--- /dev/null
+/*******************************************************************************
+ * 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.CompilationUnitDeclaration;
+import org.eclipse.jdt.internal.compiler.ast.ImportReference;
+import org.eclipse.jdt.internal.compiler.ast.TypeDeclaration;
+import org.eclipse.jdt.internal.compiler.classfmt.ClassFileConstants;
+import org.eclipse.jdt.internal.compiler.problem.ProblemReporter;
+import org.eclipse.jdt.internal.compiler.util.CompoundNameVector;
+import org.eclipse.jdt.internal.compiler.util.HashtableOfObject;
+import org.eclipse.jdt.internal.compiler.util.HashtableOfType;
+import org.eclipse.jdt.internal.compiler.util.ObjectVector;
+import org.eclipse.jdt.internal.compiler.util.SimpleNameVector;
+
+public class CompilationUnitScope extends Scope {
+
+ public LookupEnvironment environment;
+ public CompilationUnitDeclaration referenceContext;
+ public char[][] currentPackageName;
+ public PackageBinding fPackage;
+ public ImportBinding[] imports;
+ public HashtableOfObject resolvedSingeTypeImports;
+
+ public SourceTypeBinding[] topLevelTypes;
+
+ private CompoundNameVector qualifiedReferences;
+ private SimpleNameVector simpleNameReferences;
+ private ObjectVector referencedTypes;
+
+ HashtableOfType constantPoolNameUsage;
+
+public CompilationUnitScope(CompilationUnitDeclaration unit, LookupEnvironment environment) {
+ super(COMPILATION_UNIT_SCOPE, null);
+ this.environment = environment;
+ this.referenceContext = unit;
+ unit.scope = this;
+ this.currentPackageName = unit.currentPackage == null ? CharOperation.NO_CHAR_CHAR : unit.currentPackage.tokens;
+
+ if (environment.options.produceReferenceInfo) {
+ this.qualifiedReferences = new CompoundNameVector();
+ this.simpleNameReferences = new SimpleNameVector();
+ this.referencedTypes = new ObjectVector();
+ } else {
+ this.qualifiedReferences = null; // used to test if dependencies should be recorded
+ this.simpleNameReferences = null;
+ this.referencedTypes = null;
+ }
+}
+void buildFieldsAndMethods() {
+ for (int i = 0, length = topLevelTypes.length; i < length; i++)
+ topLevelTypes[i].scope.buildFieldsAndMethods();
+}
+void buildTypeBindings() {
+ topLevelTypes = new SourceTypeBinding[0]; // want it initialized if the package cannot be resolved
+ if (referenceContext.compilationResult.compilationUnit != null) {
+ char[][] expectedPackageName = referenceContext.compilationResult.compilationUnit.getPackageName();
+ if (expectedPackageName != null
+ && !CharOperation.equals(currentPackageName, expectedPackageName)) {
+
+ // only report if the unit isn't structurally empty
+ if (referenceContext.currentPackage != null
+ || referenceContext.types != null
+ || referenceContext.imports != null) {
+ problemReporter().packageIsNotExpectedPackage(referenceContext);
+ }
+ currentPackageName = expectedPackageName.length == 0 ? CharOperation.NO_CHAR_CHAR : expectedPackageName;
+ }
+ }
+ if (currentPackageName == CharOperation.NO_CHAR_CHAR) {
+ if ((fPackage = environment.defaultPackage) == null) {
+ problemReporter().mustSpecifyPackage(referenceContext);
+ return;
+ }
+ } else {
+ if ((fPackage = environment.createPackage(currentPackageName)) == null) {
+ problemReporter().packageCollidesWithType(referenceContext);
+ return;
+ }
+ recordQualifiedReference(currentPackageName); // always dependent on your own package
+ }
+
+ // Skip typeDeclarations which know of previously reported errors
+ TypeDeclaration[] types = referenceContext.types;
+ int typeLength = (types == null) ? 0 : types.length;
+ topLevelTypes = new SourceTypeBinding[typeLength];
+ int count = 0;
+ nextType: for (int i = 0; i < typeLength; i++) {
+ TypeDeclaration typeDecl = types[i];
+ ReferenceBinding typeBinding = fPackage.getType0(typeDecl.name);
+ recordSimpleReference(typeDecl.name); // needed to detect collision cases
+ if (typeBinding != null && !(typeBinding instanceof UnresolvedReferenceBinding)) {
+ // if a type exists, it must be a valid type - cannot be a NotFound problem type
+ // unless its an unresolved type which is now being defined
+ problemReporter().duplicateTypes(referenceContext, typeDecl);
+ continue nextType;
+ }
+ if (fPackage != environment.defaultPackage && fPackage.getPackage(typeDecl.name) != null) {
+ // if a package exists, it must be a valid package - cannot be a NotFound problem package
+ problemReporter().typeCollidesWithPackage(referenceContext, typeDecl);
+ continue nextType;
+ }
+
+ if ((typeDecl.modifiers & AccPublic) != 0) {
+ char[] mainTypeName;
+ if ((mainTypeName = referenceContext.getMainTypeName()) != null // mainTypeName == null means that implementor of ICompilationUnit decided to return null
+ && !CharOperation.equals(mainTypeName, typeDecl.name)) {
+ problemReporter().publicClassMustMatchFileName(referenceContext, typeDecl);
+ continue nextType;
+ }
+ }
+
+ ClassScope child = new ClassScope(this, typeDecl);
+ SourceTypeBinding type = child.buildType(null, fPackage);
+ if(type != null) {
+ topLevelTypes[count++] = type;
+ }
+ }
+
+ // shrink topLevelTypes... only happens if an error was reported
+ if (count != topLevelTypes.length)
+ System.arraycopy(topLevelTypes, 0, topLevelTypes = new SourceTypeBinding[count], 0, count);
+}
+void checkAndSetImports() {
+ if (referenceContext.imports == null) {
+ imports = getDefaultImports();
+ return;
+ }
+
+ // allocate the import array, add java.lang.* by default
+ int numberOfStatements = referenceContext.imports.length;
+ int numberOfImports = numberOfStatements + 1;
+ for (int i = 0; i < numberOfStatements; i++) {
+ ImportReference importReference = referenceContext.imports[i];
+ if (importReference.onDemand && CharOperation.equals(JAVA_LANG, importReference.tokens)) {
+ numberOfImports--;
+ break;
+ }
+ }
+ ImportBinding[] resolvedImports = new ImportBinding[numberOfImports];
+ resolvedImports[0] = getDefaultImports()[0];
+ int index = 1;
+
+ nextImport : for (int i = 0; i < numberOfStatements; i++) {
+ ImportReference importReference = referenceContext.imports[i];
+ char[][] compoundName = importReference.tokens;
+
+ // skip duplicates or imports of the current package
+ for (int j = 0; j < index; j++)
+ if (resolvedImports[j].onDemand == importReference.onDemand)
+ if (CharOperation.equals(compoundName, resolvedImports[j].compoundName))
+ continue nextImport;
+ if (importReference.onDemand == true)
+ if (CharOperation.equals(compoundName, currentPackageName))
+ continue nextImport;
+
+ if (importReference.onDemand) {
+ Binding importBinding = findOnDemandImport(compoundName);
+ if (!importBinding.isValidBinding())
+ continue nextImport; // we report all problems in faultInImports()
+ resolvedImports[index++] = new ImportBinding(compoundName, true, importBinding, importReference);
+ } else {
+ resolvedImports[index++] = new ImportBinding(compoundName, false, null, importReference);
+ }
+ }
+
+ // shrink resolvedImports... only happens if an error was reported
+ if (resolvedImports.length > index)
+ System.arraycopy(resolvedImports, 0, resolvedImports = new ImportBinding[index], 0, index);
+ imports = resolvedImports;
+}
+/*
+ * INTERNAL USE-ONLY
+ * Innerclasses get their name computed as they are generated, since some may not
+ * be actually outputed if sitting inside unreachable code.
+ */
+public char[] computeConstantPoolName(LocalTypeBinding localType) {
+ if (localType.constantPoolName() != null) {
+ return localType.constantPoolName();
+ }
+ // delegates to the outermost enclosing classfile, since it is the only one with a global vision of its innertypes.
+
+ if (constantPoolNameUsage == null)
+ constantPoolNameUsage = new HashtableOfType();
+
+ ReferenceBinding outerMostEnclosingType = localType.scope.outerMostClassScope().enclosingSourceType();
+
+ // ensure there is not already such a local type name defined by the user
+ int index = 0;
+ char[] candidateName;
+ while(true) {
+ if (localType.isMemberType()){
+ if (index == 0){
+ candidateName = CharOperation.concat(
+ localType.enclosingType().constantPoolName(),
+ localType.sourceName,
+ '$');
+ } else {
+ // in case of collision, then member name gets extra $1 inserted
+ // e.g. class X { { class L{} new X(){ class L{} } } }
+ candidateName = CharOperation.concat(
+ localType.enclosingType().constantPoolName(),
+ '$',
+ String.valueOf(index).toCharArray(),
+ '$',
+ localType.sourceName);
+ }
+ } else if (localType.isAnonymousType()){
+ candidateName = CharOperation.concat(
+ outerMostEnclosingType.constantPoolName(),
+ String.valueOf(index+1).toCharArray(),
+ '$');
+ } else {
+ candidateName = CharOperation.concat(
+ outerMostEnclosingType.constantPoolName(),
+ '$',
+ String.valueOf(index+1).toCharArray(),
+ '$',
+ localType.sourceName);
+ }
+ if (constantPoolNameUsage.get(candidateName) != null) {
+ index ++;
+ } else {
+ constantPoolNameUsage.put(candidateName, localType);
+ break;
+ }
+ }
+ return candidateName;
+}
+
+void connectTypeHierarchy() {
+ for (int i = 0, length = topLevelTypes.length; i < length; i++)
+ topLevelTypes[i].scope.connectTypeHierarchy();
+}
+void faultInImports() {
+ if (referenceContext.imports == null)
+ return;
+
+ // collect the top level type names if a single type import exists
+ int numberOfStatements = referenceContext.imports.length;
+ HashtableOfType typesBySimpleNames = null;
+ for (int i = 0; i < numberOfStatements; i++) {
+ if (!referenceContext.imports[i].onDemand) {
+ typesBySimpleNames = new HashtableOfType(topLevelTypes.length + numberOfStatements);
+ for (int j = 0, length = topLevelTypes.length; j < length; j++)
+ typesBySimpleNames.put(topLevelTypes[j].sourceName, topLevelTypes[j]);
+ break;
+ }
+ }
+
+ // allocate the import array, add java.lang.* by default
+ int numberOfImports = numberOfStatements + 1;
+ for (int i = 0; i < numberOfStatements; i++) {
+ ImportReference importReference = referenceContext.imports[i];
+ if (importReference.onDemand && CharOperation.equals(JAVA_LANG, importReference.tokens)) {
+ numberOfImports--;
+ break;
+ }
+ }
+ ImportBinding[] resolvedImports = new ImportBinding[numberOfImports];
+ resolvedImports[0] = getDefaultImports()[0];
+ int index = 1;
+
+ nextImport : for (int i = 0; i < numberOfStatements; i++) {
+ ImportReference importReference = referenceContext.imports[i];
+ char[][] compoundName = importReference.tokens;
+
+ // skip duplicates or imports of the current package
+ for (int j = 0; j < index; j++)
+ if (resolvedImports[j].onDemand == importReference.onDemand)
+ if (CharOperation.equals(compoundName, resolvedImports[j].compoundName)) {
+ problemReporter().unusedImport(importReference); // since skipped, must be reported now
+ continue nextImport;
+ }
+ if (importReference.onDemand == true)
+ if (CharOperation.equals(compoundName, currentPackageName)) {
+ problemReporter().unusedImport(importReference); // since skipped, must be reported now
+ continue nextImport;
+ }
+ if (importReference.onDemand) {
+ Binding importBinding = findOnDemandImport(compoundName);
+ if (!importBinding.isValidBinding()) {
+ problemReporter().importProblem(importReference, importBinding);
+ continue nextImport;
+ }
+ resolvedImports[index++] = new ImportBinding(compoundName, true, importBinding, importReference);
+ } else {
+ Binding typeBinding = findSingleTypeImport(compoundName);
+ if (!typeBinding.isValidBinding()) {
+ problemReporter().importProblem(importReference, typeBinding);
+ continue nextImport;
+ }
+ if (typeBinding instanceof PackageBinding) {
+ problemReporter().cannotImportPackage(importReference);
+ continue nextImport;
+ }
+ if (typeBinding instanceof ReferenceBinding) {
+ ReferenceBinding referenceBinding = (ReferenceBinding) typeBinding;
+ if (importReference.isTypeUseDeprecated(referenceBinding, this)) {
+ problemReporter().deprecatedType((TypeBinding) typeBinding, importReference);
+ }
+ }
+ ReferenceBinding existingType = typesBySimpleNames.get(compoundName[compoundName.length - 1]);
+ if (existingType != null) {
+ // duplicate test above should have caught this case, but make sure
+ if (existingType == typeBinding) {
+ continue nextImport;
+ }
+ // either the type collides with a top level type or another imported type
+ for (int j = 0, length = topLevelTypes.length; j < length; j++) {
+ if (CharOperation.equals(topLevelTypes[j].sourceName, existingType.sourceName)) {
+ problemReporter().conflictingImport(importReference);
+ continue nextImport;
+ }
+ }
+ problemReporter().duplicateImport(importReference);
+ continue nextImport;
+ }
+ resolvedImports[index++] = new ImportBinding(compoundName, false, typeBinding, importReference);
+ typesBySimpleNames.put(compoundName[compoundName.length - 1], (ReferenceBinding) typeBinding);
+ }
+ }
+
+ // shrink resolvedImports... only happens if an error was reported
+ if (resolvedImports.length > index)
+ System.arraycopy(resolvedImports, 0, resolvedImports = new ImportBinding[index], 0, index);
+ imports = resolvedImports;
+
+ int length = imports.length;
+ resolvedSingeTypeImports = new HashtableOfObject(length);
+ for (int i = 0; i < length; i++) {
+ ImportBinding binding = imports[i];
+ if (!binding.onDemand)
+ resolvedSingeTypeImports.put(binding.compoundName[binding.compoundName.length - 1], binding);
+ }
+}
+public void faultInTypes() {
+ faultInImports();
+
+ for (int i = 0, length = topLevelTypes.length; i < length; i++)
+ topLevelTypes[i].faultInTypesForFieldsAndMethods();
+}
+private Binding findOnDemandImport(char[][] compoundName) {
+ recordQualifiedReference(compoundName);
+
+ Binding binding = environment.getTopLevelPackage(compoundName[0]);
+ int i = 1;
+ int length = compoundName.length;
+ foundNothingOrType: if (binding != null) {
+ PackageBinding packageBinding = (PackageBinding) binding;
+ while (i < length) {
+ binding = packageBinding.getTypeOrPackage(compoundName[i++]);
+ if (binding == null || !binding.isValidBinding()) {
+ binding = null;
+ break foundNothingOrType;
+ }
+ if (!(binding instanceof PackageBinding))
+ break foundNothingOrType;
+
+ packageBinding = (PackageBinding) binding;
+ }
+ return packageBinding;
+ }
+
+ ReferenceBinding type;
+ if (binding == null) {
+ if (environment.defaultPackage == null
+ || environment.options.complianceLevel >= ClassFileConstants.JDK1_4){
+ return new ProblemReferenceBinding(
+ CharOperation.subarray(compoundName, 0, i),
+ NotFound);
+ }
+ type = findType(compoundName[0], environment.defaultPackage, environment.defaultPackage);
+ if (type == null || !type.isValidBinding())
+ return new ProblemReferenceBinding(
+ CharOperation.subarray(compoundName, 0, i),
+ NotFound);
+ i = 1; // reset to look for member types inside the default package type
+ } else {
+ type = (ReferenceBinding) binding;
+ }
+
+ for (; i < length; i++) {
+ if (!type.canBeSeenBy(fPackage)) {
+ return new ProblemReferenceBinding(CharOperation.subarray(compoundName, 0, i), type, NotVisible);
+ }
+ // does not look for inherited member types on purpose
+ if ((type = type.getMemberType(compoundName[i])) == null) {
+ return new ProblemReferenceBinding(
+ CharOperation.subarray(compoundName, 0, i + 1),
+ NotFound);
+ }
+ }
+ if (!type.canBeSeenBy(fPackage))
+ return new ProblemReferenceBinding(compoundName, type, NotVisible);
+ return type;
+}
+private Binding findSingleTypeImport(char[][] compoundName) {
+ if (compoundName.length == 1) {
+ // findType records the reference
+ // the name cannot be a package
+ if (environment.defaultPackage == null
+ || environment.options.complianceLevel >= ClassFileConstants.JDK1_4)
+ return new ProblemReferenceBinding(compoundName, NotFound);
+ ReferenceBinding typeBinding = findType(compoundName[0], environment.defaultPackage, fPackage);
+ if (typeBinding == null)
+ return new ProblemReferenceBinding(compoundName, NotFound);
+ return typeBinding;
+ }
+ return findOnDemandImport(compoundName);
+}
+ImportBinding[] getDefaultImports() {
+ // initialize the default imports if necessary... share the default java.lang.* import
+ if (environment.defaultImports != null) return environment.defaultImports;
+
+ Binding importBinding = environment.getTopLevelPackage(JAVA);
+ if (importBinding != null)
+ importBinding = ((PackageBinding) importBinding).getTypeOrPackage(JAVA_LANG[1]);
+
+ // abort if java.lang cannot be found...
+ if (importBinding == null || !importBinding.isValidBinding())
+ problemReporter().isClassPathCorrect(JAVA_LANG_OBJECT, referenceCompilationUnit());
+
+ return environment.defaultImports = new ImportBinding[] {new ImportBinding(JAVA_LANG, true, importBinding, null)};
+}
+/* Answer the problem reporter to use for raising new problems.
+*
+* Note that as a side-effect, this updates the current reference context
+* (unit, type or method) in case the problem handler decides it is necessary
+* to abort.
+*/
+
+public ProblemReporter problemReporter() {
+ ProblemReporter problemReporter = referenceContext.problemReporter;
+ problemReporter.referenceContext = referenceContext;
+ return problemReporter;
+}
+
+/*
+What do we hold onto:
+
+1. when we resolve 'a.b.c', say we keep only 'a.b.c'
+ & when we fail to resolve 'c' in 'a.b', lets keep 'a.b.c'
+THEN when we come across a new/changed/removed item named 'a.b.c',
+ we would find all references to 'a.b.c'
+-> This approach fails because every type is resolved in every onDemand import to
+ detect collision cases... so the references could be 10 times bigger than necessary.
+
+2. when we resolve 'a.b.c', lets keep 'a.b' & 'c'
+ & when we fail to resolve 'c' in 'a.b', lets keep 'a.b' & 'c'
+THEN when we come across a new/changed/removed item named 'a.b.c',
+ we would find all references to 'a.b' & 'c'
+-> This approach does not have a space problem but fails to handle collision cases.
+ What happens if a type is added named 'a.b'? We would search for 'a' & 'b' but
+ would not find a match.
+
+3. when we resolve 'a.b.c', lets keep 'a', 'a.b' & 'a', 'b', 'c'
+ & when we fail to resolve 'c' in 'a.b', lets keep 'a', 'a.b' & 'a', 'b', 'c'
+THEN when we come across a new/changed/removed item named 'a.b.c',
+ we would find all references to 'a.b' & 'c'
+OR 'a.b' -> 'a' & 'b'
+OR 'a' -> '' & 'a'
+-> As long as each single char[] is interned, we should not have a space problem
+ and can handle collision cases.
+
+4. when we resolve 'a.b.c', lets keep 'a.b' & 'a', 'b', 'c'
+ & when we fail to resolve 'c' in 'a.b', lets keep 'a.b' & 'a', 'b', 'c'
+THEN when we come across a new/changed/removed item named 'a.b.c',
+ we would find all references to 'a.b' & 'c'
+OR 'a.b' -> 'a' & 'b' in the simple name collection
+OR 'a' -> 'a' in the simple name collection
+-> As long as each single char[] is interned, we should not have a space problem
+ and can handle collision cases.
+*/
+void recordQualifiedReference(char[][] qualifiedName) {
+ if (qualifiedReferences == null) return; // not recording dependencies
+
+ int length = qualifiedName.length;
+ if (length > 1) {
+ while (!qualifiedReferences.contains(qualifiedName)) {
+ qualifiedReferences.add(qualifiedName);
+ if (length == 2) {
+ recordSimpleReference(qualifiedName[0]);
+ recordSimpleReference(qualifiedName[1]);
+ return;
+ }
+ length--;
+ recordSimpleReference(qualifiedName[length]);
+ System.arraycopy(qualifiedName, 0, qualifiedName = new char[length][], 0, length);
+ }
+ } else if (length == 1) {
+ recordSimpleReference(qualifiedName[0]);
+ }
+}
+void recordReference(char[][] qualifiedEnclosingName, char[] simpleName) {
+ recordQualifiedReference(qualifiedEnclosingName);
+ recordSimpleReference(simpleName);
+}
+void recordSimpleReference(char[] simpleName) {
+ if (simpleNameReferences == null) return; // not recording dependencies
+
+ if (!simpleNameReferences.contains(simpleName))
+ simpleNameReferences.add(simpleName);
+}
+void recordTypeReference(TypeBinding type) {
+ if (referencedTypes == null) return; // not recording dependencies
+
+ if (type.isArrayType())
+ type = ((ArrayBinding) type).leafComponentType;
+
+ if (type.isBaseType()) return;
+ if (referencedTypes.containsIdentical(type)) return;
+ if (((ReferenceBinding) type).isLocalType()) return;
+
+ referencedTypes.add(type);
+}
+void recordTypeReferences(TypeBinding[] types) {
+ if (qualifiedReferences == null) return; // not recording dependencies
+ if (types == null || types.length == 0) return;
+
+ for (int i = 0, max = types.length; i < max; i++) {
+ // No need to record supertypes of method arguments & thrown exceptions, just the compoundName
+ // If a field/method is retrieved from such a type then a separate call does the job
+ TypeBinding type = types[i];
+ if (type.isArrayType())
+ type = ((ArrayBinding) type).leafComponentType;
+ if (!type.isBaseType()) {
+ ReferenceBinding actualType = (ReferenceBinding) type;
+ if (!actualType.isLocalType())
+ recordQualifiedReference(actualType.isMemberType()
+ ? CharOperation.splitOn('.', actualType.readableName())
+ : actualType.compoundName);
+ }
+ }
+}
+Binding resolveSingleTypeImport(ImportBinding importBinding) {
+ if (importBinding.resolvedImport == null) {
+ importBinding.resolvedImport = findSingleTypeImport(importBinding.compoundName);
+ if (!importBinding.resolvedImport.isValidBinding() || importBinding.resolvedImport instanceof PackageBinding) {
+ if (this.imports != null){
+ ImportBinding[] newImports = new ImportBinding[imports.length - 1];
+ for (int i = 0, n = 0, max = this.imports.length; i < max; i++)
+ if (this.imports[i] != importBinding){
+ newImports[n++] = this.imports[i];
+ }
+ this.imports = newImports;
+ }
+ return null;
+ }
+ }
+ return importBinding.resolvedImport;
+}
+public void storeDependencyInfo() {
+ // add the type hierarchy of each referenced type
+ // cannot do early since the hierarchy may not be fully resolved
+ for (int i = 0; i < referencedTypes.size; i++) { // grows as more types are added
+ ReferenceBinding type = (ReferenceBinding) referencedTypes.elementAt(i);
+ if (!type.isLocalType()) {
+ recordQualifiedReference(type.isMemberType()
+ ? CharOperation.splitOn('.', type.readableName())
+ : type.compoundName);
+ ReferenceBinding enclosing = type.enclosingType();
+ if (enclosing != null && !referencedTypes.containsIdentical(enclosing))
+ referencedTypes.add(enclosing); // to record its supertypes
+ }
+ ReferenceBinding superclass = type.superclass();
+ if (superclass != null && !referencedTypes.containsIdentical(superclass))
+ referencedTypes.add(superclass); // to record its supertypes
+ ReferenceBinding[] interfaces = type.superInterfaces();
+ if (interfaces != null && interfaces.length > 0)
+ for (int j = 0, length = interfaces.length; j < length; j++)
+ if (!referencedTypes.containsIdentical(interfaces[j]))
+ referencedTypes.add(interfaces[j]); // to record its supertypes
+ }
+
+ int size = qualifiedReferences.size;
+ char[][][] qualifiedRefs = new char[size][][];
+ for (int i = 0; i < size; i++)
+ qualifiedRefs[i] = qualifiedReferences.elementAt(i);
+ referenceContext.compilationResult.qualifiedReferences = qualifiedRefs;
+
+ size = simpleNameReferences.size;
+ char[][] simpleRefs = new char[size][];
+ for (int i = 0; i < size; i++)
+ simpleRefs[i] = simpleNameReferences.elementAt(i);
+ referenceContext.compilationResult.simpleNameReferences = simpleRefs;
+}
+public String toString() {
+ return "--- CompilationUnit Scope : " + new String(referenceContext.getFileName()); //$NON-NLS-1$
+}
+public void verifyMethods(MethodVerifier verifier) {
+ for (int i = 0, length = topLevelTypes.length; i < length; i++)
+ topLevelTypes[i].verifyMethods(verifier);
+}
+}