+/*******************************************************************************
+ * Copyright (c) 2000, 2004 IBM Corporation and others.
+ * All rights reserved. This program and the accompanying materials
+ * are made available under the terms of the Common Public License v1.0
+ * which accompanies this distribution, and is available at
+ * http://www.eclipse.org/legal/cpl-v10.html
+ *
+ * Contributors:
+ * IBM Corporation - initial API and implementation
+ *******************************************************************************/
+package org.eclipse.jdt.internal.compiler.lookup;
+
+import org.eclipse.jdt.core.compiler.CharOperation;
+import org.eclipse.jdt.internal.compiler.ast.MethodDeclaration;
+import org.eclipse.jdt.internal.compiler.ast.TypeDeclaration;
+import org.eclipse.jdt.internal.compiler.problem.ProblemReporter;
+import org.eclipse.jdt.internal.compiler.util.HashtableOfObject;
+
+public final class MethodVerifier implements TagBits, TypeConstants {
+ SourceTypeBinding type;
+ HashtableOfObject inheritedMethods;
+ HashtableOfObject currentMethods;
+ ReferenceBinding runtimeException;
+ ReferenceBinding errorException;
+ LookupEnvironment environment;
+/*
+Binding creation is responsible for reporting all problems with types:
+ - all modifier problems (duplicates & multiple visibility modifiers + incompatible combinations - abstract/final)
+ - plus invalid modifiers given the context (the verifier did not do this before)
+ - qualified name collisions between a type and a package (types in default packages are excluded)
+ - all type hierarchy problems:
+ - cycles in the superclass or superinterface hierarchy
+ - an ambiguous, invisible or missing superclass or superinterface
+ - extending a final class
+ - extending an interface instead of a class
+ - implementing a class instead of an interface
+ - implementing the same interface more than once (ie. duplicate interfaces)
+ - with nested types:
+ - shadowing an enclosing type's source name
+ - defining a static class or interface inside a non-static nested class
+ - defining an interface as a local type (local types can only be classes)
+*/
+public MethodVerifier(LookupEnvironment environment) {
+ this.type = null; // Initialized with the public method verify(SourceTypeBinding)
+ this.inheritedMethods = null;
+ this.currentMethods = null;
+ this.runtimeException = null;
+ this.errorException = null;
+ this.environment = environment;
+}
+private 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;
+
+ for (int i = 0; i < length; i++)
+ if (!areTypesEqual(oneArgs[i], twoArgs[i])) return false;
+ return true;
+}
+private boolean areReturnTypesEqual(MethodBinding one, MethodBinding two) {
+ return areTypesEqual(one.returnType, two.returnType);
+}
+private boolean areTypesEqual(TypeBinding one, TypeBinding two) {
+ if (one == two) return true;
+ if (one instanceof ReferenceBinding && two instanceof ReferenceBinding)
+ // can compare unresolved to resolved reference bindings
+ return CharOperation.equals(((ReferenceBinding) one).compoundName, ((ReferenceBinding) two).compoundName);
+ return false; // all other type bindings are identical
+}
+private void checkAbstractMethod(MethodBinding abstractMethod) {
+ if (mustImplementAbstractMethod(abstractMethod)) {
+ TypeDeclaration typeDeclaration = this.type.scope.referenceContext;
+ if (typeDeclaration != null) {
+ MethodDeclaration missingAbstractMethod = typeDeclaration.addMissingAbstractMethodFor(abstractMethod);
+ missingAbstractMethod.scope.problemReporter().abstractMethodMustBeImplemented(this.type, abstractMethod);
+ } else {
+ this.problemReporter().abstractMethodMustBeImplemented(this.type, abstractMethod);
+ }
+ }
+}
+private void checkAgainstInheritedMethods(MethodBinding currentMethod, MethodBinding[] methods, int length) {
+ nextMethod : for (int i = length; --i >= 0;) {
+ MethodBinding inheritedMethod = methods[i];
+ if (currentMethod.isStatic() != inheritedMethod.isStatic()) { // Cannot override a static method or hide an instance method
+ this.problemReporter(currentMethod).staticAndInstanceConflict(currentMethod, inheritedMethod);
+ continue nextMethod;
+ }
+
+ if (!currentMethod.isAbstract() && inheritedMethod.isAbstract()) {
+ if ((currentMethod.modifiers & CompilerModifiers.AccOverriding) == 0)
+ currentMethod.modifiers |= CompilerModifiers.AccImplementing;
+ } else {
+ currentMethod.modifiers |= CompilerModifiers.AccOverriding;
+ }
+
+ if (!areReturnTypesEqual(currentMethod, inheritedMethod)) {
+ this.problemReporter(currentMethod).incompatibleReturnType(currentMethod, inheritedMethod);
+ } else {
+ if (currentMethod.thrownExceptions != NoExceptions)
+ this.checkExceptions(currentMethod, inheritedMethod);
+ if (inheritedMethod.isFinal())
+ this.problemReporter(currentMethod).finalMethodCannotBeOverridden(currentMethod, inheritedMethod);
+ if (!this.isAsVisible(currentMethod, inheritedMethod))
+ this.problemReporter(currentMethod).visibilityConflict(currentMethod, inheritedMethod);
+ if (environment.options.reportDeprecationWhenOverridingDeprecatedMethod && inheritedMethod.isViewedAsDeprecated()) {
+ if (!currentMethod.isViewedAsDeprecated() || environment.options.reportDeprecationInsideDeprecatedCode) {
+ // check against the other inherited methods to see if they hide this inheritedMethod
+ ReferenceBinding declaringClass = inheritedMethod.declaringClass;
+ if (declaringClass.isInterface())
+ for (int j = length; --j >= 0;)
+ if (i != j && methods[j].declaringClass.implementsInterface(declaringClass, false))
+ continue nextMethod;
+
+ this.problemReporter(currentMethod).overridesDeprecatedMethod(currentMethod, inheritedMethod);
+ }
+ }
+ }
+ }
+}
+/*
+"8.4.4"
+Verify that newExceptions are all included in inheritedExceptions.
+Assumes all exceptions are valid and throwable.
+Unchecked exceptions (compatible with runtime & error) are ignored (see the spec on pg. 203).
+*/
+private void checkExceptions(MethodBinding newMethod, MethodBinding inheritedMethod) {
+ ReferenceBinding[] newExceptions = resolvedExceptionTypesFor(newMethod);
+ ReferenceBinding[] inheritedExceptions = resolvedExceptionTypesFor(inheritedMethod);
+ for (int i = newExceptions.length; --i >= 0;) {
+ ReferenceBinding newException = newExceptions[i];
+ int j = inheritedExceptions.length;
+ while (--j > -1 && !this.isSameClassOrSubclassOf(newException, inheritedExceptions[j])){/*empty*/}
+ if (j == -1)
+ if (!(newException.isCompatibleWith(this.runtimeException()) || newException.isCompatibleWith(this.errorException())))
+ this.problemReporter(newMethod).incompatibleExceptionInThrowsClause(this.type, newMethod, inheritedMethod, newException);
+ }
+}
+private void checkInheritedMethods(MethodBinding[] methods, int length) {
+ MethodBinding first = methods[0];
+ int index = length;
+ while (--index > 0 && areReturnTypesEqual(first, methods[index])){/*empty*/}
+ if (index > 0) { // All inherited methods do NOT have the same vmSignature
+ this.problemReporter().inheritedMethodsHaveIncompatibleReturnTypes(this.type, methods, length);
+ return;
+ }
+
+ MethodBinding concreteMethod = null;
+ if (!type.isInterface()) { // ignore concrete methods for interfaces
+ for (int i = length; --i >= 0;) { // Remember that only one of the methods can be non-abstract
+ if (!methods[i].isAbstract()) {
+ concreteMethod = methods[i];
+ break;
+ }
+ }
+ }
+ if (concreteMethod == null) {
+ if (this.type.isClass() && !this.type.isAbstract()) {
+ for (int i = length; --i >= 0;) {
+ if (mustImplementAbstractMethod(methods[i])) {
+ TypeDeclaration typeDeclaration = this.type.scope.referenceContext;
+ if (typeDeclaration != null) {
+ MethodDeclaration missingAbstractMethod = typeDeclaration.addMissingAbstractMethodFor(methods[0]);
+ missingAbstractMethod.scope.problemReporter().abstractMethodMustBeImplemented(this.type, methods[0]);
+ } else {
+ this.problemReporter().abstractMethodMustBeImplemented(this.type, methods[0]);
+ }
+ return;
+ }
+ }
+ }
+ return;
+ }
+
+ MethodBinding[] abstractMethods = new MethodBinding[length - 1];
+ index = 0;
+ for (int i = length; --i >= 0;)
+ if (methods[i] != concreteMethod)
+ abstractMethods[index++] = methods[i];
+
+ // Remember that interfaces can only define public instance methods
+ if (concreteMethod.isStatic())
+ // Cannot inherit a static method which is specified as an instance method by an interface
+ this.problemReporter().staticInheritedMethodConflicts(type, concreteMethod, abstractMethods);
+ if (!concreteMethod.isPublic())
+ // Cannot reduce visibility of a public method specified by an interface
+ this.problemReporter().inheritedMethodReducesVisibility(type, concreteMethod, abstractMethods);
+ if (concreteMethod.thrownExceptions != NoExceptions)
+ for (int i = abstractMethods.length; --i >= 0;)
+ this.checkExceptions(concreteMethod, abstractMethods[i]);
+}
+/*
+For each inherited method identifier (message pattern - vm signature minus the return type)
+ if current method exists
+ if current's vm signature does not match an inherited signature then complain
+ else compare current's exceptions & visibility against each inherited method
+ else
+ if inherited methods = 1
+ if inherited is abstract && type is NOT an interface or abstract, complain
+ else
+ if vm signatures do not match complain
+ else
+ find the concrete implementation amongst the abstract methods (can only be 1)
+ if one exists then
+ it must be a public instance method
+ compare concrete's exceptions against each abstract method
+ else
+ complain about missing implementation only if type is NOT an interface or abstract
+*/
+private void checkMethods() {
+ boolean mustImplementAbstractMethods = this.type.isClass() && !this.type.isAbstract();
+ boolean skipInheritedMethods = mustImplementAbstractMethods && this.type.superInterfaces() == NoSuperInterfaces
+ && this.type.superclass() != null && !this.type.superclass().isAbstract(); // have a single concrete superclass so only check overridden methods
+ 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]);
+ if (current == null && skipInheritedMethods)
+ continue nextSelector;
+
+ MethodBinding[] inherited = (MethodBinding[]) this.inheritedMethods.valueTable[s];
+ if (inherited.length == 1 && current == null) { // handle the common case
+ if (mustImplementAbstractMethods && inherited[0].isAbstract())
+ checkAbstractMethod(inherited[0]);
+ continue nextSelector;
+ }
+
+ int index = -1;
+ MethodBinding[] matchingInherited = new MethodBinding[inherited.length];
+ if (current != null) {
+ for (int i = 0, length1 = current.length; i < length1; i++) {
+ while (index >= 0) matchingInherited[index--] = null; // clear the previous contents of the matching methods
+ MethodBinding currentMethod = current[i];
+ for (int j = 0, length2 = inherited.length; j < length2; j++) {
+ MethodBinding inheritedMethod = inherited[j];
+ if (inheritedMethod != null && areParametersEqual(currentMethod, inheritedMethod)) {
+ matchingInherited[++index] = inheritedMethod;
+ inherited[j] = null; // do not want to find it again
+ }
+ }
+ if (index >= 0)
+ this.checkAgainstInheritedMethods(currentMethod, matchingInherited, index + 1); // pass in the length of matching
+ }
+ }
+
+ 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++) {
+ if (inherited[j] != null && areParametersEqual(inheritedMethod, inherited[j])) {
+ matchingInherited[++index] = inherited[j];
+ inherited[j] = null; // do not want to find it again
+ }
+ }
+ }
+ if (index > 0)
+ this.checkInheritedMethods(matchingInherited, index + 1); // pass in the length of matching
+ else if (mustImplementAbstractMethods && index == 0 && matchingInherited[0].isAbstract())
+ checkAbstractMethod(matchingInherited[0]);
+ }
+ }
+}
+private void checkPackagePrivateAbstractMethod(MethodBinding abstractMethod) {
+ ReferenceBinding superType = this.type.superclass();
+ char[] selector = abstractMethod.selector;
+ do {
+ if (!superType.isValidBinding()) return;
+ if (!superType.isAbstract()) return; // closer non abstract super type will be flagged instead
+
+ MethodBinding[] methods = superType.getMethods(selector);
+ nextMethod : for (int m = methods.length; --m >= 0;) {
+ MethodBinding method = methods[m];
+ if (!areReturnTypesEqual(method, abstractMethod) || !areParametersEqual(method, abstractMethod))
+ continue nextMethod;
+ if (method.isPrivate() || method.isConstructor() || method.isDefaultAbstract())
+ continue nextMethod;
+ if (superType.fPackage == abstractMethod.declaringClass.fPackage) return; // found concrete implementation of abstract method in same package
+ }
+ } while ((superType = superType.superclass()) != abstractMethod.declaringClass);
+
+ // non visible abstract methods cannot be overridden so the type must be defined abstract
+ this.problemReporter().abstractMethodCannotBeOverridden(this.type, abstractMethod);
+}
+/*
+Binding creation is responsible for reporting:
+ - all modifier problems (duplicates & multiple visibility modifiers + incompatible combinations)
+ - plus invalid modifiers given the context... examples:
+ - interface methods can only be public
+ - abstract methods can only be defined by abstract classes
+ - collisions... 2 methods with identical vmSelectors
+ - multiple methods with the same message pattern but different return types
+ - ambiguous, invisible or missing return/argument/exception types
+ - check the type of any array is not void
+ - check that each exception type is Throwable or a subclass of it
+*/
+private void computeInheritedMethods() {
+ this.inheritedMethods = new HashtableOfObject(51); // maps method selectors to an array of methods... must search to match paramaters & return type
+ ReferenceBinding[][] interfacesToVisit = new ReferenceBinding[3][];
+ int lastPosition = -1;
+ ReferenceBinding[] itsInterfaces = type.superInterfaces();
+ if (itsInterfaces != NoSuperInterfaces)
+ interfacesToVisit[++lastPosition] = itsInterfaces;
+
+ ReferenceBinding superType = this.type.isClass()
+ ? this.type.superclass()
+ : this.type.scope.getJavaLangObject(); // check interface methods against Object
+ HashtableOfObject nonVisibleDefaultMethods = new HashtableOfObject(3); // maps method selectors to an array of methods
+ boolean allSuperclassesAreAbstract = true;
+
+ while (superType != null) {
+ if (superType.isValidBinding()) {
+ if (allSuperclassesAreAbstract) {
+ if (superType.isAbstract()) {
+ // only need to include superinterfaces if immediate superclasses are abstract
+ if ((itsInterfaces = superType.superInterfaces()) != NoSuperInterfaces) {
+ if (++lastPosition == interfacesToVisit.length)
+ System.arraycopy(interfacesToVisit, 0, interfacesToVisit = new ReferenceBinding[lastPosition * 2][], 0, lastPosition);
+ interfacesToVisit[lastPosition] = itsInterfaces;
+ }
+ } else {
+ allSuperclassesAreAbstract = false;
+ }
+ }
+
+ MethodBinding[] methods = superType.unResolvedMethods();
+ nextMethod : for (int m = methods.length; --m >= 0;) {
+ MethodBinding method = methods[m];
+ if (method.isPrivate() || method.isConstructor() || method.isDefaultAbstract())
+ continue nextMethod;
+ MethodBinding[] existingMethods = (MethodBinding[]) this.inheritedMethods.get(method.selector);
+ if (existingMethods != null) {
+ for (int i = 0, length = existingMethods.length; i < length; i++) {
+ if (areReturnTypesEqual(method, existingMethods[i]) && areParametersEqual(method, existingMethods[i])) {
+ if (method.isDefault() && method.isAbstract() && method.declaringClass.fPackage != type.fPackage)
+ checkPackagePrivateAbstractMethod(method);
+ continue nextMethod;
+ }
+ }
+ }
+ MethodBinding[] nonVisible = (MethodBinding[]) nonVisibleDefaultMethods.get(method.selector);
+ if (nonVisible != null)
+ for (int i = 0, l = nonVisible.length; i < l; i++)
+ if (areReturnTypesEqual(method, nonVisible[i]) && areParametersEqual(method, nonVisible[i]))
+ continue nextMethod;
+
+ if (!method.isDefault() || method.declaringClass.fPackage == type.fPackage) {
+ if (existingMethods == null) {
+ existingMethods = new MethodBinding[] {method};
+ } else {
+ int length = existingMethods.length;
+ System.arraycopy(existingMethods, 0, existingMethods = new MethodBinding[length + 1], 0, length);
+ existingMethods[length] = method;
+ }
+ this.inheritedMethods.put(method.selector, existingMethods);
+ } else {
+ if (nonVisible == null) {
+ nonVisible = new MethodBinding[] {method};
+ } else {
+ int length = nonVisible.length;
+ System.arraycopy(nonVisible, 0, nonVisible = new MethodBinding[length + 1], 0, length);
+ nonVisible[length] = method;
+ }
+ nonVisibleDefaultMethods.put(method.selector, nonVisible);
+
+ if (method.isAbstract() && !this.type.isAbstract()) // non visible abstract methods cannot be overridden so the type must be defined abstract
+ this.problemReporter().abstractMethodCannotBeOverridden(this.type, method);
+
+ MethodBinding[] current = (MethodBinding[]) this.currentMethods.get(method.selector);
+ if (current != null) { // non visible methods cannot be overridden so a warning is issued
+ foundMatch : for (int i = 0, length = current.length; i < length; i++) {
+ if (areReturnTypesEqual(method, current[i]) && areParametersEqual(method, current[i])) {
+ this.problemReporter().overridesPackageDefaultMethod(current[i], method);
+ break foundMatch;
+ }
+ }
+ }
+ }
+ }
+ superType = superType.superclass();
+ }
+ }
+
+ for (int i = 0; i <= lastPosition; i++) {
+ ReferenceBinding[] interfaces = interfacesToVisit[i];
+ for (int j = 0, l = interfaces.length; j < l; j++) {
+ superType = interfaces[j];
+ if ((superType.tagBits & InterfaceVisited) == 0) {
+ superType.tagBits |= InterfaceVisited;
+ if (superType.isValidBinding()) {
+ if ((itsInterfaces = superType.superInterfaces()) != NoSuperInterfaces) {
+ if (++lastPosition == interfacesToVisit.length)
+ System.arraycopy(interfacesToVisit, 0, interfacesToVisit = new ReferenceBinding[lastPosition * 2][], 0, lastPosition);
+ interfacesToVisit[lastPosition] = itsInterfaces;
+ }
+
+ MethodBinding[] methods = superType.unResolvedMethods();
+ nextMethod : for (int m = methods.length; --m >= 0;) { // Interface methods are all abstract public
+ MethodBinding method = methods[m];
+ MethodBinding[] existingMethods = (MethodBinding[]) this.inheritedMethods.get(method.selector);
+ if (existingMethods == null) {
+ existingMethods = new MethodBinding[] {method};
+ } else {
+ int length = existingMethods.length;
+ for (int e = 0; e < length; e++) {
+ MethodBinding existing = existingMethods[e];
+ if (areParametersEqual(method, existing) && existing.declaringClass.implementsInterface(superType, true))
+ continue nextMethod; // skip interface method with the same signature if visible to its declaringClass
+ }
+ System.arraycopy(existingMethods, 0, existingMethods = new MethodBinding[length + 1], 0, length);
+ existingMethods[length] = method;
+ }
+ this.inheritedMethods.put(method.selector, existingMethods);
+ }
+ }
+ }
+ }
+ }
+
+ // bit reinitialization
+ for (int i = 0; i <= lastPosition; i++) {
+ ReferenceBinding[] interfaces = interfacesToVisit[i];
+ for (int j = 0, length = interfaces.length; j < length; j++)
+ interfaces[j].tagBits &= ~InterfaceVisited;
+ }
+}
+private void computeMethods() {
+ MethodBinding[] methods = type.methods();
+ int size = methods.length;
+ this.currentMethods = new HashtableOfObject(size == 0 ? 1 : size); // maps method selectors to an array of methods... must search to match paramaters & return type
+ for (int m = size; --m >= 0;) {
+ MethodBinding method = methods[m];
+ if (!(method.isConstructor() || method.isDefaultAbstract())) { // keep all methods which are NOT constructors or default abstract
+ MethodBinding[] existingMethods = (MethodBinding[]) this.currentMethods.get(method.selector);
+ if (existingMethods == null)
+ existingMethods = new MethodBinding[1];
+ else
+ System.arraycopy(existingMethods, 0,
+ (existingMethods = new MethodBinding[existingMethods.length + 1]), 0, existingMethods.length - 1);
+ existingMethods[existingMethods.length - 1] = method;
+ this.currentMethods.put(method.selector, existingMethods);
+ }
+ }
+}
+private ReferenceBinding errorException() {
+ if (errorException == null)
+ this.errorException = this.type.scope.getJavaLangError();
+ return errorException;
+}
+private boolean isAsVisible(MethodBinding newMethod, MethodBinding inheritedMethod) {
+ if (inheritedMethod.modifiers == newMethod.modifiers) return true;
+
+ if (newMethod.isPublic()) return true; // Covers everything
+ if (inheritedMethod.isPublic()) return false;
+
+ if (newMethod.isProtected()) return true;
+ if (inheritedMethod.isProtected()) return false;
+
+ return !newMethod.isPrivate(); // The inheritedMethod cannot be private since it would not be visible
+}
+private boolean isSameClassOrSubclassOf(ReferenceBinding testClass, ReferenceBinding superclass) {
+ do {
+ if (testClass == superclass) return true;
+ } while ((testClass = testClass.superclass()) != null);
+ return false;
+}
+private boolean mustImplementAbstractMethod(MethodBinding abstractMethod) {
+ // if the type's superclass is an abstract class, then all abstract methods must be implemented
+ // otherwise, skip it if the type's superclass must implement any of the inherited methods
+ ReferenceBinding superclass = this.type.superclass();
+ ReferenceBinding declaringClass = abstractMethod.declaringClass;
+ if (declaringClass.isClass()) {
+ while (superclass.isAbstract() && superclass != declaringClass)
+ superclass = superclass.superclass(); // find the first concrete superclass or the abstract declaringClass
+ } else {
+ if (this.type.implementsInterface(declaringClass, false)) {
+ if (this.type.isAbstract()) return false; // leave it for the subclasses
+ if (!superclass.implementsInterface(declaringClass, true)) // only if a superclass does not also implement the interface
+ return true;
+ }
+ while (superclass.isAbstract() && !superclass.implementsInterface(declaringClass, false))
+ superclass = superclass.superclass(); // find the first concrete superclass or the superclass which implements the interface
+ }
+ return superclass.isAbstract(); // if it is a concrete class then we have already reported problem against it
+}
+private ProblemReporter problemReporter() {
+ return this.type.scope.problemReporter();
+}
+private ProblemReporter problemReporter(MethodBinding currentMethod) {
+ ProblemReporter reporter = problemReporter();
+ if (currentMethod.declaringClass == type) // only report against the currentMethod if its implemented by the type
+ reporter.referenceContext = currentMethod.sourceMethod();
+ return reporter;
+}
+ReferenceBinding[] resolvedExceptionTypesFor(MethodBinding method) {
+ ReferenceBinding[] exceptions = method.thrownExceptions;
+ if ((method.modifiers & CompilerModifiers.AccUnresolved) == 0)
+ return exceptions;
+
+ if (!(method.declaringClass instanceof BinaryTypeBinding))
+ return TypeConstants.NoExceptions; // safety check
+ BinaryTypeBinding binaryType = (BinaryTypeBinding) method.declaringClass;
+
+ for (int i = exceptions.length; --i >= 0;)
+ if (exceptions[i] instanceof UnresolvedReferenceBinding)
+ exceptions[i] = (ReferenceBinding) binaryType.resolveType(exceptions[i]);
+ return exceptions;
+}
+private ReferenceBinding runtimeException() {
+ if (runtimeException == null)
+ this.runtimeException = this.type.scope.getJavaLangRuntimeException();
+ return runtimeException;
+}
+public void verify(SourceTypeBinding someType) {
+ this.type = someType;
+ this.computeMethods();
+ this.computeInheritedMethods();
+ this.checkMethods();
+}
+public String toString() {
+ StringBuffer buffer = new StringBuffer(10);
+ buffer.append("MethodVerifier for type: "); //$NON-NLS-1$
+ buffer.append(type.readableName());
+ buffer.append('\n');
+ buffer.append("\t-inherited methods: "); //$NON-NLS-1$
+ buffer.append(this.inheritedMethods);
+ return buffer.toString();
+}
+}