/**
* Return the greatest lower bound of two types. That is, return the largest type that is a
* subtype of both inputs.
*/
public JReferenceType strongerType(JReferenceType type1, JReferenceType type2) {
if (type1 == type2) {
return type1;
}
if (type1 instanceof JNullType || type2 instanceof JNullType) {
return JNullType.INSTANCE;
}
if (type1 instanceof JNonNullType != type2 instanceof JNonNullType) {
// If either is non-nullable, the result should be non-nullable.
return strongerType(type1.getNonNull(), type2.getNonNull());
}
if (typeOracle.canTriviallyCast(type1, type2)) {
return type1;
}
if (typeOracle.canTriviallyCast(type2, type1)) {
return type2;
}
// cannot determine a strong type, just return the first one (this makes two
// "unrelated" interfaces work correctly in TypeTightener
return type1;
}
/**
* Return the greatest lower bound of two types. That is, return the largest type that is a
* subtype of both inputs. If none exists return {@code thisType}.
*/
public JReferenceType strengthenType(JReferenceType thisType, JReferenceType thatType) {
if (thisType == thatType) {
return thisType;
}
if (thisType.isNullType() || thatType.isNullType()) {
return JReferenceType.NULL_TYPE;
}
if (thisType.canBeNull() != thatType.canBeNull()) {
// If either is non-nullable, the result should be non-nullable.
return strengthenType(thisType.strengthenToNonNull(), thatType.strengthenToNonNull());
}
if (typeOracle.castSucceedsTrivially(thisType, thatType)) {
return thisType;
}
if (typeOracle.castSucceedsTrivially(thatType, thisType)) {
return thatType;
}
// This types are incompatible; ideally this code should not be reached, but there are two
// situations where this happens:
// 1 - unrelated interfaces;
// 2 - unsafe code.
// The original type is preserved in this case.
return thisType;
}
private JReferenceType generalizeUnderlyingTypes(
JReferenceType thisType, JReferenceType thatType) {
// We should not have any analysis properties from this point forward.
assert thisType == thisType.getUnderlyingType() && thatType == thatType.getUnderlyingType();
if (thisType == thatType) {
return thisType;
}
if (thisType instanceof JInterfaceType && thatType instanceof JInterfaceType) {
return generalizeInterfaces((JInterfaceType) thisType, (JInterfaceType) thatType);
}
if (thisType instanceof JArrayType && thatType instanceof JArrayType) {
return generalizeArrayTypes((JArrayType) thisType, (JArrayType) thatType);
}
if (thisType instanceof JClassType && thatType instanceof JClassType) {
return generalizeClasses((JClassType) thisType, (JClassType) thatType);
}
JInterfaceType interfaceType =
thisType instanceof JInterfaceType
? (JInterfaceType) thisType
: (thatType instanceof JInterfaceType ? (JInterfaceType) thatType : null);
JReferenceType nonInterfaceType = interfaceType == thisType ? thatType : thisType;
// See if the class or the array is castable to the interface type.
if (interfaceType != null
&& typeOracle.castSucceedsTrivially(nonInterfaceType, interfaceType)) {
return interfaceType;
}
// unrelated: the best commonality is Object
return typeJavaLangObject;
}
public EnumSet<DispatchType> getDispatchType(JReferenceType type) {
if (!typeOracle.isInstantiatedType(type)) {
return EnumSet.noneOf(DispatchType.class);
}
// Object methods can be dispatched to all four possible classes.
if (type == getTypeJavaLangObject()) {
return EnumSet.allOf(DispatchType.class);
}
EnumSet<DispatchType> dispatchSet = EnumSet.noneOf(DispatchType.class);
DispatchType dispatchType = getRepresentedAsNativeTypesDispatchMap().get(type);
if (dispatchType != null) {
dispatchSet = EnumSet.of(dispatchType);
} else if (typeOracle.isDualJsoInterface(type)) {
// If it is an interface implemented both by JSOs and regular Java Objects;
dispatchSet = EnumSet.of(DispatchType.HAS_JAVA_VIRTUAL_DISPATCH, DispatchType.JSO);
} else if (typeOracle.isSingleJsoImpl(type) || type.isJsoType()) {
// If it is either an interface implemented by JSOs or JavaScriptObject or one of its
// subclasses.
dispatchSet = EnumSet.of(DispatchType.JSO);
}
for (JDeclaredType potentialNativeDispatchType : getRepresentedAsNativeTypes()) {
if (potentialNativeDispatchType == type) {
continue;
}
if (typeOracle.isInstantiatedType(potentialNativeDispatchType)
&& typeOracle.isSuperClassOrInterface(potentialNativeDispatchType, type)) {
dispatchSet.add(getRepresentedAsNativeTypesDispatchMap().get(potentialNativeDispatchType));
dispatchSet.add(DispatchType.HAS_JAVA_VIRTUAL_DISPATCH);
}
}
return dispatchSet;
}
/** Resolve an external reference during AST stitching. */
public void resolve(JReferenceType newType) {
assert newType.replaces(testType);
testType = newType;
}
/**
* Return the least upper bound of two types. That is, the "smallest" type that is a supertype of
* both types. In this lattice there the smallest element might no exist, there might be multiple
* minimal elements neither of which is smaller than the others. E.g.
*
* <p>{@code I J | \ /| | \ / | | x | | / \ | | / \ | A B }
*
* <p>where I and J are interfaces, A and B are classes and both A and B implement I and J. In
* this case both I and J are generalizing the types A and B.
*/
private JReferenceType generalizeTypes(JReferenceType thisType, JReferenceType thatType) {
if (!thisType.canBeNull() && !thatType.canBeNull()) {
// Nullability is an orthogonal property, so remove non_nullability and perform the
// generalization on the nullable types, and if both were NOT nullable then strengthen the
// result to NOT nullable.
//
// not_nullable(A) v not_nullable(B) = not_nullable(A v B)
JReferenceType nulllableGeneralizer =
generalizeTypes(thisType.weakenToNullable(), thatType.weakenToNullable());
return nulllableGeneralizer.strengthenToNonNull();
}
thisType = thisType.weakenToNullable();
thatType = thatType.weakenToNullable();
// From here on nullability does not need to be considered.
// Generalization for exact types is as follows.
// exact(A) v null = exact(A)
// A v null = A
if (thatType.isNullType()) {
return thisType;
}
// null v exact(A) = exact(A)
// null v A = A
if (thisType.isNullType()) {
return thatType;
}
// exact(A) v exact(A) = exact(A)
// A v A = A
if (thisType == thatType) {
return thisType;
}
// exact(A) v exact(B) = A v B
// A v exact(B) = A v B
// exact(A) v B = A v B
// A v B = A v B
return generalizeUnderlyingTypes(thisType.getUnderlyingType(), thatType.getUnderlyingType());
}
/**
* Return the least upper bound of two types. That is, the smallest type that is a supertype of
* both types.
*/
public JReferenceType generalizeTypes(JReferenceType type1, JReferenceType type2) {
if (type1 == type2) {
return type1;
}
if (type1 instanceof JNonNullType && type2 instanceof JNonNullType) {
// Neither can be null.
type1 = type1.getUnderlyingType();
type2 = type2.getUnderlyingType();
return generalizeTypes(type1, type2).getNonNull();
} else if (type1 instanceof JNonNullType) {
// type2 can be null, so the result can be null
type1 = type1.getUnderlyingType();
} else if (type2 instanceof JNonNullType) {
// type1 can be null, so the result can be null
type2 = type2.getUnderlyingType();
}
assert !(type1 instanceof JNonNullType);
assert !(type2 instanceof JNonNullType);
int classify1 = classifyType(type1);
int classify2 = classifyType(type2);
if (classify1 == IS_NULL) {
return type2;
}
if (classify2 == IS_NULL) {
return type1;
}
if (classify1 == classify2) {
// same basic kind of type
if (classify1 == IS_INTERFACE) {
if (typeOracle.canTriviallyCast(type1, type2)) {
return type2;
}
if (typeOracle.canTriviallyCast(type2, type1)) {
return type1;
}
// unrelated
return typeJavaLangObject;
} else if (classify1 == IS_ARRAY) {
JArrayType aType1 = (JArrayType) type1;
JArrayType aType2 = (JArrayType) type2;
int dims1 = aType1.getDims();
int dims2 = aType2.getDims();
int minDims = Math.min(dims1, dims2);
/*
* At a bare minimum, any two arrays generalize to an Object array with
* one less dim than the lesser of the two; that is, int[][][][] and
* String[][][] generalize to Object[][]. If minDims is 1, then they
* just generalize to Object.
*/
JReferenceType minimalGeneralType;
if (minDims > 1) {
minimalGeneralType = getTypeArray(typeJavaLangObject, minDims - 1);
} else {
minimalGeneralType = typeJavaLangObject;
}
if (dims1 == dims2) {
// Try to generalize by leaf types
JType leafType1 = aType1.getLeafType();
JType leafType2 = aType2.getLeafType();
if (!(leafType1 instanceof JReferenceType) || !(leafType2 instanceof JReferenceType)) {
return minimalGeneralType;
}
/*
* Both are reference types; the result is the generalization of the
* leaf types combined with the number of dims; that is, Foo[] and
* Bar[] generalize to X[] where X is the generalization of Foo and
* Bar.
*/
JReferenceType leafRefType1 = (JReferenceType) leafType1;
JReferenceType leafRefType2 = (JReferenceType) leafType2;
/**
* Never generalize arrays to arrays of {@link JNonNullType} as null array initialization
* is not accounted for in {@link TypeTightener}.
*/
JReferenceType leafGeneralization =
generalizeTypes(leafRefType1, leafRefType2).getUnderlyingType();
return getTypeArray(leafGeneralization, dims1);
} else {
// Conflicting number of dims
// int[][] and Object[] generalize to Object[]
JArrayType lesser = dims1 < dims2 ? aType1 : aType2;
if (lesser.getLeafType() == typeJavaLangObject) {
return lesser;
}
// Totally unrelated
return minimalGeneralType;
}
} else {
assert (classify1 == IS_CLASS);
JClassType class1 = (JClassType) type1;
JClassType class2 = (JClassType) type2;
/*
* see how far each type is from object; walk the one who's farther up
* until they're even; then walk them up together until they meet (worst
* case at Object)
*/
int distance1 = countSuperTypes(class1);
int distance2 = countSuperTypes(class2);
for (; distance1 > distance2; --distance1) {
class1 = class1.getSuperClass();
}
for (; distance1 < distance2; --distance2) {
class2 = class2.getSuperClass();
}
while (class1 != class2) {
class1 = class1.getSuperClass();
class2 = class2.getSuperClass();
}
return class1;
}
} else {
// different kinds of types
int lesser = Math.min(classify1, classify2);
int greater = Math.max(classify1, classify2);
JReferenceType tLesser = classify1 < classify2 ? type1 : type2;
JReferenceType tGreater = classify1 > classify2 ? type1 : type2;
if (lesser == IS_INTERFACE && greater == IS_CLASS) {
// just see if the class implements the interface
if (typeOracle.canTriviallyCast(tGreater, tLesser)) {
return tLesser;
}
// unrelated
return typeJavaLangObject;
} else if (greater == IS_ARRAY
&& ((tLesser == typeJavaLangCloneable) || (tLesser == typeJavaIoSerializable))) {
return tLesser;
} else {
// unrelated: the best commonality between an interface and array, or
// between an array and a class is Object
return typeJavaLangObject;
}
}
}
public int addDescriptor(JReferenceType type) {
return addDescriptor(type.getDescriptor());
}