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Vaadin is a web application framework for Rich Internet Applications (RIA).
Vaadin enables easy development and maintenance of fast and
secure rich web
applications with a stunning look and feel and a wide browser support.
It features a server-side architecture with the majority of the logic
running
on the server. Ajax technology is used at the browser-side to ensure a
rich
and interactive user experience.
/*******************************************************************************
* Copyright (c) 2000, 2012 IBM Corporation and others.
* All rights reserved. This program and the accompanying materials
* are made available under the terms of the Eclipse Public License v1.0
* which accompanies this distribution, and is available at
* http://www.eclipse.org/legal/epl-v10.html
*
* Contributors:
* IBM Corporation - initial API and implementation
* Stephan Herrmann - Contributions for
* bug 186342 - [compiler][null] Using annotations for null checking
* bug 365519 - editorial cleanup after bug 186342 and bug 365387
*******************************************************************************/
package org.eclipse.jdt.internal.compiler.lookup;
import org.eclipse.jdt.internal.compiler.ast.ASTNode;
import org.eclipse.jdt.internal.compiler.ast.AbstractMethodDeclaration;
import org.eclipse.jdt.internal.compiler.ast.Argument;
import org.eclipse.jdt.internal.compiler.ast.MethodDeclaration;
import org.eclipse.jdt.internal.compiler.ast.TypeParameter;
import org.eclipse.jdt.internal.compiler.ast.TypeReference;
import org.eclipse.jdt.internal.compiler.classfmt.ClassFileConstants;
import org.eclipse.jdt.internal.compiler.impl.CompilerOptions;
import org.eclipse.jdt.internal.compiler.problem.ProblemSeverities;
import org.eclipse.jdt.internal.compiler.util.HashtableOfObject;
import org.eclipse.jdt.internal.compiler.util.SimpleSet;
class MethodVerifier15 extends MethodVerifier {
MethodVerifier15(LookupEnvironment environment) {
super(environment);
}
boolean areMethodsCompatible(MethodBinding one, MethodBinding two) {
// use the original methods to test compatibility, but do not check visibility, etc
one = one.original();
two = one.findOriginalInheritedMethod(two);
if (two == null)
return false; // method's declaringClass does not inherit from inheritedMethod's
return isParameterSubsignature(one, two);
}
boolean areParametersEqual(MethodBinding one, MethodBinding two) {
TypeBinding[] oneArgs = one.parameters;
TypeBinding[] twoArgs = two.parameters;
if (oneArgs == twoArgs) return true;
int length = oneArgs.length;
if (length != twoArgs.length) return false;
// methods with raw parameters are considered equal to inherited methods
// with parameterized parameters for backwards compatibility, need a more complex check
int i;
foundRAW: for (i = 0; i < length; i++) {
if (!areTypesEqual(oneArgs[i], twoArgs[i])) {
if (oneArgs[i].leafComponentType().isRawType()) {
if (oneArgs[i].dimensions() == twoArgs[i].dimensions() && oneArgs[i].leafComponentType().isEquivalentTo(twoArgs[i].leafComponentType())) {
// raw mode does not apply if the method defines its own type variables
if (one.typeVariables != Binding.NO_TYPE_VARIABLES)
return false;
// one parameter type is raw, hence all parameters types must be raw or non generic
// otherwise we have a mismatch check backwards
for (int j = 0; j < i; j++)
if (oneArgs[j].leafComponentType().isParameterizedTypeWithActualArguments())
return false;
// switch to all raw mode
break foundRAW;
}
}
return false;
}
}
// all raw mode for remaining parameters (if any)
for (i++; i < length; i++) {
if (!areTypesEqual(oneArgs[i], twoArgs[i])) {
if (oneArgs[i].leafComponentType().isRawType())
if (oneArgs[i].dimensions() == twoArgs[i].dimensions() && oneArgs[i].leafComponentType().isEquivalentTo(twoArgs[i].leafComponentType()))
continue;
return false;
} else if (oneArgs[i].leafComponentType().isParameterizedTypeWithActualArguments()) {
return false; // no remaining parameter can be a Parameterized type (if one has been converted then all RAW types must be converted)
}
}
return true;
}
boolean areReturnTypesCompatible(MethodBinding one, MethodBinding two) {
if (one.returnType == two.returnType) return true;
if (this.type.scope.compilerOptions().sourceLevel >= ClassFileConstants.JDK1_5) {
return areReturnTypesCompatible0(one, two);
} else {
return areTypesEqual(one.returnType.erasure(), two.returnType.erasure());
}
}
boolean areTypesEqual(TypeBinding one, TypeBinding two) {
if (one == two) return true;
// https://bugs.eclipse.org/bugs/show_bug.cgi?id=329584
switch(one.kind()) {
case Binding.TYPE:
switch (two.kind()) {
case Binding.PARAMETERIZED_TYPE:
case Binding.RAW_TYPE:
if (one == two.erasure())
return true;
}
break;
case Binding.RAW_TYPE:
case Binding.PARAMETERIZED_TYPE:
switch(two.kind()) {
case Binding.TYPE:
if (one.erasure() == two)
return true;
}
}
// need to consider X> and X extends Object> as the same 'type'
if (one.isParameterizedType() && two.isParameterizedType())
return one.isEquivalentTo(two) && two.isEquivalentTo(one);
// Can skip this since we resolved each method before comparing it, see computeSubstituteMethod()
// if (one instanceof UnresolvedReferenceBinding)
// return ((UnresolvedReferenceBinding) one).resolvedType == two;
// if (two instanceof UnresolvedReferenceBinding)
// return ((UnresolvedReferenceBinding) two).resolvedType == one;
return false; // all other type bindings are identical
}
// Given `overridingMethod' which overrides `inheritedMethod' answer whether some subclass method that
// differs in erasure from overridingMethod could override `inheritedMethod'
protected boolean canOverridingMethodDifferInErasure(MethodBinding overridingMethod, MethodBinding inheritedMethod) {
if (overridingMethod.areParameterErasuresEqual(inheritedMethod))
return false; // no further change in signature is possible due to parameterization.
if (overridingMethod.declaringClass.isRawType())
return false; // no parameterization is happening anyways.
return true;
}
boolean canSkipInheritedMethods() {
if (this.type.superclass() != null)
if (this.type.superclass().isAbstract() || this.type.superclass().isParameterizedType())
return false;
return this.type.superInterfaces() == Binding.NO_SUPERINTERFACES;
}
boolean canSkipInheritedMethods(MethodBinding one, MethodBinding two) {
return two == null // already know one is not null
|| (one.declaringClass == two.declaringClass && !one.declaringClass.isParameterizedType());
}
void checkConcreteInheritedMethod(MethodBinding concreteMethod, MethodBinding[] abstractMethods) {
super.checkConcreteInheritedMethod(concreteMethod, abstractMethods);
boolean analyseNullAnnotations = this.environment.globalOptions.isAnnotationBasedNullAnalysisEnabled;
for (int i = 0, l = abstractMethods.length; i < l; i++) {
MethodBinding abstractMethod = abstractMethods[i];
if (concreteMethod.isVarargs() != abstractMethod.isVarargs())
problemReporter().varargsConflict(concreteMethod, abstractMethod, this.type);
// so the parameters are equal and the return type is compatible b/w the currentMethod & the substituted inheritedMethod
MethodBinding originalInherited = abstractMethod.original();
if (originalInherited.returnType != concreteMethod.returnType)
if (!isAcceptableReturnTypeOverride(concreteMethod, abstractMethod))
problemReporter().unsafeReturnTypeOverride(concreteMethod, originalInherited, this.type);
// check whether bridge method is already defined above for interface methods
// skip generation of bridge method for current class & method if an equivalent
// bridge will be/would have been generated in the context of the super class since
// the bridge itself will be inherited. See https://bugs.eclipse.org/bugs/show_bug.cgi?id=298362
if (originalInherited.declaringClass.isInterface()) {
if ((concreteMethod.declaringClass == this.type.superclass && this.type.superclass.isParameterizedType() && !areMethodsCompatible(concreteMethod, originalInherited))
|| this.type.superclass.erasure().findSuperTypeOriginatingFrom(originalInherited.declaringClass) == null)
this.type.addSyntheticBridgeMethod(originalInherited, concreteMethod.original());
}
if (analyseNullAnnotations && !concreteMethod.isStatic() && !abstractMethod.isStatic())
checkNullSpecInheritance(concreteMethod, abstractMethod);
}
}
void checkForBridgeMethod(MethodBinding currentMethod, MethodBinding inheritedMethod, MethodBinding[] allInheritedMethods) {
if (currentMethod.isVarargs() != inheritedMethod.isVarargs())
problemReporter(currentMethod).varargsConflict(currentMethod, inheritedMethod, this.type);
// so the parameters are equal and the return type is compatible b/w the currentMethod & the substituted inheritedMethod
MethodBinding originalInherited = inheritedMethod.original();
if (originalInherited.returnType != currentMethod.returnType)
if (!isAcceptableReturnTypeOverride(currentMethod, inheritedMethod))
problemReporter(currentMethod).unsafeReturnTypeOverride(currentMethod, originalInherited, this.type);
MethodBinding bridge = this.type.addSyntheticBridgeMethod(originalInherited, currentMethod.original());
if (bridge != null) {
for (int i = 0, l = allInheritedMethods == null ? 0 : allInheritedMethods.length; i < l; i++) {
if (allInheritedMethods[i] != null && detectInheritedNameClash(originalInherited, allInheritedMethods[i].original()))
return;
}
// See if the new bridge clashes with any of the user methods of the class. For this check
// we should check for "method descriptor clash" and not just "method signature clash". Really
// what we are checking is whether there is a contention for the method dispatch table slot.
// See https://bugs.eclipse.org/bugs/show_bug.cgi?id=293615.
MethodBinding[] current = (MethodBinding[]) this.currentMethods.get(bridge.selector);
for (int i = current.length - 1; i >= 0; --i) {
final MethodBinding thisMethod = current[i];
if (thisMethod.areParameterErasuresEqual(bridge) && thisMethod.returnType.erasure() == bridge.returnType.erasure()) {
// use inherited method for problem reporting.
problemReporter(thisMethod).methodNameClash(thisMethod, inheritedMethod.declaringClass.isRawType() ? inheritedMethod : inheritedMethod.original(), ProblemSeverities.Error);
return;
}
}
}
}
void checkForNameClash(MethodBinding currentMethod, MethodBinding inheritedMethod) {
// sent from checkMethods() to compare a current method and an inherited method that are not 'equal'
// error cases:
// abstract class AA { abstract void test(E element); }
// class A extends AA { public void test(Integer i) {} }
// public class B extends A { public void test(Comparable i) {} }
// interface I { void test(E element); }
// class A implements I { public void test(Integer i) {} }
// public class B extends A { public void test(Comparable i) {} }
// abstract class Y implements EqualityComparable, Equivalent {
// public boolean equalTo(Integer other) { return true; }
// }
// interface Equivalent { boolean equalTo(T other); }
// interface EqualityComparable { boolean equalTo(T other); }
// class Y implements EqualityComparable, Equivalent{
// public boolean equalTo(String other) { return true; }
// public boolean equalTo(Object other) { return true; }
// }
// interface Equivalent { boolean equalTo(T other); }
// interface EqualityComparable { boolean equalTo(Object other); }
// class A { void m(T t) {} }
// class B extends A { void m(S t) {}}
// class D extends B { void m(Number t) {} void m(Integer t) {} }
// inheritedMethods does not include I.test since A has a valid implementation
// interface I> { void test(E element); }
// class A implements I { public void test(Integer i) {} }
// class B extends A { public void test(Comparable i) {} }
if (inheritedMethod.isStatic() || currentMethod.isStatic()) {
MethodBinding original = inheritedMethod.original(); // can be the same as inherited
if (this.type.scope.compilerOptions().complianceLevel >= ClassFileConstants.JDK1_7 && currentMethod.areParameterErasuresEqual(original)) {
problemReporter(currentMethod).methodNameClashHidden(currentMethod, inheritedMethod.declaringClass.isRawType() ? inheritedMethod : original);
}
return; // no chance of bridge method's clashing
}
if (!detectNameClash(currentMethod, inheritedMethod, false)) { // check up the hierarchy for skipped inherited methods
TypeBinding[] currentParams = currentMethod.parameters;
TypeBinding[] inheritedParams = inheritedMethod.parameters;
int length = currentParams.length;
if (length != inheritedParams.length) return; // no match
for (int i = 0; i < length; i++)
if (currentParams[i] != inheritedParams[i])
if (currentParams[i].isBaseType() != inheritedParams[i].isBaseType() || !inheritedParams[i].isCompatibleWith(currentParams[i]))
return; // no chance that another inherited method's bridge method can collide
ReferenceBinding[] interfacesToVisit = null;
int nextPosition = 0;
ReferenceBinding superType = inheritedMethod.declaringClass;
ReferenceBinding[] itsInterfaces = superType.superInterfaces();
if (itsInterfaces != Binding.NO_SUPERINTERFACES) {
nextPosition = itsInterfaces.length;
interfacesToVisit = itsInterfaces;
}
superType = superType.superclass(); // now start with its superclass
while (superType != null && superType.isValidBinding()) {
MethodBinding[] methods = superType.getMethods(currentMethod.selector);
for (int m = 0, n = methods.length; m < n; m++) {
MethodBinding substitute = computeSubstituteMethod(methods[m], currentMethod);
if (substitute != null && !isSubstituteParameterSubsignature(currentMethod, substitute) && detectNameClash(currentMethod, substitute, true))
return;
}
if ((itsInterfaces = superType.superInterfaces()) != Binding.NO_SUPERINTERFACES) {
if (interfacesToVisit == null) {
interfacesToVisit = itsInterfaces;
nextPosition = interfacesToVisit.length;
} else {
int itsLength = itsInterfaces.length;
if (nextPosition + itsLength >= interfacesToVisit.length)
System.arraycopy(interfacesToVisit, 0, interfacesToVisit = new ReferenceBinding[nextPosition + itsLength + 5], 0, nextPosition);
nextInterface : for (int a = 0; a < itsLength; a++) {
ReferenceBinding next = itsInterfaces[a];
for (int b = 0; b < nextPosition; b++)
if (next == interfacesToVisit[b]) continue nextInterface;
interfacesToVisit[nextPosition++] = next;
}
}
}
superType = superType.superclass();
}
for (int i = 0; i < nextPosition; i++) {
superType = interfacesToVisit[i];
if (superType.isValidBinding()) {
MethodBinding[] methods = superType.getMethods(currentMethod.selector);
for (int m = 0, n = methods.length; m < n; m++){
MethodBinding substitute = computeSubstituteMethod(methods[m], currentMethod);
if (substitute != null && !isSubstituteParameterSubsignature(currentMethod, substitute) && detectNameClash(currentMethod, substitute, true))
return;
}
if ((itsInterfaces = superType.superInterfaces()) != Binding.NO_SUPERINTERFACES) {
int itsLength = itsInterfaces.length;
if (nextPosition + itsLength >= interfacesToVisit.length)
System.arraycopy(interfacesToVisit, 0, interfacesToVisit = new ReferenceBinding[nextPosition + itsLength + 5], 0, nextPosition);
nextInterface : for (int a = 0; a < itsLength; a++) {
ReferenceBinding next = itsInterfaces[a];
for (int b = 0; b < nextPosition; b++)
if (next == interfacesToVisit[b]) continue nextInterface;
interfacesToVisit[nextPosition++] = next;
}
}
}
}
}
}
void checkInheritedMethods(MethodBinding inheritedMethod, MethodBinding otherInheritedMethod) {
// the 2 inherited methods clash because of a parameterized type overrides a raw type
// interface I { void foo(A a); }
// class Y { void foo(A a) {} }
// abstract class X extends Y implements I { }
// class A {}
// in this case the 2 inherited methods clash because of type variables
// interface I { void foo(T t); }
// class Y { void foo(T t) {} }
// abstract class X extends Y implements I {}
if (inheritedMethod.isStatic()) return;
if (this.environment.globalOptions.complianceLevel < ClassFileConstants.JDK1_7 && inheritedMethod.declaringClass.isInterface())
return; // JDK7 checks for name clashes in interface inheritance, while JDK6 and below don't. See https://bugs.eclipse.org/bugs/show_bug.cgi?id=354229
detectInheritedNameClash(inheritedMethod.original(), otherInheritedMethod.original());
}
// 8.4.8.4
void checkInheritedMethods(MethodBinding[] methods, int length) {
boolean continueInvestigation = true;
MethodBinding concreteMethod = null;
for (int i = 0; i < length; i++) {
if (!methods[i].isAbstract()) {
if (concreteMethod != null) {
problemReporter().duplicateInheritedMethods(this.type, concreteMethod, methods[i]);
continueInvestigation = false;
}
concreteMethod = methods[i];
}
}
if (continueInvestigation) {
super.checkInheritedMethods(methods, length);
}
}
boolean checkInheritedReturnTypes(MethodBinding method, MethodBinding otherMethod) {
if (areReturnTypesCompatible(method, otherMethod)) return true;
/* We used to have some checks here to see if we would have already blamed the super type and if so avoid blaming
the current type again. I have gotten rid of them as they in fact short circuit error reporting in cases where
they should not. This means that occasionally we would report the error twice - the diagnostics is valid however,
albeit arguably redundant. See https://bugs.eclipse.org/bugs/show_bug.cgi?id=334313. For an example of a test
where we do this extra reporting see org.eclipse.jdt.core.tests.compiler.regression.MethodVerifyTest.test159()
*/
// check to see if this is just a warning, if so report it & skip to next method
if (isUnsafeReturnTypeOverride(method, otherMethod)) {
if (!method.declaringClass.implementsInterface(otherMethod.declaringClass, false))
problemReporter(method).unsafeReturnTypeOverride(method, otherMethod, this.type);
return true;
}
return false;
}
void checkAgainstInheritedMethods(MethodBinding currentMethod, MethodBinding[] methods, int length, MethodBinding[] allInheritedMethods)
{
super.checkAgainstInheritedMethods(currentMethod, methods, length, allInheritedMethods);
if (this.environment.globalOptions.isAnnotationBasedNullAnalysisEnabled) {
for (int i = length; --i >= 0;)
if (!currentMethod.isStatic() && !methods[i].isStatic())
checkNullSpecInheritance(currentMethod, methods[i]);
}
}
void checkNullSpecInheritance(MethodBinding currentMethod, MethodBinding inheritedMethod) {
// precondition: caller has checked whether annotation-based null analysis is enabled.
long inheritedBits = inheritedMethod.tagBits;
long currentBits = currentMethod.tagBits;
AbstractMethodDeclaration srcMethod = null;
if (this.type.equals(currentMethod.declaringClass)) // is currentMethod from the current type?
srcMethod = currentMethod.sourceMethod();
// return type:
if ((inheritedBits & TagBits.AnnotationNonNull) != 0) {
long currentNullBits = currentBits & (TagBits.AnnotationNonNull|TagBits.AnnotationNullable);
if (currentNullBits != TagBits.AnnotationNonNull) {
if (srcMethod != null) {
this.type.scope.problemReporter().illegalReturnRedefinition(srcMethod, inheritedMethod,
this.environment.getNonNullAnnotationName());
} else {
this.type.scope.problemReporter().cannotImplementIncompatibleNullness(currentMethod, inheritedMethod);
return;
}
}
}
// parameters:
Argument[] currentArguments = srcMethod == null ? null : srcMethod.arguments;
if (inheritedMethod.parameterNonNullness != null) {
// inherited method has null-annotations, check compatibility:
int length = inheritedMethod.parameterNonNullness.length;
for (int i = 0; i < length; i++) {
Argument currentArgument = currentArguments == null ? null : currentArguments[i];
Boolean inheritedNonNullNess = inheritedMethod.parameterNonNullness[i];
Boolean currentNonNullNess = (currentMethod.parameterNonNullness == null)
? null : currentMethod.parameterNonNullness[i];
if (inheritedNonNullNess != null) { // super has a null annotation
if (currentNonNullNess == null) { // current parameter lacks null annotation
boolean needNonNull = false;
char[][] annotationName;
if (inheritedNonNullNess == Boolean.TRUE) {
needNonNull = true;
annotationName = this.environment.getNonNullAnnotationName();
} else {
annotationName = this.environment.getNullableAnnotationName();
}
if (currentArgument != null) {
this.type.scope.problemReporter().parameterLackingNullAnnotation(
currentArgument,
inheritedMethod.declaringClass,
needNonNull,
annotationName);
continue;
} else {
this.type.scope.problemReporter().cannotImplementIncompatibleNullness(currentMethod, inheritedMethod);
break;
}
}
}
if (inheritedNonNullNess != Boolean.TRUE) { // super parameter is not restricted to @NonNull
if (currentNonNullNess == Boolean.TRUE) { // current parameter is restricted to @NonNull
if (currentArgument != null)
this.type.scope.problemReporter().illegalRedefinitionToNonNullParameter(
currentArgument,
inheritedMethod.declaringClass,
inheritedNonNullNess == null
? null
: this.environment.getNullableAnnotationName());
else
this.type.scope.problemReporter().cannotImplementIncompatibleNullness(currentMethod, inheritedMethod);
}
}
}
} else if (currentMethod.parameterNonNullness != null) {
// super method has no annotations but current has
for (int i = 0; i < currentMethod.parameterNonNullness.length; i++) {
if (currentMethod.parameterNonNullness[i] == Boolean.TRUE) { // tightening from unconstrained to @NonNull
if (currentArguments != null) {
this.type.scope.problemReporter().illegalRedefinitionToNonNullParameter(
currentArguments[i],
inheritedMethod.declaringClass,
null);
} else {
this.type.scope.problemReporter().cannotImplementIncompatibleNullness(currentMethod, inheritedMethod);
break;
}
}
}
}
}
void reportRawReferences() {
CompilerOptions compilerOptions = this.type.scope.compilerOptions();
if (compilerOptions.sourceLevel < ClassFileConstants.JDK1_5 // shouldn't whine at all
|| compilerOptions.reportUnavoidableGenericTypeProblems) { // must have already whined
return;
}
/* Code below is only for a method that does not override/implement a super type method. If it were to,
it would have been handled in checkAgainstInheritedMethods.
*/
Object [] methodArray = this.currentMethods.valueTable;
for (int s = methodArray.length; --s >= 0;) {
if (methodArray[s] == null) continue;
MethodBinding[] current = (MethodBinding[]) methodArray[s];
for (int i = 0, length = current.length; i < length; i++) {
MethodBinding currentMethod = current[i];
if ((currentMethod.modifiers & (ExtraCompilerModifiers.AccImplementing | ExtraCompilerModifiers.AccOverriding)) == 0) {
AbstractMethodDeclaration methodDecl = currentMethod.sourceMethod();
if (methodDecl == null) return;
TypeBinding [] parameterTypes = currentMethod.parameters;
Argument[] arguments = methodDecl.arguments;
for (int j = 0, size = currentMethod.parameters.length; j < size; j++) {
TypeBinding parameterType = parameterTypes[j];
Argument arg = arguments[j];
if (parameterType.leafComponentType().isRawType()
&& compilerOptions.getSeverity(CompilerOptions.RawTypeReference) != ProblemSeverities.Ignore
&& (arg.type.bits & ASTNode.IgnoreRawTypeCheck) == 0) {
methodDecl.scope.problemReporter().rawTypeReference(arg.type, parameterType);
}
}
if (!methodDecl.isConstructor() && methodDecl instanceof MethodDeclaration) {
TypeReference returnType = ((MethodDeclaration) methodDecl).returnType;
TypeBinding methodType = currentMethod.returnType;
if (returnType != null) {
if (methodType.leafComponentType().isRawType()
&& compilerOptions.getSeverity(CompilerOptions.RawTypeReference) != ProblemSeverities.Ignore
&& (returnType.bits & ASTNode.IgnoreRawTypeCheck) == 0) {
methodDecl.scope.problemReporter().rawTypeReference(returnType, methodType);
}
}
}
}
}
}
}
public void reportRawReferences(MethodBinding currentMethod, MethodBinding inheritedMethod) {
CompilerOptions compilerOptions = this.type.scope.compilerOptions();
if (compilerOptions.sourceLevel < ClassFileConstants.JDK1_5 // shouldn't whine at all
|| compilerOptions.reportUnavoidableGenericTypeProblems) { // must have already whined
return;
}
AbstractMethodDeclaration methodDecl = currentMethod.sourceMethod();
if (methodDecl == null) return;
TypeBinding [] parameterTypes = currentMethod.parameters;
TypeBinding [] inheritedParameterTypes = inheritedMethod.parameters;
Argument[] arguments = methodDecl.arguments;
for (int j = 0, size = currentMethod.parameters.length; j < size; j++) {
TypeBinding parameterType = parameterTypes[j];
TypeBinding inheritedParameterType = inheritedParameterTypes[j];
Argument arg = arguments[j];
if (parameterType.leafComponentType().isRawType()) {
if (inheritedParameterType.leafComponentType().isRawType()) {
arg.binding.tagBits |= TagBits.ForcedToBeRawType;
} else {
if (compilerOptions.getSeverity(CompilerOptions.RawTypeReference) != ProblemSeverities.Ignore
&& (arg.type.bits & ASTNode.IgnoreRawTypeCheck) == 0) {
methodDecl.scope.problemReporter().rawTypeReference(arg.type, parameterType);
}
}
}
}
TypeReference returnType = null;
if (!methodDecl.isConstructor() && methodDecl instanceof MethodDeclaration && (returnType = ((MethodDeclaration) methodDecl).returnType) != null) {
final TypeBinding inheritedMethodType = inheritedMethod.returnType;
final TypeBinding methodType = currentMethod.returnType;
if (methodType.leafComponentType().isRawType()) {
if (inheritedMethodType.leafComponentType().isRawType()) {
//
} else {
if ((returnType.bits & ASTNode.IgnoreRawTypeCheck) == 0
&& compilerOptions.getSeverity(CompilerOptions.RawTypeReference) != ProblemSeverities.Ignore) {
methodDecl.scope.problemReporter().rawTypeReference(returnType, methodType);
}
}
}
}
}
void checkMethods() {
boolean mustImplementAbstractMethods = mustImplementAbstractMethods();
boolean skipInheritedMethods = mustImplementAbstractMethods && canSkipInheritedMethods(); // have a single concrete superclass so only check overridden methods
boolean isOrEnclosedByPrivateType = this.type.isOrEnclosedByPrivateType();
char[][] methodSelectors = this.inheritedMethods.keyTable;
nextSelector : for (int s = methodSelectors.length; --s >= 0;) {
if (methodSelectors[s] == null) continue nextSelector;
MethodBinding[] current = (MethodBinding[]) this.currentMethods.get(methodSelectors[s]);
MethodBinding[] inherited = (MethodBinding[]) this.inheritedMethods.valueTable[s];
// https://bugs.eclipse.org/bugs/show_bug.cgi?id=296660, if current type is exposed,
// inherited methods of super classes are too. current != null case handled below.
if (current == null && !isOrEnclosedByPrivateType) {
int length = inherited.length;
for (int i = 0; i < length; i++){
inherited[i].original().modifiers |= ExtraCompilerModifiers.AccLocallyUsed;
}
}
if (current == null && this.type.isPublic()) {
int length = inherited.length;
for (int i = 0; i < length; i++) {
MethodBinding inheritedMethod = inherited[i];
if (inheritedMethod.isPublic() && !inheritedMethod.declaringClass.isPublic())
this.type.addSyntheticBridgeMethod(inheritedMethod.original());
}
}
if (current == null && skipInheritedMethods)
continue nextSelector;
if (inherited.length == 1 && current == null) { // handle the common case
if (mustImplementAbstractMethods && inherited[0].isAbstract())
checkAbstractMethod(inherited[0]);
continue nextSelector;
}
int index = -1;
int inheritedLength = inherited.length;
MethodBinding[] matchingInherited = new MethodBinding[inheritedLength];
MethodBinding[] foundMatch = new MethodBinding[inheritedLength]; // null is no match, otherwise value is matching currentMethod
if (current != null) {
for (int i = 0, length1 = current.length; i < length1; i++) {
MethodBinding currentMethod = current[i];
MethodBinding[] nonMatchingInherited = null;
for (int j = 0; j < inheritedLength; j++) {
MethodBinding inheritedMethod = computeSubstituteMethod(inherited[j], currentMethod);
if (inheritedMethod != null) {
if (foundMatch[j] == null && isSubstituteParameterSubsignature(currentMethod, inheritedMethod)) {
matchingInherited[++index] = inheritedMethod;
foundMatch[j] = currentMethod;
} else {
// best place to check each currentMethod against each non-matching inheritedMethod
checkForNameClash(currentMethod, inheritedMethod);
if (inheritedLength > 1) {
if (nonMatchingInherited == null)
nonMatchingInherited = new MethodBinding[inheritedLength];
nonMatchingInherited[j] = inheritedMethod;
}
}
}
}
if (index >= 0) {
// see addtional comments in https://bugs.eclipse.org/bugs/show_bug.cgi?id=122881
// if (index > 0 && currentMethod.declaringClass.isInterface()) // only check when inherited methods are from interfaces
// checkInheritedReturnTypes(matchingInherited, index + 1);
checkAgainstInheritedMethods(currentMethod, matchingInherited, index + 1, nonMatchingInherited); // pass in the length of matching
while (index >= 0) matchingInherited[index--] = null; // clear the contents of the matching methods
}
}
}
// skip tracks which inherited methods have matched other inherited methods
// either because they match the same currentMethod or match each other
boolean[] skip = new boolean[inheritedLength];
for (int i = 0; i < inheritedLength; i++) {
MethodBinding matchMethod = foundMatch[i];
if (matchMethod == null && current != null && this.type.isPublic()) { // current == null case handled already.
MethodBinding inheritedMethod = inherited[i];
if (inheritedMethod.isPublic() && !inheritedMethod.declaringClass.isPublic()) {
this.type.addSyntheticBridgeMethod(inheritedMethod.original());
}
}
// https://bugs.eclipse.org/bugs/show_bug.cgi?id=296660, if current type is exposed,
// inherited methods of super classes are too. current == null case handled already.
if (!isOrEnclosedByPrivateType && matchMethod == null && current != null) {
inherited[i].original().modifiers |= ExtraCompilerModifiers.AccLocallyUsed;
}
if (skip[i]) continue;
MethodBinding inheritedMethod = inherited[i];
if (matchMethod == null)
matchingInherited[++index] = inheritedMethod;
for (int j = i + 1; j < inheritedLength; j++) {
MethodBinding otherInheritedMethod = inherited[j];
if (matchMethod == foundMatch[j] && matchMethod != null)
continue; // both inherited methods matched the same currentMethod
if (canSkipInheritedMethods(inheritedMethod, otherInheritedMethod))
continue;
// Skip the otherInheritedMethod if it is completely replaced by inheritedMethod
// This elimination used to happen rather eagerly in computeInheritedMethods step
// itself earlier. (https://bugs.eclipse.org/bugs/show_bug.cgi?id=302358)
if (inheritedMethod.declaringClass != otherInheritedMethod.declaringClass) {
if (otherInheritedMethod.declaringClass.isInterface()) {
if (isInterfaceMethodImplemented(otherInheritedMethod, inheritedMethod, otherInheritedMethod.declaringClass)) {
skip[j] = true;
continue;
}
} else if (areMethodsCompatible(inheritedMethod, otherInheritedMethod)) {
skip[j] = true;
continue;
}
}
otherInheritedMethod = computeSubstituteMethod(otherInheritedMethod, inheritedMethod);
if (otherInheritedMethod != null) {
if (isSubstituteParameterSubsignature(inheritedMethod, otherInheritedMethod)) {
if (index == -1)
matchingInherited[++index] = inheritedMethod;
if (foundMatch[j] == null)
matchingInherited[++index] = otherInheritedMethod;
skip[j] = true;
} else if (matchMethod == null && foundMatch[j] == null) {
checkInheritedMethods(inheritedMethod, otherInheritedMethod);
}
}
}
if (index == -1) continue;
if (index > 0)
checkInheritedMethods(matchingInherited, index + 1); // pass in the length of matching
else if (mustImplementAbstractMethods && matchingInherited[0].isAbstract() && matchMethod == null)
checkAbstractMethod(matchingInherited[0]);
while (index >= 0) matchingInherited[index--] = null; // clear the previous contents of the matching methods
}
}
}
void checkTypeVariableMethods(TypeParameter typeParameter) {
char[][] methodSelectors = this.inheritedMethods.keyTable;
nextSelector : for (int s = methodSelectors.length; --s >= 0;) {
if (methodSelectors[s] == null) continue nextSelector;
MethodBinding[] inherited = (MethodBinding[]) this.inheritedMethods.valueTable[s];
if (inherited.length == 1) continue nextSelector;
int index = -1;
MethodBinding[] matchingInherited = new MethodBinding[inherited.length];
for (int i = 0, length = inherited.length; i < length; i++) {
while (index >= 0) matchingInherited[index--] = null; // clear the previous contents of the matching methods
MethodBinding inheritedMethod = inherited[i];
if (inheritedMethod != null) {
matchingInherited[++index] = inheritedMethod;
for (int j = i + 1; j < length; j++) {
MethodBinding otherInheritedMethod = inherited[j];
if (canSkipInheritedMethods(inheritedMethod, otherInheritedMethod))
continue;
otherInheritedMethod = computeSubstituteMethod(otherInheritedMethod, inheritedMethod);
if (otherInheritedMethod != null && isSubstituteParameterSubsignature(inheritedMethod, otherInheritedMethod)) {
matchingInherited[++index] = otherInheritedMethod;
inherited[j] = null; // do not want to find it again
}
}
}
if (index > 0) {
MethodBinding first = matchingInherited[0];
int count = index + 1;
while (--count > 0) {
MethodBinding match = matchingInherited[count];
// https://bugs.eclipse.org/bugs/show_bug.cgi?id=314556
MethodBinding interfaceMethod = null, implementation = null;
if (first.declaringClass.isInterface()) {
interfaceMethod = first;
} else if (first.declaringClass.isClass()) {
implementation = first;
}
if (match.declaringClass.isInterface()) {
interfaceMethod = match;
} else if (match.declaringClass.isClass()) {
implementation = match;
}
if (interfaceMethod != null && implementation != null && !isAsVisible(implementation, interfaceMethod))
problemReporter().inheritedMethodReducesVisibility(typeParameter, implementation, new MethodBinding [] {interfaceMethod});
if (areReturnTypesCompatible(first, match)) continue;
// unrelated interfaces - check to see if return types are compatible
if (first.declaringClass.isInterface() && match.declaringClass.isInterface() && areReturnTypesCompatible(match, first))
continue;
break;
}
if (count > 0) { // All inherited methods do NOT have the same vmSignature
problemReporter().inheritedMethodsHaveIncompatibleReturnTypes(typeParameter, matchingInherited, index + 1);
continue nextSelector;
}
}
}
}
}
MethodBinding computeSubstituteMethod(MethodBinding inheritedMethod, MethodBinding currentMethod) {
if (inheritedMethod == null) return null;
if (currentMethod.parameters.length != inheritedMethod.parameters.length) return null; // no match
// due to hierarchy & compatibility checks, we need to ensure these 2 methods are resolved
if (currentMethod.declaringClass instanceof BinaryTypeBinding)
((BinaryTypeBinding) currentMethod.declaringClass).resolveTypesFor(currentMethod);
if (inheritedMethod.declaringClass instanceof BinaryTypeBinding)
((BinaryTypeBinding) inheritedMethod.declaringClass).resolveTypesFor(inheritedMethod);
TypeVariableBinding[] inheritedTypeVariables = inheritedMethod.typeVariables;
int inheritedLength = inheritedTypeVariables.length;
if (inheritedLength == 0) return inheritedMethod; // no substitution needed
TypeVariableBinding[] typeVariables = currentMethod.typeVariables;
int length = typeVariables.length;
if (length == 0)
return inheritedMethod.asRawMethod(this.environment);
if (length != inheritedLength)
return inheritedMethod; // no match JLS 8.4.2
// interface I { void foo(T t); }
// class X implements I { public void foo(T t) {} }
// for the above case, we do not want to answer the substitute method since its not a match
TypeBinding[] arguments = new TypeBinding[length];
System.arraycopy(typeVariables, 0, arguments, 0, length);
ParameterizedGenericMethodBinding substitute =
this.environment.createParameterizedGenericMethod(inheritedMethod, arguments);
for (int i = 0; i < inheritedLength; i++) {
TypeVariableBinding inheritedTypeVariable = inheritedTypeVariables[i];
TypeBinding argument = arguments[i];
if (argument instanceof TypeVariableBinding) {
TypeVariableBinding typeVariable = (TypeVariableBinding) argument;
if (typeVariable.firstBound == inheritedTypeVariable.firstBound) {
if (typeVariable.firstBound == null)
continue; // both are null
} else if (typeVariable.firstBound != null && inheritedTypeVariable.firstBound != null) {
if (typeVariable.firstBound.isClass() != inheritedTypeVariable.firstBound.isClass())
return inheritedMethod; // not a match
}
if (Scope.substitute(substitute, inheritedTypeVariable.superclass) != typeVariable.superclass)
return inheritedMethod; // not a match
int interfaceLength = inheritedTypeVariable.superInterfaces.length;
ReferenceBinding[] interfaces = typeVariable.superInterfaces;
if (interfaceLength != interfaces.length)
return inheritedMethod; // not a match
// TODO (kent) another place where we expect the superinterfaces to be in the exact same order
next : for (int j = 0; j < interfaceLength; j++) {
TypeBinding superType = Scope.substitute(substitute, inheritedTypeVariable.superInterfaces[j]);
for (int k = 0; k < interfaceLength; k++)
if (superType == interfaces[k])
continue next;
return inheritedMethod; // not a match
}
} else if (inheritedTypeVariable.boundCheck(substitute, argument) != TypeConstants.OK) {
return inheritedMethod;
}
}
return substitute;
}
boolean detectInheritedNameClash(MethodBinding inherited, MethodBinding otherInherited) {
if (!inherited.areParameterErasuresEqual(otherInherited))
return false;
// https://bugs.eclipse.org/bugs/show_bug.cgi?id=322001
// https://bugs.eclipse.org/bugs/show_bug.cgi?id=323693
// When reporting a name clash between two inherited methods, we should not look for a
// signature clash, but instead should be looking for method descriptor clash.
if (inherited.returnType.erasure() != otherInherited.returnType.erasure())
return false;
// skip it if otherInherited is defined by a subtype of inherited's declaringClass or vice versa.
// avoid being order sensitive and check with the roles reversed also.
if (inherited.declaringClass.erasure() != otherInherited.declaringClass.erasure()) {
if (inherited.declaringClass.findSuperTypeOriginatingFrom(otherInherited.declaringClass) != null)
return false;
if (otherInherited.declaringClass.findSuperTypeOriginatingFrom(inherited.declaringClass) != null)
return false;
}
problemReporter().inheritedMethodsHaveNameClash(this.type, inherited, otherInherited);
return true;
}
boolean detectNameClash(MethodBinding current, MethodBinding inherited, boolean treatAsSynthetic) {
MethodBinding methodToCheck = inherited;
MethodBinding original = methodToCheck.original(); // can be the same as inherited
if (!current.areParameterErasuresEqual(original))
return false;
int severity = ProblemSeverities.Error;
if (this.environment.globalOptions.complianceLevel == ClassFileConstants.JDK1_6) {
// for 1.6 return types also need to be checked
// https://bugs.eclipse.org/bugs/show_bug.cgi?id=317719
if (current.returnType.erasure() != original.returnType.erasure())
severity = ProblemSeverities.Warning;
}
if (!treatAsSynthetic) {
// For a user method, see if current class overrides the inherited method. If it does,
// then any grievance we may have ought to be against the current class's method and
// NOT against any super implementations. https://bugs.eclipse.org/bugs/show_bug.cgi?id=293615
// https://bugs.eclipse.org/bugs/show_bug.cgi?id=315978 : we now defer this rather expensive
// check to just before reporting (the incorrect) name clash. In the event there is no name
// clash to report to begin with (the common case), no penalty needs to be paid.
MethodBinding[] currentNamesakes = (MethodBinding[]) this.currentMethods.get(inherited.selector);
if (currentNamesakes.length > 1) { // we know it ought to at least one and that current is NOT the override
for (int i = 0, length = currentNamesakes.length; i < length; i++) {
MethodBinding currentMethod = currentNamesakes[i];
if (currentMethod != current && doesMethodOverride(currentMethod, inherited)) {
methodToCheck = currentMethod;
break;
}
}
}
}
original = methodToCheck.original(); // can be the same as inherited
if (!current.areParameterErasuresEqual(original))
return false;
original = inherited.original(); // For error reporting use, inherited.original()
problemReporter(current).methodNameClash(current, inherited.declaringClass.isRawType() ? inherited : original, severity);
if (severity == ProblemSeverities.Warning) return false;
return true;
}
public boolean doesMethodOverride(MethodBinding method, MethodBinding inheritedMethod) {
return couldMethodOverride(method, inheritedMethod) && areMethodsCompatible(method, inheritedMethod);
}
boolean doTypeVariablesClash(MethodBinding one, MethodBinding substituteTwo) {
// one has type variables and substituteTwo did not pass bounds check in computeSubstituteMethod()
return one.typeVariables != Binding.NO_TYPE_VARIABLES && !(substituteTwo instanceof ParameterizedGenericMethodBinding);
}
SimpleSet findSuperinterfaceCollisions(ReferenceBinding superclass, ReferenceBinding[] superInterfaces) {
ReferenceBinding[] interfacesToVisit = null;
int nextPosition = 0;
ReferenceBinding[] itsInterfaces = superInterfaces;
if (itsInterfaces != Binding.NO_SUPERINTERFACES) {
nextPosition = itsInterfaces.length;
interfacesToVisit = itsInterfaces;
}
boolean isInconsistent = this.type.isHierarchyInconsistent();
ReferenceBinding superType = superclass;
while (superType != null && superType.isValidBinding()) {
isInconsistent |= superType.isHierarchyInconsistent();
if ((itsInterfaces = superType.superInterfaces()) != Binding.NO_SUPERINTERFACES) {
if (interfacesToVisit == null) {
interfacesToVisit = itsInterfaces;
nextPosition = interfacesToVisit.length;
} else {
int itsLength = itsInterfaces.length;
if (nextPosition + itsLength >= interfacesToVisit.length)
System.arraycopy(interfacesToVisit, 0, interfacesToVisit = new ReferenceBinding[nextPosition + itsLength + 5], 0, nextPosition);
nextInterface : for (int a = 0; a < itsLength; a++) {
ReferenceBinding next = itsInterfaces[a];
for (int b = 0; b < nextPosition; b++)
if (next == interfacesToVisit[b]) continue nextInterface;
interfacesToVisit[nextPosition++] = next;
}
}
}
superType = superType.superclass();
}
for (int i = 0; i < nextPosition; i++) {
superType = interfacesToVisit[i];
if (superType.isValidBinding()) {
isInconsistent |= superType.isHierarchyInconsistent();
if ((itsInterfaces = superType.superInterfaces()) != Binding.NO_SUPERINTERFACES) {
int itsLength = itsInterfaces.length;
if (nextPosition + itsLength >= interfacesToVisit.length)
System.arraycopy(interfacesToVisit, 0, interfacesToVisit = new ReferenceBinding[nextPosition + itsLength + 5], 0, nextPosition);
nextInterface : for (int a = 0; a < itsLength; a++) {
ReferenceBinding next = itsInterfaces[a];
for (int b = 0; b < nextPosition; b++)
if (next == interfacesToVisit[b]) continue nextInterface;
interfacesToVisit[nextPosition++] = next;
}
}
}
}
if (!isInconsistent) return null; // hierarchy is consistent so no collisions are possible
SimpleSet copy = null;
for (int i = 0; i < nextPosition; i++) {
ReferenceBinding current = interfacesToVisit[i];
if (current.isValidBinding()) {
TypeBinding erasure = current.erasure();
for (int j = i + 1; j < nextPosition; j++) {
ReferenceBinding next = interfacesToVisit[j];
if (next.isValidBinding() && next.erasure() == erasure) {
if (copy == null)
copy = new SimpleSet(nextPosition);
copy.add(interfacesToVisit[i]);
copy.add(interfacesToVisit[j]);
}
}
}
}
return copy;
}
boolean hasGenericParameter(MethodBinding method) {
if (method.genericSignature() == null) return false;
// may be only the return type that is generic, need to check parameters
TypeBinding[] params = method.parameters;
for (int i = 0, l = params.length; i < l; i++) {
TypeBinding param = params[i].leafComponentType();
if (param instanceof ReferenceBinding) {
int modifiers = ((ReferenceBinding) param).modifiers;
if ((modifiers & ExtraCompilerModifiers.AccGenericSignature) != 0)
return true;
}
}
return false;
}
boolean isAcceptableReturnTypeOverride(MethodBinding currentMethod, MethodBinding inheritedMethod) {
// called when currentMethod's return type is compatible with inheritedMethod's return type
if (inheritedMethod.declaringClass.isRawType())
return true; // since the inheritedMethod comes from a raw type, the return type is always acceptable
MethodBinding originalInherited = inheritedMethod.original();
TypeBinding originalInheritedReturnType = originalInherited.returnType.leafComponentType();
if (originalInheritedReturnType.isParameterizedTypeWithActualArguments())
return !currentMethod.returnType.leafComponentType().isRawType(); // raw types issue a warning if inherited is parameterized
TypeBinding currentReturnType = currentMethod.returnType.leafComponentType();
switch (currentReturnType.kind()) {
case Binding.TYPE_PARAMETER :
if (currentReturnType == inheritedMethod.returnType.leafComponentType())
return true;
//$FALL-THROUGH$
default :
if (originalInheritedReturnType.isTypeVariable())
if (((TypeVariableBinding) originalInheritedReturnType).declaringElement == originalInherited)
return false;
return true;
}
}
// caveat: returns false if a method is implemented that needs a bridge method
boolean isInterfaceMethodImplemented(MethodBinding inheritedMethod, MethodBinding existingMethod, ReferenceBinding superType) {
if (inheritedMethod.original() != inheritedMethod && existingMethod.declaringClass.isInterface())
return false; // must hold onto ParameterizedMethod to see if a bridge method is necessary
inheritedMethod = computeSubstituteMethod(inheritedMethod, existingMethod);
return inheritedMethod != null
&& inheritedMethod.returnType == existingMethod.returnType // keep around to produce bridge methods
&& doesMethodOverride(existingMethod, inheritedMethod);
}
public boolean isMethodSubsignature(MethodBinding method, MethodBinding inheritedMethod) {
if (!org.eclipse.jdt.core.compiler.CharOperation.equals(method.selector, inheritedMethod.selector))
return false;
// need to switch back to the original if the method is from a ParameterizedType
if (method.declaringClass.isParameterizedType())
method = method.original();
MethodBinding inheritedOriginal = method.findOriginalInheritedMethod(inheritedMethod);
return isParameterSubsignature(method, inheritedOriginal == null ? inheritedMethod : inheritedOriginal);
}
boolean isParameterSubsignature(MethodBinding method, MethodBinding inheritedMethod) {
MethodBinding substitute = computeSubstituteMethod(inheritedMethod, method);
return substitute != null && isSubstituteParameterSubsignature(method, substitute);
}
// if method "overrides" substituteMethod then we can skip over substituteMethod while resolving a message send
// if it does not then a name clash error is likely
boolean isSubstituteParameterSubsignature(MethodBinding method, MethodBinding substituteMethod) {
if (!areParametersEqual(method, substituteMethod)) {
// method can still override substituteMethod in cases like :
// void c(U u) {}
// @Override void c(Number n) {}
// but method cannot have a "generic-enabled" parameter type
if (substituteMethod.hasSubstitutedParameters() && method.areParameterErasuresEqual(substituteMethod))
return method.typeVariables == Binding.NO_TYPE_VARIABLES && !hasGenericParameter(method);
// see https://bugs.eclipse.org/bugs/show_bug.cgi?id=279836
if (method.declaringClass.isRawType() && substituteMethod.declaringClass.isRawType())
if (method.hasSubstitutedParameters() && substituteMethod.hasSubstitutedParameters())
return areMethodsCompatible(method, substituteMethod);
return false;
}
if (substituteMethod instanceof ParameterizedGenericMethodBinding) {
if (method.typeVariables != Binding.NO_TYPE_VARIABLES)
return !((ParameterizedGenericMethodBinding) substituteMethod).isRaw;
// since substituteMethod has substituted type variables, method cannot have a generic signature AND no variables -> its a name clash if it does
return !hasGenericParameter(method);
}
// if method has its own variables, then substituteMethod failed bounds check in computeSubstituteMethod()
return method.typeVariables == Binding.NO_TYPE_VARIABLES;
}
boolean isUnsafeReturnTypeOverride(MethodBinding currentMethod, MethodBinding inheritedMethod) {
// called when currentMethod's return type is NOT compatible with inheritedMethod's return type
// JLS 3 �8.4.5: more are accepted, with an unchecked conversion
if (currentMethod.returnType == inheritedMethod.returnType.erasure()) {
TypeBinding[] currentParams = currentMethod.parameters;
TypeBinding[] inheritedParams = inheritedMethod.parameters;
for (int i = 0, l = currentParams.length; i < l; i++)
if (!areTypesEqual(currentParams[i], inheritedParams[i]))
return true;
}
if (currentMethod.typeVariables == Binding.NO_TYPE_VARIABLES
&& inheritedMethod.original().typeVariables != Binding.NO_TYPE_VARIABLES
&& currentMethod.returnType.erasure().findSuperTypeOriginatingFrom(inheritedMethod.returnType.erasure()) != null) {
return true;
}
return false;
}
boolean reportIncompatibleReturnTypeError(MethodBinding currentMethod, MethodBinding inheritedMethod) {
if (isUnsafeReturnTypeOverride(currentMethod, inheritedMethod)) {
problemReporter(currentMethod).unsafeReturnTypeOverride(currentMethod, inheritedMethod, this.type);
return false;
}
return super.reportIncompatibleReturnTypeError(currentMethod, inheritedMethod);
}
void verify() {
if (this.type.isAnnotationType())
this.type.detectAnnotationCycle();
super.verify();
reportRawReferences();
for (int i = this.type.typeVariables.length; --i >= 0;) {
TypeVariableBinding var = this.type.typeVariables[i];
// must verify bounds if the variable has more than 1
if (var.superInterfaces == Binding.NO_SUPERINTERFACES) continue;
if (var.superInterfaces.length == 1 && var.superclass.id == TypeIds.T_JavaLangObject) continue;
this.currentMethods = new HashtableOfObject(0);
ReferenceBinding superclass = var.superclass();
if (superclass.kind() == Binding.TYPE_PARAMETER)
superclass = (ReferenceBinding) superclass.erasure();
ReferenceBinding[] itsInterfaces = var.superInterfaces();
ReferenceBinding[] superInterfaces = new ReferenceBinding[itsInterfaces.length];
for (int j = itsInterfaces.length; --j >= 0;) {
superInterfaces[j] = itsInterfaces[j].kind() == Binding.TYPE_PARAMETER
? (ReferenceBinding) itsInterfaces[j].erasure()
: itsInterfaces[j];
}
computeInheritedMethods(superclass, superInterfaces);
checkTypeVariableMethods(this.type.scope.referenceContext.typeParameters[i]);
}
}
}