 +01:00
commit f788b74f26
10 changed files with 454 additions and 167 deletions

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@ -48,7 +48,8 @@ public interface IFiniteClosure {
public Set<UnifyType> grArg(PlaceholderType type);
public Set<UnifyType> smArg(PlaceholderType type);
public Optional<UnifyType> getGenericType(String typeName);
public Set<UnifyType> getAllTypes(String typeName);
public Set<UnifyType> getAllTypesByName(String typeName);
}

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@ -1,5 +1,7 @@
package de.dhbwstuttgart.typeinference.unify.model;
import java.util.ArrayList;
import java.util.Arrays;
import java.util.HashMap;
import java.util.HashSet;
import java.util.Optional;
@ -7,13 +9,19 @@ import java.util.Set;
import java.util.stream.Collectors;
import de.dhbwstuttgart.typeinference.unify.interfaces.IFiniteClosure;
import de.dhbwstuttgart.typeinference.unify.interfaces.IUnify;
import de.dhbwstuttgart.typeinference.unify.model.MPair.PairOperator;
import de.dhbwstuttgart.typeinference.unifynew.MartelliMontanariUnify;
public class FiniteClosure implements IFiniteClosure {
private HashMap<UnifyType, Node<UnifyType>> inheritanceGraph;
private HashMap<String, HashSet<Node<UnifyType>>> strInheritanceGraph;
public FiniteClosure() {
}
public FiniteClosure(Set<MPair> pairs) {
inheritanceGraph = new HashMap<UnifyType, Node<UnifyType>>();
@ -50,33 +58,120 @@ public class FiniteClosure implements IFiniteClosure {
strInheritanceGraph.get(key.getName()).add(inheritanceGraph.get(key));
}
}
/**
* Returns all types of the finite closure that are subtypes of the argument.
* @return The set of subtypes of the argument.
*/
@Override
@Override
public Set<UnifyType> smaller(UnifyType type) {
if(!inheritanceGraph.containsKey(type))
return new HashSet<>();
Set<UnifyType> result = inheritanceGraph.get(type).getContentOfDescendants();
// - if(T < T') then T <=* T'
Set<UnifyType> result = inheritanceGraph.containsKey(type) ? inheritanceGraph.get(type).getContentOfDescendants() : new HashSet<>();
result.add(type);
// if T1 <=* T2 then sigma1(T1) <=* sigma1(T2)
// where foreach type var a in T2:
// sigma1(T1) <=* sigma2(T2)
/*if(strInheritanceGraph.containsKey(type.getName())) {
IUnify unify = new MartelliMontanariUnify();
HashSet<Node<Type>> candidateNodes = strInheritanceGraph.get(type.getName());
for(Node<Type> candidateNode : candidateNodes) {
Type theta2 = candidateNode.getContent();
Optional<Unifier> sigma2 = unify.unify(theta2, type);
if(!sigma2.isPresent())
continue;
for(Type sigma1theta1 : candidateNode.getContentOfDescendants()) {
Type theta1 = sigma2.get().apply(sigma1theta1);
}
}
}*/
if(type.getTypeParams().size() == 0)
return result;
ArrayList<Set<UnifyType>> paramCandidates = new ArrayList<>();
for(UnifyType param : type.getTypeParams()) {
if(param instanceof ExtendsType || param instanceof SuperType) {
Set<UnifyType> pc = param.smArg(this);
paramCandidates.add(pc);
} else {
HashSet<UnifyType> pc = new HashSet<>();
pc.add(param);
paramCandidates.add(pc);
}
}
Set<TypeParams> permResult = new HashSet<>();
permuteParams(paramCandidates, 0, permResult, new UnifyType[paramCandidates.size()]);
for(TypeParams newParams : permResult)
result.add(type.setTypeParams(newParams));
return result;
}
/**
* @param t1
* @param t2
* @return
*/
protected Optional<Unifier> match(UnifyType t1, UnifyType t2) {
if(!t1.getName().equals(t2.getName()))
return Optional.empty();
TypeParams t1Params = t1.getTypeParams();
TypeParams t2Params = t2.getTypeParams();
if(t1Params.size() != t2Params.size())
return Optional.empty();
Unifier result = new Unifier();
for(int i = 0; i < t1Params.size(); i++) {
UnifyType t1i = t1Params.get(i);
UnifyType t2i = t2Params.get(i);
boolean equal = t1i.equals(t2i);
if(!equal && !(t2i instanceof PlaceholderType))
return Optional.empty();
if(!equal && t2i instanceof PlaceholderType)
result.Add((PlaceholderType) t2i, t1i);
}
return Optional.of(result);
}
/**
* Returns all types of the finite closure that are supertypes of the argument.
* @return The set of supertypes of the argument.
*/
@Override
@Override
public Set<UnifyType> greater(UnifyType type) {
if(!inheritanceGraph.containsKey(type))
return new HashSet<>();
Set<UnifyType> result = inheritanceGraph.get(type).getContentOfPredecessors();
Set<UnifyType> result = inheritanceGraph.containsKey(type) ? inheritanceGraph.get(type).getContentOfPredecessors() : new HashSet<>();
result.add(type);
if(type.getTypeParams().size() == 0)
return result;
ArrayList<Set<UnifyType>> paramCandidates = new ArrayList<>();
for(UnifyType param : type.getTypeParams()) {
if(param instanceof ExtendsType || param instanceof SuperType) {
Set<UnifyType> pc = param.grArg(this);
paramCandidates.add(pc);
} else {
HashSet<UnifyType> pc = new HashSet<>();
pc.add(param);
paramCandidates.add(pc);
}
}
Set<TypeParams> permResult = new HashSet<>();
permuteParams(paramCandidates, 0, permResult, new UnifyType[paramCandidates.size()]);
for(TypeParams newParams : permResult)
result.add(type.setTypeParams(newParams));
return result;
}
@ -103,8 +198,9 @@ public class FiniteClosure implements IFiniteClosure {
public Set<UnifyType> grArg(ExtendsType type) {
if(!inheritanceGraph.containsKey(type.getExtendedType()))
return new HashSet<UnifyType>();
Set<UnifyType> result = new HashSet<UnifyType>();
result.add(type);
UnifyType t = type.getExtendedType();
@ -117,8 +213,9 @@ public class FiniteClosure implements IFiniteClosure {
public Set<UnifyType> grArg(SuperType type) {
if(!inheritanceGraph.containsKey(type.getSuperedType()))
return new HashSet<UnifyType>();
Set<UnifyType> result = new HashSet<UnifyType>();
result.add(type);
UnifyType t = type.getSuperedType();
@ -127,9 +224,13 @@ public class FiniteClosure implements IFiniteClosure {
return result;
}
@Override
@Override
public Set<UnifyType> grArg(PlaceholderType type) {
return new HashSet<>();
HashSet<UnifyType> result = new HashSet<>();
result.add(type);
result.add(new SuperType(type));
result.add(new ExtendsType(type));
return result;
}
@Override
@ -153,8 +254,9 @@ public class FiniteClosure implements IFiniteClosure {
public Set<UnifyType> smArg(ExtendsType type) {
if(!inheritanceGraph.containsKey(type.getExtendedType()))
return new HashSet<UnifyType>();
Set<UnifyType> result = new HashSet<UnifyType>();
result.add(type);
UnifyType t = type.getExtendedType();
@ -172,8 +274,9 @@ public class FiniteClosure implements IFiniteClosure {
public Set<UnifyType> smArg(SuperType type) {
if(!inheritanceGraph.containsKey(type.getSuperedType()))
return new HashSet<UnifyType>();
Set<UnifyType> result = new HashSet<UnifyType>();
result.add(type);
UnifyType t = type.getSuperedType();
@ -186,9 +289,13 @@ public class FiniteClosure implements IFiniteClosure {
return result;
}
@Override
@Override
public Set<UnifyType> smArg(PlaceholderType type) {
return new HashSet<>();
HashSet<UnifyType> result = new HashSet<>();
result.add(type);
result.add(new SuperType(type));
result.add(new ExtendsType(type));
return result;
}
@Override
@ -207,10 +314,24 @@ public class FiniteClosure implements IFiniteClosure {
return Optional.empty();
}
@Override
public Set<UnifyType> getAllTypes(String typeName) {
@Override
public Set<UnifyType> getAllTypesByName(String typeName) {
if(!strInheritanceGraph.containsKey(typeName))
return new HashSet<>();
return strInheritanceGraph.get(typeName).stream().map(x -> x.getContent()).collect(Collectors.toCollection(HashSet::new));
}
protected void permuteParams(ArrayList<Set<UnifyType>> candidates, int idx, Set<TypeParams> result, UnifyType[] current) {
if(candidates.size() == idx) {
result.add(new TypeParams(Arrays.copyOf(current, current.length)));
return;
}
Set<UnifyType> localCandidates = candidates.get(idx);
for(UnifyType t : localCandidates) {
current[idx] = t;
permuteParams(candidates, idx+1, result, current);
}
}
}

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@ -5,8 +5,10 @@ import java.util.Map.Entry;
import java.util.Set;
import java.util.function.Function;
public class Unifier implements Function<UnifyType, UnifyType> {
public class Unifier implements Function<UnifyType, UnifyType> /*, Set<MPair>*/ { // TODO set implementieren
private HashMap<PlaceholderType, UnifyType> substitutions = new HashMap<>();
public static Unifier IDENTITY = new Unifier();

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@ -101,12 +101,12 @@ public class MartelliMontanariUnify implements IUnify {
TypeParams rhsTypeParams = rhs.getTypeParams();
TypeParams lhsTypeParams = lhs.getTypeParams();
if(!rhs.getName().equals(lhs.getName()) || rhsTypeParams.size() != lhsTypeParams.size())
return null; // conflict
if(rhsTypeParams.size() == 0 || lhsTypeParams.size() == 0)
return Optional.empty();
if(!rhs.getName().equals(lhs.getName()) || rhsTypeParams.size() != lhsTypeParams.size())
return null; // conflict
for(int i = 0; i < rhsTypeParams.size(); i++)
result.add(new MPair(rhsTypeParams.get(i), lhsTypeParams.get(i), PairOperator.EQUALSDOT));

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@ -57,33 +57,48 @@ public class Unify {
* mit dem geordneten Tripel (a,b,c), wodurch das kartesische Produkt auch assoziativ wird." - Wikipedia
*/
// All Sets
List<Set<MPair>> sets = new ArrayList<Set<MPair>>();
// There are up to 10 toplevel set. 8 of 10 are the result of the
// cartesian product of the sets created by pattern matching.
List<Set<Set<MPair>>> topLevelSets = new ArrayList<>();
if(eq1s.size() != 0)
sets.add(eq1s); // Add Eq1'
if(eq1s.size() != 0) {
Set<Set<MPair>> wrap = new HashSet<>();
wrap.add(eq1s);
topLevelSets.add(wrap); // Add Eq1'
}
// Add the set of [a =. Theta | (a=. Theta) in Eq2']
Set<MPair> bufferSet = eq2s.stream()
.filter(x -> x.getPairOp() == PairOperator.EQUALSDOT && x.getLhsType() instanceof PlaceholderType)
.collect(Collectors.toSet());
if(bufferSet.size() != 0)
sets.add(bufferSet);
if(bufferSet.size() != 0) {
Set<Set<MPair>> wrap = new HashSet<>();
wrap.add(bufferSet);
topLevelSets.add(wrap);
}
// Sets that originate from pair pattern matching
// Sets of the "second level"
sets.addAll(calculatePairSets(eq2s, fc));
Set<Set<Set<MPair>>> secondLevelSets = calculatePairSets(eq2s, fc);
/* Up to here, no cartesian products are calculated.
* Around here, filters for pairs and sets can be applied */
* filters for pairs and sets can be applied here */
ISetOperations setOps = new GuavaSetOperations();
// Calculate the cartesian products
Set<Set<MPair>> result = setOps.cartesianProduct(sets).stream()
.map(x -> new HashSet<MPair>(x)).collect(Collectors.toCollection(HashSet::new));
// Sub cartesian products of the second level (pattern matched) sets
for(Set<Set<MPair>> secondLevelSet : secondLevelSets) {
List<Set<MPair>> secondLevelSetList = new ArrayList<>(secondLevelSet);
topLevelSets.add(setOps.cartesianProduct(secondLevelSetList)
.stream().map(x -> new HashSet<>(x))
.collect(Collectors.toCollection(HashSet::new)));
}
// Cartesian product over all (up to 10) top level sets
Set<Set<Set<MPair>>> eqPrimeSet = setOps.cartesianProduct(topLevelSets)
.stream().map(x -> new HashSet<>(x))
.collect(Collectors.toCollection(HashSet::new));
//System.out.println(result);
/*
@ -91,38 +106,41 @@ public class Unify {
*/
/*
* TODO
* Im Paper wird Eq'' genannt, es wird also von einer Menge in einer Menge in einer Menge ausgegangen.
* Durch das flache Kartesische Produkt gibt es hier aber nur Mengen in Mengen.
* Richtig so?
* TODO hier das ergebnis schonh flach machen? (wird im unify old (glaub ich) so gemacht)
*/
Set<Set<MPair>> eqPrimeSetFlat = new HashSet<>();
for(Set<Set<MPair>> setToFlatten : eqPrimeSet) {
Set<MPair> buffer = new HashSet<>();
setToFlatten.stream().forEach(x -> buffer.addAll(x));
eqPrimeSetFlat.add(buffer);
}
IRuleSet rules = new RuleSet(fc);
Set<Set<MPair>> changed = new HashSet<>();
Set<Set<MPair>> unchanged = new HashSet<>();
Set<Set<MPair>> eqPrimePrimeSet = new HashSet<>();
for(Set<MPair> eqss : result) {
Optional<Set<MPair>> newEqss = rules.subst(eqss);
if(newEqss.isPresent())
changed.add(newEqss.get());
else
unchanged.add(eqss);
for(Set<MPair> eqPrime : eqPrimeSetFlat) {
Optional<Set<MPair>> eqPrimePrime = rules.subst(eqPrime);
if(eqPrimePrime.isPresent())
changed.add(eqPrimePrime.get());
else
eqPrimePrimeSet.add(eqPrime);
}
/*
* Step 6 a) Restart for pairs where subst was applied
* b) Build the union over everything
*/
for(Set<MPair> eqss : changed)
unchanged.addAll(this.unify(eqss, fc));
for(Set<MPair> eqss : changed) {
eqPrimePrimeSet.addAll(this.unify(eqss, fc));
}
/*
* Step 7: Filter result for solved pairs TODO wie?
* Step 7: Filter result for solved pairs
*/
return unchanged;
return eqPrimePrimeSet;
}
@ -217,8 +235,12 @@ public class Unify {
}
protected List<Set<MPair>> calculatePairSets(Set<MPair> eq2s, IFiniteClosure fc) {
List<Set<MPair>> result = new ArrayList<Set<MPair>>();
protected Set<Set<Set<MPair>>> calculatePairSets(Set<MPair> eq2s, IFiniteClosure fc) {
List<Set<Set<MPair>>> result = new ArrayList<>();
// Init all 8 cases
for(int i = 0; i < 8; i++)
result.add(new HashSet<>());
for(MPair pair : eq2s) {
@ -226,105 +248,223 @@ public class Unify {
UnifyType lhsType = pair.getLhsType();
UnifyType rhsType = pair.getRhsType();
// Case 1: (a <. Theta')
if(pairOp == PairOperator.SMALLERDOT && lhsType instanceof PlaceholderType) {
UnifyType thetaPrime = pair.getRhsType();
Set<MPair> set = new HashSet<>();
IUnify unify = new MartelliMontanariUnify();
//Set<Type> cs = fc.getAllTypes(rhsType.getName());
UnifyType c = rhsType;
//Set<Type> thetaQs = cs.stream().flatMap(x -> fc.smaller(x).stream()).collect(Collectors.toCollection(HashSet::new));
Set<UnifyType> thetaQs = fc.smaller(c);
Set<UnifyType> thetaQPrimes = new HashSet<>();
TypeParams cParams = c.getTypeParams();
if(cParams.size() == 0)
thetaQPrimes.add(c);
else {
ArrayList<Set<UnifyType>> candidateParams = new ArrayList<>();
for(UnifyType param : cParams)
candidateParams.add(fc.grArg(param));
Set<TypeParams> permutations = new HashSet<TypeParams>();
permuteParams(candidateParams, 0, permutations, new UnifyType[candidateParams.size()]);
for(TypeParams tp : permutations)
thetaQPrimes.add(c.setTypeParams(tp));
}
for(UnifyType tqp : thetaQPrimes) {
Optional<Unifier> opt = unify.unify(tqp, thetaPrime);
if(opt.isPresent()) {
Unifier unifier = opt.get();
Set<Entry<PlaceholderType, UnifyType>> substitutions = unifier.getSubstitutions();
for(Entry<PlaceholderType, UnifyType> sigma : substitutions)
set.add(new MPair(sigma.getKey(), sigma.getValue(), PairOperator.EQUALSDOT));
for(UnifyType tq : thetaQs) {
Set<UnifyType> smaller = fc.smaller(unifier.apply(tq));
smaller.stream().map(x -> new MPair(lhsType, x, PairOperator.EQUALSDOT)).forEach(x -> set.add(x));
}
}
}
result.add(set);
}
// Case 1: (a <. Theta')
if(pairOp == PairOperator.SMALLERDOT && lhsType instanceof PlaceholderType)
result.get(0).add(unifyCase1((PlaceholderType) pair.getLhsType(), pair.getRhsType(), fc));
// Case 2: (a <.? ? ext Theta')
else if(pairOp == PairOperator.SMALLERDOTWC && lhsType instanceof PlaceholderType && rhsType instanceof ExtendsType){
throw new NotImplementedException(); // TODO
}
else if(pairOp == PairOperator.SMALLERDOTWC && lhsType instanceof PlaceholderType && rhsType instanceof ExtendsType)
result.get(1).add(unifyCase2((PlaceholderType) pair.getLhsType(), (ExtendsType) pair.getRhsType(), fc));
// Case 3: (a <.? ? sup Theta')
else if(pairOp == PairOperator.SMALLERDOTWC && lhsType instanceof PlaceholderType && rhsType instanceof SuperType) {
Set<MPair> set = new HashSet<>();
for(UnifyType theta : fc.smArg(rhsType))
set.add(new MPair(lhsType, theta, PairOperator.EQUALSDOT));
result.add(set);
}
// Case 3: (a <.? ? sup Theta')
else if(pairOp == PairOperator.SMALLERDOTWC && lhsType instanceof PlaceholderType && rhsType instanceof SuperType)
result.get(2).add(unifyCase3((PlaceholderType) lhsType, (SuperType) rhsType, fc));
// Case 4: (a <.? Theta')
else if(pairOp == PairOperator.SMALLERDOTWC && lhsType instanceof PlaceholderType) {
Set<MPair> set = new HashSet<>();
set.add(new MPair(lhsType, rhsType, PairOperator.EQUALSDOT));
result.add(set);
}
else if(pairOp == PairOperator.SMALLERDOTWC && lhsType instanceof PlaceholderType)
result.get(3).add(unifyCase4((PlaceholderType) lhsType, rhsType, fc));
// Case 5: (Theta <. a)
else if(pairOp == PairOperator.SMALLERDOT && rhsType instanceof PlaceholderType) {
Set<MPair> set = new HashSet<>();
for(UnifyType thetaS : fc.greater(lhsType))
set.add(new MPair(rhsType, thetaS, PairOperator.EQUALSDOT));
result.add(set);
}
// Case 5: (Theta <. a)
else if(pairOp == PairOperator.SMALLERDOT && rhsType instanceof PlaceholderType)
result.get(4).add(unifyCase5(lhsType, (PlaceholderType) rhsType, fc));
// Case 6: (? ext Theta <.? a)
else if(pairOp == PairOperator.SMALLERDOTWC && lhsType instanceof ExtendsType && rhsType instanceof PlaceholderType) {
Set<MPair> set = new HashSet<>();
for(UnifyType thetaS : fc.grArg(lhsType))
set.add(new MPair(rhsType, thetaS, PairOperator.EQUALSDOT));
result.add(set);
}
else if(pairOp == PairOperator.SMALLERDOTWC && lhsType instanceof ExtendsType && rhsType instanceof PlaceholderType)
result.get(5).add(unifyCase6((ExtendsType) lhsType, (PlaceholderType) rhsType, fc));
// Case 7: (? sup Theta <.? a)
else if(pairOp == PairOperator.SMALLERDOTWC && lhsType instanceof SuperType && rhsType instanceof PlaceholderType) {
throw new NotImplementedException(); // TODO
}
else if(pairOp == PairOperator.SMALLERDOTWC && lhsType instanceof SuperType && rhsType instanceof PlaceholderType)
result.get(6).add(unifyCase7((SuperType) lhsType, (PlaceholderType) rhsType, fc));
// Case 8: (Theta <.? a)
else if(pairOp == PairOperator.SMALLERDOTWC && rhsType instanceof PlaceholderType) {
Set<MPair> set = new HashSet<>();
for(UnifyType thetaS : fc.grArg(lhsType))
set.add(new MPair(rhsType, thetaS, PairOperator.EQUALSDOT));
result.add(set);
else if(pairOp == PairOperator.SMALLERDOTWC && rhsType instanceof PlaceholderType)
result.get(7).add(unifyCase8(lhsType, (PlaceholderType) rhsType, fc));
}
return result.stream().filter(x -> x.size() > 0).collect(Collectors.toCollection(HashSet::new));
}
protected Set<MPair> unifyCase1(PlaceholderType a, UnifyType thetaPrime, IFiniteClosure fc) {
Set<MPair> result = new HashSet<>();
IUnify unify = new MartelliMontanariUnify();
Set<UnifyType> cs = fc.getAllTypesByName(thetaPrime.getName());
for(UnifyType c : cs) {
// Wenn die fc nach spezifikation funktioniert ist das hier nicht mehr nötig?
Set<UnifyType> thetaQs = fc.smaller(c).stream().filter(x -> x.getTypeParams().arePlaceholders()).collect(Collectors.toCollection(HashSet::new));
thetaQs.add(c); // reflexive
Set<UnifyType> thetaQPrimes = new HashSet<>();
TypeParams cParams = c.getTypeParams();
if(cParams.size() == 0)
thetaQPrimes.add(c);
else {
ArrayList<Set<UnifyType>> candidateParams = new ArrayList<>();
for(UnifyType param : cParams)
candidateParams.add(fc.grArg(param));
for(TypeParams tp : permuteParams(candidateParams))
thetaQPrimes.add(c.setTypeParams(tp));
}
for(UnifyType tqp : thetaQPrimes) {
Optional<Unifier> opt = unify.unify(tqp, thetaPrime);
if (!opt.isPresent())
continue;
Unifier unifier = opt.get();
Set<Entry<PlaceholderType, UnifyType>> substitutions = unifier.getSubstitutions();
for (Entry<PlaceholderType, UnifyType> sigma : substitutions)
result.add(new MPair(sigma.getKey(), sigma.getValue(), PairOperator.EQUALSDOT));
for (UnifyType tq : thetaQs) {
Set<UnifyType> smaller = fc.smaller(unifier.apply(tq));
smaller.stream().map(x -> new MPair(a, x, PairOperator.EQUALSDOT))
.forEach(x -> result.add(x));
}
}
}
return result;
}
protected void permuteParams(ArrayList<Set<UnifyType>> candidates, int idx, Set<TypeParams> result, UnifyType[] current) {
protected Set<MPair> unifyCase2(PlaceholderType a, ExtendsType extThetaPrime, IFiniteClosure fc) {
Set<MPair> result = new HashSet<>();
IUnify unify = new MartelliMontanariUnify();
UnifyType thetaPrime = extThetaPrime.getExtendedType();
Set<UnifyType> cs = fc.getAllTypesByName(thetaPrime.getName());
for(UnifyType c : cs) {
// Wenn die fc nach spezifikation funktioniert ist das hier nicht mehr nötig?
Set<UnifyType> thetaQs = fc.smaller(c).stream().filter(x -> x.getTypeParams().arePlaceholders()).collect(Collectors.toCollection(HashSet::new));
thetaQs.add(c); // reflexive
Set<UnifyType> thetaQPrimes = new HashSet<>();
TypeParams cParams = c.getTypeParams();
if(cParams.size() == 0)
thetaQPrimes.add(c);
else {
ArrayList<Set<UnifyType>> candidateParams = new ArrayList<>();
for(UnifyType param : cParams)
candidateParams.add(fc.grArg(param));
for(TypeParams tp : permuteParams(candidateParams))
thetaQPrimes.add(c.setTypeParams(tp));
}
for(UnifyType tqp : thetaQPrimes) {
Optional<Unifier> opt = unify.unify(tqp, thetaPrime);
if (!opt.isPresent())
continue;
Unifier unifier = opt.get();
Set<Entry<PlaceholderType, UnifyType>> substitutions = unifier.getSubstitutions();
for (Entry<PlaceholderType, UnifyType> sigma : substitutions)
result.add(new MPair(sigma.getKey(), sigma.getValue(), PairOperator.EQUALSDOT));
for (UnifyType tq : thetaQs) {
ExtendsType extTq = new ExtendsType(tq);
Set<UnifyType> smaller = fc.smaller(unifier.apply(extTq));
smaller.stream().map(x -> new MPair(a, x, PairOperator.EQUALSDOT))
.forEach(x -> result.add(x));
}
}
}
return result;
}
protected Set<MPair> unifyCase3(PlaceholderType a, SuperType subThetaPrime, IFiniteClosure fc) {
Set<MPair> result = new HashSet<>();
for(UnifyType theta : fc.smArg(subThetaPrime))
result.add(new MPair(a, theta, PairOperator.EQUALSDOT));
return result;
}
protected Set<MPair> unifyCase4(PlaceholderType a, UnifyType thetaPrime, IFiniteClosure fc) {
Set<MPair> result = new HashSet<>();
result.add(new MPair(a, thetaPrime, PairOperator.EQUALSDOT));
return result;
}
protected Set<MPair> unifyCase5(UnifyType theta, PlaceholderType a, IFiniteClosure fc) {
Set<MPair> result = new HashSet<>();
for(UnifyType thetaS : fc.greater(theta))
result.add(new MPair(a, thetaS, PairOperator.EQUALSDOT));
return result;
}
protected Set<MPair> unifyCase6(ExtendsType extTheta, PlaceholderType a, IFiniteClosure fc) {
Set<MPair> result = new HashSet<>();
for(UnifyType thetaS : fc.grArg(extTheta))
result.add(new MPair(a, thetaS, PairOperator.EQUALSDOT));
return result;
}
protected Set<MPair> unifyCase7(SuperType supTheta, PlaceholderType a, IFiniteClosure fc) {
Set<MPair> result = new HashSet<>();
IUnify unify = new MartelliMontanariUnify();
UnifyType theta = supTheta.getSuperedType();
Set<UnifyType> cs = fc.getAllTypesByName(theta.getName());
for(UnifyType c : cs) {
// Wenn die fc nach spezifikation funktioniert ist das hier nicht mehr nötig?
Set<UnifyType> thetaQs = fc.smaller(c).stream().filter(x -> x.getTypeParams().arePlaceholders()).collect(Collectors.toCollection(HashSet::new));
thetaQs.add(c); // reflexive
Set<UnifyType> thetaQPrimes = new HashSet<>();
TypeParams cParams = c.getTypeParams();
if(cParams.size() == 0)
thetaQPrimes.add(c);
else {
ArrayList<Set<UnifyType>> candidateParams = new ArrayList<>();
for(UnifyType param : cParams)
candidateParams.add(fc.grArg(param));
for(TypeParams tp : permuteParams(candidateParams))
thetaQPrimes.add(c.setTypeParams(tp));
}
for(UnifyType tqp : thetaQPrimes) {
Optional<Unifier> opt = unify.unify(tqp, theta);
if (!opt.isPresent())
continue;
Unifier unifier = opt.get();
Set<Entry<PlaceholderType, UnifyType>> substitutions = unifier.getSubstitutions();
for (Entry<PlaceholderType, UnifyType> sigma : substitutions)
result.add(new MPair(sigma.getKey(), sigma.getValue(), PairOperator.EQUALSDOT));
for (UnifyType tq : thetaQs) {
Set<UnifyType> smaller = fc.smaller(unifier.apply(tq));
smaller.stream().map(x -> new MPair(a, new SuperType(x), PairOperator.EQUALSDOT))
.forEach(x -> result.add(x));
}
}
}
return result;
}
protected Set<MPair> unifyCase8(UnifyType theta, PlaceholderType a, IFiniteClosure fc) {
Set<MPair> result = new HashSet<>();
for(UnifyType thetaS : fc.grArg(theta))
result.add(new MPair(a, thetaS, PairOperator.EQUALSDOT));
return result;
}
protected Set<TypeParams> permuteParams(ArrayList<Set<UnifyType>> candidates) {
Set<TypeParams> result = new HashSet<>();
permuteParams(candidates, 0, result, new UnifyType[candidates.size()]);
return result;
}
private void permuteParams(ArrayList<Set<UnifyType>> candidates, int idx, Set<TypeParams> result, UnifyType[] current) {
if(candidates.size() == idx) {
result.add(new TypeParams(Arrays.copyOf(current, current.length)));
return;
@ -336,14 +476,5 @@ public class Unify {
current[idx] = t;
permuteParams(candidates, idx+1, result, current);
}
}
private Set<UnifyType> getAllInstantiations(UnifyType t, IFiniteClosure fc) {
Set<UnifyType> result = new HashSet<>();
result.add(t);
return result;
// TODO
}
}
}

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@ -1,15 +1,20 @@
class AutoOverloading{
method2(String p){
return p;
}
method2(Integer p){
return p;
}
method(p){
method2(p);
return method2(p);
}
public static void main(String[] args){
System.out.println(methode("hallo"));
System.out.println(methode(2));
}
}

View File

@ -17,6 +17,7 @@ import bytecode.SourceFileBytecodeTest;
public class SuperType extends SourceFileBytecodeTest{
@Override
protected void init() {
testName = "ExtendsType";

View File

@ -1,16 +1,38 @@
package unify;
import java.util.HashSet;
import java.util.Set;
import org.junit.Assert;
import org.junit.Test;
import de.dhbwstuttgart.typeinference.unify.interfaces.IFiniteClosure;
import de.dhbwstuttgart.typeinference.unify.model.MPair;
import de.dhbwstuttgart.typeinference.unify.model.MPair.PairOperator;
import de.dhbwstuttgart.typeinference.unify.model.UnifyType;
import de.dhbwstuttgart.typeinference.unify.model.MPair.PairOperator;
import de.dhbwstuttgart.typeinference.unify.model.FiniteClosure;
import de.dhbwstuttgart.typeinference.unify.model.UnifyType;
public class FiniteClosureTest {
public class FiniteClosureTest extends FiniteClosure {
@Test
public void testMatch() {
TypeFactory tf = new TypeFactory();
UnifyType a = tf.getPlaceholderType("a");
UnifyType b = tf.getPlaceholderType("b");
UnifyType c = tf.getPlaceholderType("c");
UnifyType A = tf.getSimpleType("A");
UnifyType B = tf.getSimpleType("B");
UnifyType C1 = tf.getSimpleType("C", a, b, c);
UnifyType C2 = tf.getSimpleType("C", a, A, b);
UnifyType C3 = tf.getSimpleType("C", A, B, A);
UnifyType D1 = tf.getSimpleType("D", C1, a, b, c);
UnifyType D2 = tf.getSimpleType("D", C3, A, B, A);
System.out.println(match(C2, C1));
System.out.println(match(C3, C1));
System.out.println(match(D2, D1));
Assert.assertFalse(match(C3, C2).isPresent());
Assert.assertFalse(match(C1, C2).isPresent());
}
@Test
public void testGreater() {
@ -36,10 +58,14 @@ public class FiniteClosureTest {
@Test
public void testSmaller() {
IFiniteClosure fc = new FiniteClosureBuilder().getCollectionExample();
FiniteClosureBuilder fcb = new FiniteClosureBuilder();
TypeFactory tf = new TypeFactory();
fcb.add(tf.getSimpleType("Integer"), tf.getSimpleType("Number"));
IFiniteClosure fc = fcb.getCollectionExample();
System.out.println("\n\n----- Smaller Test -----");
System.out.println("Smaller(List<? extends Number>) = " + fc.smaller(tf.getSimpleType("List", tf.getExtendsType(tf.getSimpleType("Number")))));
System.out.println("Smaller(List<T>) = " + fc.smaller(tf.getSimpleType("List", "T")));
System.out.println("Smaller(TreeSet<T>) = " + fc.smaller(tf.getSimpleType("TreeSet", "T")));
System.out.println("Smaller(Collection) = " + fc.smaller(tf.getSimpleType("Collection")));

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@ -16,7 +16,7 @@ import de.dhbwstuttgart.typeinference.assumptions.TypeAssumptions;
import de.dhbwstuttgart.typeinference.unify.model.FiniteClosure;
import de.dhbwstuttgart.typeinference.unify.model.UnifyType;
public class GenerateFiniteClosure {
public class GenerateFiniteClosure{
private TypeAssumptions generateAssumptionsFromImport(String importClass){
SourceFile sf = new SourceFile();
@ -44,7 +44,7 @@ public class GenerateFiniteClosure {
String importClass = "java.util.Vector";
TypeAssumptions ass = generateAssumptionsFromImport(importClass);
FiniteClosure fc = UnifyTypeFactory.generateFC(ass);
Set<UnifyType> test = fc.getAllTypes(importClass);
Set<UnifyType> test = fc.getAllTypesByName(importClass);
assertTrue(test.size()>0);
}

View File

@ -24,6 +24,7 @@ public class UnifyTest extends Unify {
//fcb.add(tf.getSimpleType("Number"), tf.getSimpleType("Object"));
fcb.add(tf.getSimpleType("Integer"), tf.getSimpleType("Number"));
fcb.add(tf.getSimpleType("Double"), tf.getSimpleType("Number"));
fcb.add(tf.getSimpleType("MyList"), tf.getSimpleType("List", tf.getSimpleType("Integer")));
//fcb.add(tf.getSimpleType("List", "T"));
IFiniteClosure fc = fcb.getCollectionExample();
@ -35,9 +36,9 @@ public class UnifyTest extends Unify {
// Double <. B
// B <. Object
eq.add(new MPair(tf.getSimpleType("Vector", tf.getSimpleType("Integer")), tf.getSimpleType("Vector", "A"), PairOperator.SMALLERDOT));
//eq.add(new MPair(tf.getSimpleType("Vector", tf.getSimpleType("Number")), tf.getSimpleType("Vector", "A"), PairOperator.SMALLERDOT));
eq.add(new MPair(tf.getSimpleType("Vector", tf.getSimpleType("Number")), tf.getSimpleType("Vector", "A"), PairOperator.SMALLERDOT));
//eq.add(new MPair(tf.getSimpleType("Vector", tf.getSimpleType("Integer")), tf.getSimpleType("Vector", "C"), PairOperator.SMALLERDOT));
eq.add(new MPair(tf.getPlaceholderType("A"), tf.getSimpleType("List", tf.getSimpleType("Number")), PairOperator.SMALLERDOT));
//eq.add(new MPair(tf.getPlaceholderType("A"), tf.getSimpleType("List", "A"), PairOperator.SMALLERDOT));
//eq.add(new MPair(tf.getSimpleType("Number"), tf.getPlaceholderType("A"), PairOperator.SMALLERDOT));
//eq.add(new MPair(tf.getPlaceholderType("A"), tf.getPlaceholderType("C"), PairOperator.SMALLERDOT));
//eq.add(new MPair(tf.getSimpleType("Double"), tf.getPlaceholderType("B"), PairOperator.SMALLERDOT));
@ -78,9 +79,8 @@ public class UnifyTest extends Unify {
candidates.add(p1);
candidates.add(p2);
candidates.add(p3);
Set<TypeParams> result = new HashSet<>();
permuteParams(candidates, 0, result, new UnifyType[candidates.size()]);
Set<TypeParams> result = permuteParams(candidates);
System.out.println(result);
}