/******************************************************************************* * 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.problem; import org.eclipse.jdt.core.compiler.CharOperation; import org.eclipse.jdt.core.compiler.IProblem; import org.eclipse.jdt.internal.compiler.*; import org.eclipse.jdt.internal.compiler.ast.*; import org.eclipse.jdt.internal.compiler.env.IConstants; import org.eclipse.jdt.internal.compiler.impl.CompilerOptions; import org.eclipse.jdt.internal.compiler.impl.ReferenceContext; import org.eclipse.jdt.internal.compiler.lookup.*; import org.eclipse.jdt.internal.compiler.parser.*; import org.eclipse.jdt.internal.compiler.util.Util; public class ProblemReporter extends ProblemHandler implements ProblemReasons { public ReferenceContext referenceContext; public ProblemReporter(IErrorHandlingPolicy policy, CompilerOptions options, IProblemFactory problemFactory) { super(policy, options, problemFactory); } public void abortDueToInternalError(String errorMessage) { String[] arguments = new String[] {errorMessage}; this.handle( IProblem.Unclassified, arguments, arguments, Error | Abort, 0, 0); } public void abortDueToInternalError(String errorMessage, ASTNode location) { String[] arguments = new String[] {errorMessage}; this.handle( IProblem.Unclassified, arguments, arguments, Error | Abort, location.sourceStart, location.sourceEnd); } public void abstractMethodCannotBeOverridden(SourceTypeBinding type, MethodBinding concreteMethod) { this.handle( // %1 must be abstract since it cannot override the inherited package-private abstract method %2 IProblem.AbstractMethodCannotBeOverridden, new String[] { new String(type.sourceName()), new String( CharOperation.concat( concreteMethod.declaringClass.readableName(), concreteMethod.readableName(), '.'))}, new String[] { new String(type.sourceName()), new String( CharOperation.concat( concreteMethod.declaringClass.shortReadableName(), concreteMethod.shortReadableName(), '.'))}, type.sourceStart(), type.sourceEnd()); } public void abstractMethodInAbstractClass(SourceTypeBinding type, AbstractMethodDeclaration methodDecl) { String[] arguments = new String[] {new String(type.sourceName()), new String(methodDecl.selector)}; this.handle( IProblem.AbstractMethodInAbstractClass, arguments, arguments, methodDecl.sourceStart, methodDecl.sourceEnd); } public void abstractMethodMustBeImplemented(SourceTypeBinding type, MethodBinding abstractMethod) { this.handle( // Must implement the inherited abstract method %1 // 8.4.3 - Every non-abstract subclass of an abstract type, A, must provide a concrete implementation of all of A's methods. IProblem.AbstractMethodMustBeImplemented, new String[] { new String(abstractMethod.selector), typesAsString(abstractMethod.isVarargs(), abstractMethod.parameters, false), new String(abstractMethod.declaringClass.readableName()), new String(type.readableName()), }, new String[] { new String(abstractMethod.selector), typesAsString(abstractMethod.isVarargs(), abstractMethod.parameters, true), new String(abstractMethod.declaringClass.shortReadableName()), new String(type.shortReadableName()), }, type.sourceStart(), type.sourceEnd()); } public void abstractMethodNeedingNoBody(AbstractMethodDeclaration method) { this.handle( IProblem.BodyForAbstractMethod, NoArgument, NoArgument, method.sourceStart, method.sourceEnd, method, method.compilationResult()); } public void alreadyDefinedLabel(char[] labelName, ASTNode location) { String[] arguments = new String[] {new String(labelName)}; this.handle( IProblem.DuplicateLabel, arguments, arguments, location.sourceStart, location.sourceEnd); } public void annotationCircularity(TypeBinding sourceType, TypeBinding otherType, TypeReference reference) { if (sourceType == otherType) this.handle( IProblem.AnnotationCircularitySelfReference, new String[] {new String(sourceType.readableName())}, new String[] {new String(sourceType.shortReadableName())}, reference.sourceStart, reference.sourceEnd); else this.handle( IProblem.AnnotationCircularity, new String[] {new String(sourceType.readableName()), new String(otherType.readableName())}, new String[] {new String(sourceType.shortReadableName()), new String(otherType.shortReadableName())}, reference.sourceStart, reference.sourceEnd); } public void annotationCannotOverrideMethod(MethodBinding overrideMethod, MethodBinding inheritedMethod) { ASTNode location = overrideMethod.sourceMethod(); this.handle( IProblem.AnnotationCannotOverrideMethod, new String[] { new String(overrideMethod.declaringClass.readableName()), new String(inheritedMethod.declaringClass.readableName()), new String(inheritedMethod.selector), typesAsString(inheritedMethod.isVarargs(), inheritedMethod.parameters, false)}, new String[] { new String(overrideMethod.declaringClass.shortReadableName()), new String(inheritedMethod.declaringClass.shortReadableName()), new String(inheritedMethod.selector), typesAsString(inheritedMethod.isVarargs(), inheritedMethod.parameters, true)}, location.sourceStart, location.sourceEnd); } public void annotationFieldNeedConstantInitialization(FieldDeclaration fieldDecl) { String str = new String(fieldDecl.name); this.handle( IProblem.AnnotationFieldNeedConstantInitialization, new String[] { new String(fieldDecl.binding.declaringClass.readableName()), str }, new String[] { new String(fieldDecl.binding.declaringClass.shortReadableName()), str}, fieldDecl.sourceStart, fieldDecl.sourceEnd); } public void annotationMembersCannotHaveParameters(AnnotationMethodDeclaration annotationMethodDeclaration) { this.handle( IProblem.AnnotationMembersCannotHaveParameters, NoArgument, NoArgument, annotationMethodDeclaration.sourceStart, annotationMethodDeclaration.sourceEnd); } public void annotationMembersCannotHaveTypeParameters(AnnotationMethodDeclaration annotationMethodDeclaration) { this.handle( IProblem.AnnotationMembersCannotHaveTypeParameters, NoArgument, NoArgument, annotationMethodDeclaration.sourceStart, annotationMethodDeclaration.sourceEnd); } public void annotationTypeDeclarationCannotHaveConstructor(ConstructorDeclaration constructorDeclaration) { this.handle( IProblem.AnnotationTypeDeclarationCannotHaveConstructor, NoArgument, NoArgument, constructorDeclaration.sourceStart, constructorDeclaration.sourceEnd); } public void annotationTypeDeclarationCannotHaveSuperclass(TypeDeclaration typeDeclaration) { this.handle( IProblem.AnnotationTypeDeclarationCannotHaveSuperclass, NoArgument, NoArgument, typeDeclaration.sourceStart, typeDeclaration.sourceEnd); } public void annotationTypeDeclarationCannotHaveSuperinterfaces(TypeDeclaration typeDeclaration) { this.handle( IProblem.AnnotationTypeDeclarationCannotHaveSuperinterfaces, NoArgument, NoArgument, typeDeclaration.sourceStart, typeDeclaration.sourceEnd); } public void annotationValueMustBeClassLiteral(TypeBinding annotationType, char[] name, Expression value) { String str = new String(name); this.handle( IProblem.AnnotationValueMustBeClassLiteral, new String[] { new String(annotationType.readableName()), str }, new String[] { new String(annotationType.shortReadableName()), str}, value.sourceStart, value.sourceEnd); } public void annotationValueMustBeConstant(TypeBinding annotationType, char[] name, Expression value) { String str = new String(name); this.handle( IProblem.AnnotationValueMustBeConstant, new String[] { new String(annotationType.readableName()), str }, new String[] { new String(annotationType.shortReadableName()), str}, value.sourceStart, value.sourceEnd); } public void anonymousClassCannotExtendFinalClass(Expression expression, TypeBinding type) { this.handle( IProblem.AnonymousClassCannotExtendFinalClass, new String[] {new String(type.readableName())}, new String[] {new String(type.shortReadableName())}, expression.sourceStart, expression.sourceEnd); } public void argumentTypeCannotBeVoid(SourceTypeBinding type, AbstractMethodDeclaration methodDecl, Argument arg) { String[] arguments = new String[] {new String(methodDecl.selector), new String(arg.name)}; this.handle( IProblem.ArgumentTypeCannotBeVoid, arguments, arguments, methodDecl.sourceStart, methodDecl.sourceEnd); } public void argumentTypeCannotBeVoidArray(SourceTypeBinding type, AbstractMethodDeclaration methodDecl, Argument arg) { String[] arguments = new String[] {new String(methodDecl.selector), new String(arg.name)}; this.handle( IProblem.ArgumentTypeCannotBeVoidArray, arguments, arguments, methodDecl.sourceStart, methodDecl.sourceEnd); } public void arrayConstantsOnlyInArrayInitializers(int sourceStart, int sourceEnd) { this.handle( IProblem.ArrayConstantsOnlyInArrayInitializers, NoArgument, NoArgument, sourceStart, sourceEnd); } public void assignmentHasNoEffect(Assignment assignment, char[] name){ String[] arguments = new String[] { new String(name) }; this.handle( IProblem.AssignmentHasNoEffect, arguments, arguments, assignment.sourceStart, assignment.sourceEnd); } public void attemptToReturnNonVoidExpression(ReturnStatement returnStatement, TypeBinding expectedType) { this.handle( IProblem.VoidMethodReturnsValue, new String[] {new String(expectedType.readableName())}, new String[] {new String(expectedType.shortReadableName())}, returnStatement.sourceStart, returnStatement.sourceEnd); } public void attemptToReturnVoidValue(ReturnStatement returnStatement) { this.handle( IProblem.MethodReturnsVoid, NoArgument, NoArgument, returnStatement.sourceStart, returnStatement.sourceEnd); } public void boundHasConflictingArguments(ASTNode location, TypeBinding type) { this.handle( IProblem.BoundHasConflictingArguments, new String[] {new String(type.readableName())}, new String[] {new String(type.shortReadableName())}, location.sourceStart, location.sourceEnd); } public void boundsMustBeAnInterface(ASTNode location, TypeBinding type) { this.handle( IProblem.BoundsMustBeAnInterface, new String[] {new String(type.readableName())}, new String[] {new String(type.shortReadableName())}, location.sourceStart, location.sourceEnd); } public void bytecodeExceeds64KLimit(AbstractMethodDeclaration location) { MethodBinding method = location.binding; if (location.isConstructor()) { this.handle( IProblem.BytecodeExceeds64KLimitForConstructor, new String[] {new String(location.selector), typesAsString(method.isVarargs(), method.parameters, false)}, new String[] {new String(location.selector), typesAsString(method.isVarargs(), method.parameters, true)}, Error | Abort, location.sourceStart, location.sourceEnd); } else { this.handle( IProblem.BytecodeExceeds64KLimit, new String[] {new String(location.selector), typesAsString(method.isVarargs(), method.parameters, false)}, new String[] {new String(location.selector), typesAsString(method.isVarargs(), method.parameters, true)}, Error | Abort, location.sourceStart, location.sourceEnd); } } public void bytecodeExceeds64KLimit(TypeDeclaration location) { this.handle( IProblem.BytecodeExceeds64KLimitForClinit, NoArgument, NoArgument, Error | Abort, location.sourceStart, location.sourceEnd); } public void cannotAllocateVoidArray(Expression expression) { this.handle( IProblem.CannotAllocateVoidArray, NoArgument, NoArgument, expression.sourceStart, expression.sourceEnd); } public void cannotAssignToFinalField(FieldBinding field, ASTNode location) { this.handle( IProblem.FinalFieldAssignment, new String[] { (field.declaringClass == null ? "array" : new String(field.declaringClass.readableName())), //$NON-NLS-1$ new String(field.readableName())}, new String[] { (field.declaringClass == null ? "array" : new String(field.declaringClass.shortReadableName())), //$NON-NLS-1$ new String(field.shortReadableName())}, location.sourceStart, location.sourceEnd); } public void cannotAssignToFinalLocal(LocalVariableBinding local, ASTNode location) { String[] arguments = new String[] { new String(local.readableName())}; this.handle( IProblem.NonBlankFinalLocalAssignment, arguments, arguments, location.sourceStart, location.sourceEnd); } public void cannotAssignToFinalOuterLocal(LocalVariableBinding local, ASTNode location) { String[] arguments = new String[] {new String(local.readableName())}; this.handle( IProblem.FinalOuterLocalAssignment, arguments, arguments, location.sourceStart, location.sourceEnd); } public void cannotDeclareLocalInterface(char[] interfaceName, int sourceStart, int sourceEnd) { String[] arguments = new String[] {new String(interfaceName)}; this.handle( IProblem.CannotDefineInterfaceInLocalType, arguments, arguments, sourceStart, sourceEnd); } public void cannotDefineDimensionsAndInitializer(ArrayAllocationExpression expresssion) { this.handle( IProblem.CannotDefineDimensionExpressionsWithInit, NoArgument, NoArgument, expresssion.sourceStart, expresssion.sourceEnd); } public void cannotDireclyInvokeAbstractMethod(MessageSend messageSend, MethodBinding method) { this.handle( IProblem.DirectInvocationOfAbstractMethod, new String[] {new String(method.declaringClass.readableName()), new String(method.selector), typesAsString(method.isVarargs(), method.parameters, false)}, new String[] {new String(method.declaringClass.shortReadableName()), new String(method.selector), typesAsString(method.isVarargs(), method.parameters, true)}, messageSend.sourceStart, messageSend.sourceEnd); } public void cannotExtendEnum(SourceTypeBinding type, TypeReference superclass, TypeBinding superTypeBinding) { String name = new String(type.sourceName()); String superTypeFullName = new String(superTypeBinding.readableName()); String superTypeShortName = new String(superTypeBinding.shortReadableName()); if (superTypeShortName.equals(name)) superTypeShortName = superTypeFullName; this.handle( IProblem.CannotExtendEnum, new String[] {superTypeFullName, name}, new String[] {superTypeShortName, name}, superclass.sourceStart, superclass.sourceEnd); } public void cannotImportPackage(ImportReference importRef) { String[] arguments = new String[] {CharOperation.toString(importRef.tokens)}; this.handle( IProblem.CannotImportPackage, arguments, arguments, importRef.sourceStart, importRef.sourceEnd); } public void cannotInstantiate(TypeReference typeRef, TypeBinding type) { this.handle( IProblem.InvalidClassInstantiation, new String[] {new String(type.readableName())}, new String[] {new String(type.shortReadableName())}, typeRef.sourceStart, typeRef.sourceEnd); } public void cannotReferToNonFinalOuterLocal(LocalVariableBinding local, ASTNode location) { String[] arguments =new String[]{ new String(local.readableName())}; this.handle( IProblem.OuterLocalMustBeFinal, arguments, arguments, location.sourceStart, location.sourceEnd); } public void cannotReturnInInitializer(ASTNode location) { this.handle( IProblem.CannotReturnInInitializer, NoArgument, NoArgument, location.sourceStart, location.sourceEnd); } public void cannotThrowNull(ThrowStatement statement) { this.handle( IProblem.CannotThrowNull, NoArgument, NoArgument, statement.sourceStart, statement.sourceEnd); } public void cannotThrowType(SourceTypeBinding type, AbstractMethodDeclaration methodDecl, TypeReference exceptionType, TypeBinding expectedType) { this.handle( IProblem.CannotThrowType, new String[] {new String(expectedType.readableName())}, new String[] {new String(expectedType.shortReadableName())}, exceptionType.sourceStart, exceptionType.sourceEnd); } public void cannotUseSuperInCodeSnippet(int start, int end) { this.handle( IProblem.CannotUseSuperInCodeSnippet, NoArgument, NoArgument, Error | Abort, start, end); } public void cannotUseSuperInJavaLangObject(ASTNode reference) { this.handle( IProblem.ObjectHasNoSuperclass, NoArgument, NoArgument, reference.sourceStart, reference.sourceEnd); } public void cannotUseQualifiedEnumConstantInCaseLabel(QualifiedNameReference reference) { String[] arguments = new String[]{ String.valueOf(reference.fieldBinding().name) }; this.handle( IProblem.IllegalQualifiedEnumConstantLabel, arguments, arguments, reference.sourceStart, reference.sourceEnd); } public void caseExpressionMustBeConstant(Expression expression) { this.handle( IProblem.NonConstantExpression, NoArgument, NoArgument, expression.sourceStart, expression.sourceEnd); } public void classExtendFinalClass(SourceTypeBinding type, TypeReference superclass, TypeBinding superTypeBinding) { String name = new String(type.sourceName()); String superTypeFullName = new String(superTypeBinding.readableName()); String superTypeShortName = new String(superTypeBinding.shortReadableName()); if (superTypeShortName.equals(name)) superTypeShortName = superTypeFullName; this.handle( IProblem.ClassExtendFinalClass, new String[] {superTypeFullName, name}, new String[] {superTypeShortName, name}, superclass.sourceStart, superclass.sourceEnd); } public void codeSnippetMissingClass(String missing, int start, int end) { String[] arguments = new String[]{missing}; this.handle( IProblem.CodeSnippetMissingClass, arguments, arguments, Error | Abort, start, end); } public void codeSnippetMissingMethod(String className, String missingMethod, String argumentTypes, int start, int end) { String[] arguments = new String[]{ className, missingMethod, argumentTypes }; this.handle( IProblem.CodeSnippetMissingMethod, arguments, arguments, Error | Abort, start, end); } /* * Given the current configuration, answers which category the problem * falls into: * Error | Warning | Ignore */ public int computeSeverity(int problemId){ // severity can have been preset on the problem // if ((problem.severity & Fatal) != 0){ // return Error; // } // if not then check whether it is a configurable problem switch(problemId){ case IProblem.MaskedCatch : return this.options.getSeverity(CompilerOptions.MaskedCatchBlock); case IProblem.UnusedImport : return this.options.getSeverity(CompilerOptions.UnusedImport); case IProblem.MethodButWithConstructorName : return this.options.getSeverity(CompilerOptions.MethodWithConstructorName); case IProblem.OverridingNonVisibleMethod : return this.options.getSeverity(CompilerOptions.OverriddenPackageDefaultMethod); case IProblem.IncompatibleReturnTypeForNonInheritedInterfaceMethod : case IProblem.IncompatibleExceptionInThrowsClauseForNonInheritedInterfaceMethod : return this.options.getSeverity(CompilerOptions.IncompatibleNonInheritedInterfaceMethod); case IProblem.OverridingDeprecatedMethod : case IProblem.UsingDeprecatedType : case IProblem.UsingDeprecatedMethod : case IProblem.UsingDeprecatedConstructor : case IProblem.UsingDeprecatedField : return this.options.getSeverity(CompilerOptions.UsingDeprecatedAPI); case IProblem.LocalVariableIsNeverUsed : return this.options.getSeverity(CompilerOptions.UnusedLocalVariable); case IProblem.ArgumentIsNeverUsed : return this.options.getSeverity(CompilerOptions.UnusedArgument); case IProblem.NoImplicitStringConversionForCharArrayExpression : return this.options.getSeverity(CompilerOptions.NoImplicitStringConversion); case IProblem.NeedToEmulateFieldReadAccess : case IProblem.NeedToEmulateFieldWriteAccess : case IProblem.NeedToEmulateMethodAccess : case IProblem.NeedToEmulateConstructorAccess : return this.options.getSeverity(CompilerOptions.AccessEmulation); case IProblem.NonExternalizedStringLiteral : return this.options.getSeverity(CompilerOptions.NonExternalizedString); case IProblem.UseAssertAsAnIdentifier : return this.options.getSeverity(CompilerOptions.AssertUsedAsAnIdentifier); case IProblem.UseEnumAsAnIdentifier : return this.options.getSeverity(CompilerOptions.EnumUsedAsAnIdentifier); case IProblem.NonStaticAccessToStaticMethod : case IProblem.NonStaticAccessToStaticField : return this.options.getSeverity(CompilerOptions.NonStaticAccessToStatic); case IProblem.IndirectAccessToStaticMethod : case IProblem.IndirectAccessToStaticField : case IProblem.IndirectAccessToStaticType : return this.options.getSeverity(CompilerOptions.IndirectStaticAccess); case IProblem.AssignmentHasNoEffect: return this.options.getSeverity(CompilerOptions.NoEffectAssignment); case IProblem.UnusedPrivateConstructor: case IProblem.UnusedPrivateMethod: case IProblem.UnusedPrivateField: case IProblem.UnusedPrivateType: return this.options.getSeverity(CompilerOptions.UnusedPrivateMember); case IProblem.Task : return Warning; case IProblem.LocalVariableHidingLocalVariable: case IProblem.LocalVariableHidingField: case IProblem.ArgumentHidingLocalVariable: case IProblem.ArgumentHidingField: return this.options.getSeverity(CompilerOptions.LocalVariableHiding); case IProblem.FieldHidingLocalVariable: case IProblem.FieldHidingField: return this.options.getSeverity(CompilerOptions.FieldHiding); case IProblem.PossibleAccidentalBooleanAssignment: return this.options.getSeverity(CompilerOptions.AccidentalBooleanAssign); case IProblem.SuperfluousSemicolon: case IProblem.EmptyControlFlowStatement: return this.options.getSeverity(CompilerOptions.EmptyStatement); case IProblem.UndocumentedEmptyBlock: return this.options.getSeverity(CompilerOptions.UndocumentedEmptyBlock); case IProblem.UnnecessaryCast: case IProblem.UnnecessaryArgumentCast: case IProblem.UnnecessaryInstanceof: return this.options.getSeverity(CompilerOptions.UnnecessaryTypeCheck); case IProblem.FinallyMustCompleteNormally: return this.options.getSeverity(CompilerOptions.FinallyBlockNotCompleting); case IProblem.UnusedMethodDeclaredThrownException: case IProblem.UnusedConstructorDeclaredThrownException: return this.options.getSeverity(CompilerOptions.UnusedDeclaredThrownException); case IProblem.UnqualifiedFieldAccess: return this.options.getSeverity(CompilerOptions.UnqualifiedFieldAccess); case IProblem.UnnecessaryElse: return this.options.getSeverity(CompilerOptions.UnnecessaryElse); case IProblem.UnsafeRawConstructorInvocation: case IProblem.UnsafeRawMethodInvocation: case IProblem.UnsafeRawConversion: case IProblem.UnsafeRawFieldAssignment: case IProblem.UnsafeGenericCast: case IProblem.UnsafeReturnTypeOverride: return this.options.getSeverity(CompilerOptions.UnsafeTypeOperation); case IProblem.FinalBoundForTypeVariable: return this.options.getSeverity(CompilerOptions.FinalParameterBound); case IProblem.MissingSerialVersion: return this.options.getSeverity(CompilerOptions.MissingSerialVersion); case IProblem.ForbiddenReference: return this.options.getSeverity(CompilerOptions.ForbiddenReference); case IProblem.MethodVarargsArgumentNeedCast : case IProblem.ConstructorVarargsArgumentNeedCast : return this.options.getSeverity(CompilerOptions.VarargsArgumentNeedCast); case IProblem.LocalVariableCannotBeNull : case IProblem.LocalVariableCanOnlyBeNull : return this.options.getSeverity(CompilerOptions.InconsistentNullCheck); /* * Javadoc syntax errors */ case IProblem.JavadocUnexpectedTag: case IProblem.JavadocDuplicateReturnTag: case IProblem.JavadocInvalidThrowsClass: case IProblem.JavadocInvalidReference: case IProblem.JavadocInvalidParamTagName: case IProblem.JavadocInvalidParamTagTypeParameter: case IProblem.JavadocMalformedSeeReference: case IProblem.JavadocInvalidSeeHref: case IProblem.JavadocInvalidSeeArgs: case IProblem.JavadocInvalidTag: case IProblem.JavadocUnterminatedInlineTag: case IProblem.JavadocMissingHashCharacter: case IProblem.JavadocEmptyReturnTag: case IProblem.JavadocUnexpectedText: if (this.options.docCommentSupport) { return this.options.getSeverity(CompilerOptions.InvalidJavadoc); } else { return ProblemSeverities.Ignore; } /* * Javadoc tags resolved references errors */ case IProblem.JavadocInvalidParamName: case IProblem.JavadocDuplicateParamName: case IProblem.JavadocMissingParamName: case IProblem.JavadocInvalidThrowsClassName: case IProblem.JavadocDuplicateThrowsClassName: case IProblem.JavadocMissingThrowsClassName: case IProblem.JavadocMissingReference: case IProblem.JavadocInvalidValueReference: case IProblem.JavadocUndefinedField: case IProblem.JavadocAmbiguousField: case IProblem.JavadocUndefinedConstructor: case IProblem.JavadocAmbiguousConstructor: case IProblem.JavadocUndefinedMethod: case IProblem.JavadocAmbiguousMethod: case IProblem.JavadocAmbiguousMethodReference: case IProblem.JavadocParameterMismatch: case IProblem.JavadocUndefinedType: case IProblem.JavadocAmbiguousType: case IProblem.JavadocInternalTypeNameProvided: case IProblem.JavadocNoMessageSendOnArrayType: case IProblem.JavadocNoMessageSendOnBaseType: case IProblem.JavadocInheritedMethodHidesEnclosingName: case IProblem.JavadocInheritedFieldHidesEnclosingName: case IProblem.JavadocInheritedNameHidesEnclosingTypeName: if (this.options.docCommentSupport && this.options.reportInvalidJavadocTags) { return this.options.getSeverity(CompilerOptions.InvalidJavadoc); } return ProblemSeverities.Ignore; /* * Javadoc invalid tags due to deprecated references */ case IProblem.JavadocUsingDeprecatedField: case IProblem.JavadocUsingDeprecatedConstructor: case IProblem.JavadocUsingDeprecatedMethod: case IProblem.JavadocUsingDeprecatedType: if (this.options.docCommentSupport && this.options.reportInvalidJavadocTags && this.options.reportInvalidJavadocTagsDeprecatedRef) { return this.options.getSeverity(CompilerOptions.InvalidJavadoc); } return ProblemSeverities.Ignore; /* * Javadoc invalid tags due to non-visible references */ case IProblem.JavadocNotVisibleField: case IProblem.JavadocNotVisibleConstructor: case IProblem.JavadocNotVisibleMethod: case IProblem.JavadocNotVisibleType: if (this.options.docCommentSupport && this.options.reportInvalidJavadocTags && this.options.reportInvalidJavadocTagsNotVisibleRef) { return this.options.getSeverity(CompilerOptions.InvalidJavadoc); } return ProblemSeverities.Ignore; /* * Javadoc missing tags errors */ case IProblem.JavadocMissingParamTag: case IProblem.JavadocMissingReturnTag: case IProblem.JavadocMissingThrowsTag: if (this.options.docCommentSupport) { return this.options.getSeverity(CompilerOptions.MissingJavadocTags); } else { return ProblemSeverities.Ignore; } /* * Missing Javadoc errors */ case IProblem.JavadocMissing: if (this.options.docCommentSupport) { return this.options.getSeverity(CompilerOptions.MissingJavadocComments); } else { return ProblemSeverities.Ignore; } // by default problems are errors. default: return Error; } } public void conditionalArgumentsIncompatibleTypes(ConditionalExpression expression, TypeBinding trueType, TypeBinding falseType) { this.handle( IProblem.IncompatibleTypesInConditionalOperator, new String[] {new String(trueType.readableName()), new String(falseType.readableName())}, new String[] {new String(trueType.sourceName()), new String(falseType.sourceName())}, expression.sourceStart, expression.sourceEnd); } public void conflictingImport(ImportReference importRef) { String[] arguments = new String[] {CharOperation.toString(importRef.tokens)}; this.handle( IProblem.ConflictingImport, arguments, arguments, importRef.sourceStart, importRef.sourceEnd); } public void constantOutOfFormat(NumberLiteral literal) { // the literal is not in a correct format // this code is called on IntLiteral and LongLiteral // example 000811 ...the 8 is uncorrect. if ((literal instanceof LongLiteral) || (literal instanceof IntLiteral)) { char[] source = literal.source(); try { final String Radix; final int radix; if ((source[1] == 'x') || (source[1] == 'X')) { radix = 16; Radix = "Hex"; //$NON-NLS-1$ } else { radix = 8; Radix = "Octal"; //$NON-NLS-1$ } //look for the first digit that is incorrect int place = -1; label : for (int i = radix == 8 ? 1 : 2; i < source.length; i++) { if (Character.digit(source[i], radix) == -1) { place = i; break label; } } String[] arguments = new String[] { new String(literal.literalType(null).readableName()), // numeric literals do not need scope to reach type Radix + " " + new String(source) + " (digit " + new String(new char[] {source[place]}) + ")"}; //$NON-NLS-1$ //$NON-NLS-2$ //$NON-NLS-3$ this.handle( IProblem.NumericValueOutOfRange, arguments, arguments, literal.sourceStart, literal.sourceEnd); return; } catch (IndexOutOfBoundsException ex) { // should never happen } // just in case .... use a predefined error.. // we should never come here...(except if the code changes !) this.constantOutOfRange(literal, literal.literalType(null)); // numeric literals do not need scope to reach type } } public void constantOutOfRange(Literal literal, TypeBinding literalType) { String[] arguments = new String[] {new String(literalType.readableName()), new String(literal.source())}; this.handle( IProblem.NumericValueOutOfRange, arguments, arguments, literal.sourceStart, literal.sourceEnd); } public void corruptedSignature(TypeBinding enclosingType, char[] signature, int position) { this.handle( IProblem.CorruptedSignature, new String[] { new String(enclosingType.readableName()), new String(signature), String.valueOf(position) }, new String[] { new String(enclosingType.shortReadableName()), new String(signature), String.valueOf(position) }, Error | Abort, 0, 0); } public void deprecatedField(FieldBinding field, ASTNode location) { this.handle( IProblem.UsingDeprecatedField, new String[] {new String(field.declaringClass.readableName()), new String(field.name)}, new String[] {new String(field.declaringClass.shortReadableName()), new String(field.name)}, location.sourceStart, location.sourceEnd); } public void deprecatedMethod(MethodBinding method, ASTNode location) { if (method.isConstructor()) { this.handle( IProblem.UsingDeprecatedConstructor, new String[] {new String(method.declaringClass.readableName()), typesAsString(method.isVarargs(), method.parameters, false)}, new String[] {new String(method.declaringClass.shortReadableName()), typesAsString(method.isVarargs(), method.parameters, true)}, location.sourceStart, location.sourceEnd); } else { this.handle( IProblem.UsingDeprecatedMethod, new String[] {new String(method.declaringClass.readableName()), new String(method.selector), typesAsString(method.isVarargs(), method.parameters, false)}, new String[] {new String(method.declaringClass.shortReadableName()), new String(method.selector), typesAsString(method.isVarargs(), method.parameters, true)}, location.sourceStart, location.sourceEnd); } } public void methodMustOverride(AbstractMethodDeclaration method) { MethodBinding binding = method.binding; this.handle( IProblem.MethodMustOverride, new String[] {new String(binding.selector), typesAsString(binding.isVarargs(), binding.parameters, false), new String(binding.declaringClass.readableName()), }, new String[] {new String(binding.selector), typesAsString(binding.isVarargs(), binding.parameters, true), new String(binding.declaringClass.shortReadableName()),}, method.sourceStart, method.sourceEnd); } public void deprecatedType(TypeBinding type, ASTNode location) { if (location == null) return; // 1G828DN - no type ref for synthetic arguments this.handle( IProblem.UsingDeprecatedType, new String[] {new String(type.readableName())}, new String[] {new String(type.shortReadableName())}, location.sourceStart, location.sourceEnd); } public void duplicateAnnotation(Annotation annotation) { this.handle( IProblem.DuplicateAnnotation, new String[] {new String(annotation.resolvedType.readableName())}, new String[] {new String(annotation.resolvedType.shortReadableName())}, annotation.sourceStart, annotation.sourceEnd); } public void duplicateAnnotationValue(TypeBinding annotationType, MemberValuePair memberValuePair) { String name = new String(memberValuePair.name); this.handle( IProblem.DuplicateAnnotationMember, new String[] { name, new String(annotationType.readableName())}, new String[] { name, new String(annotationType.shortReadableName())}, memberValuePair.sourceStart, memberValuePair.sourceEnd); } public void duplicateTargetInTargetAnnotation(TypeBinding annotationType, NameReference reference) { String name = new String(reference.fieldBinding().name); this.handle( IProblem.DuplicateTargetInTargetAnnotation, new String[] { name, new String(annotationType.readableName())}, new String[] { name, new String(annotationType.shortReadableName())}, reference.sourceStart, reference.sourceEnd); } public void duplicateCase(CaseStatement caseStatement) { this.handle( IProblem.DuplicateCase, NoArgument, NoArgument, caseStatement.sourceStart, caseStatement.sourceEnd); } public void duplicateDefaultCase(ASTNode statement) { this.handle( IProblem.DuplicateDefaultCase, NoArgument, NoArgument, statement.sourceStart, statement.sourceEnd); } public void duplicateFieldInType(SourceTypeBinding type, FieldDeclaration fieldDecl) { this.handle( IProblem.DuplicateField, new String[] {new String(type.sourceName()), new String(fieldDecl.name)}, new String[] {new String(type.shortReadableName()), new String(fieldDecl.name)}, fieldDecl.sourceStart, fieldDecl.sourceEnd); } public void duplicateImport(ImportReference importRef) { String[] arguments = new String[] {CharOperation.toString(importRef.tokens)}; this.handle( IProblem.DuplicateImport, arguments, arguments, importRef.sourceStart, importRef.sourceEnd); } public void duplicateInheritedMethods(SourceTypeBinding type, MethodBinding inheritedMethod1, MethodBinding inheritedMethod2) { this.handle( IProblem.DuplicateParameterizedMethods, new String[] { new String(inheritedMethod1.selector), new String(inheritedMethod1.declaringClass.readableName()), typesAsString(inheritedMethod1.isVarargs(), inheritedMethod1.original().parameters, false), typesAsString(inheritedMethod2.isVarargs(), inheritedMethod2.original().parameters, false)}, new String[] { new String(inheritedMethod1.selector), new String(inheritedMethod1.declaringClass.shortReadableName()), typesAsString(inheritedMethod1.isVarargs(), inheritedMethod1.original().parameters, true), typesAsString(inheritedMethod2.isVarargs(), inheritedMethod2.original().parameters, true)}, type.sourceStart(), type.sourceEnd()); } public void duplicateInitializationOfBlankFinalField(FieldBinding field, Reference reference) { String[] arguments = new String[]{ new String(field.readableName())}; this.handle( IProblem.DuplicateBlankFinalFieldInitialization, arguments, arguments, reference.sourceStart, reference.sourceEnd); } public void duplicateInitializationOfFinalLocal(LocalVariableBinding local, ASTNode location) { String[] arguments = new String[] { new String(local.readableName())}; this.handle( IProblem.DuplicateFinalLocalInitialization, arguments, arguments, location.sourceStart, location.sourceEnd); } public void duplicateEnumSpecialMethod(SourceTypeBinding type, AbstractMethodDeclaration methodDecl) { MethodBinding method = methodDecl.binding; this.handle( IProblem.CannotDeclareEnumSpecialMethod, new String[] { new String(methodDecl.selector), new String(method.declaringClass.readableName()), typesAsString(method.isVarargs(), method.parameters, false)}, new String[] { new String(methodDecl.selector), new String(method.declaringClass.shortReadableName()), typesAsString(method.isVarargs(), method.parameters, true)}, methodDecl.sourceStart, methodDecl.sourceEnd); } public void duplicateMethodInType(SourceTypeBinding type, AbstractMethodDeclaration methodDecl) { MethodBinding method = methodDecl.binding; boolean duplicateErasure = false; if ((method.modifiers & CompilerModifiers.AccGenericSignature) != 0) { // chech it occurs in parameters (the bit is set for return type | params | thrown exceptions for (int i = 0, length = method.parameters.length; i < length; i++) { if ((method.parameters[i].tagBits & TagBits.HasTypeVariable) != 0) { duplicateErasure = true; break; } } } if (duplicateErasure) { int length = method.parameters.length; TypeBinding[] erasures = new TypeBinding[length]; for (int i = 0; i < length; i++) { erasures[i] = method.parameters[i].erasure(); } this.handle( IProblem.DuplicateMethodErasure, new String[] { new String(methodDecl.selector), new String(method.declaringClass.readableName()), typesAsString(method.isVarargs(), method.parameters, false), typesAsString(method.isVarargs(), erasures, false) } , new String[] { new String(methodDecl.selector), new String(method.declaringClass.shortReadableName()), typesAsString(method.isVarargs(), method.parameters, true), typesAsString(method.isVarargs(), erasures, true) }, methodDecl.sourceStart, methodDecl.sourceEnd); } else { this.handle( IProblem.DuplicateMethod, new String[] { new String(methodDecl.selector), new String(method.declaringClass.readableName()), typesAsString(method.isVarargs(), method.parameters, false)}, new String[] { new String(methodDecl.selector), new String(method.declaringClass.shortReadableName()), typesAsString(method.isVarargs(), method.parameters, true)}, methodDecl.sourceStart, methodDecl.sourceEnd); } } public void duplicateModifierForField(ReferenceBinding type, FieldDeclaration fieldDecl) { /* to highlight modifiers use: this.handle( new Problem( DuplicateModifierForField, new String[] {new String(fieldDecl.name)}, fieldDecl.modifiers.sourceStart, fieldDecl.modifiers.sourceEnd)); */ String[] arguments = new String[] {new String(fieldDecl.name)}; this.handle( IProblem.DuplicateModifierForField, arguments, arguments, fieldDecl.sourceStart, fieldDecl.sourceEnd); } public void duplicateModifierForMethod(ReferenceBinding type, AbstractMethodDeclaration methodDecl) { this.handle( IProblem.DuplicateModifierForMethod, new String[] {new String(type.sourceName()), new String(methodDecl.selector)}, new String[] {new String(type.shortReadableName()), new String(methodDecl.selector)}, methodDecl.sourceStart, methodDecl.sourceEnd); } public void duplicateModifierForType(SourceTypeBinding type) { String[] arguments = new String[] {new String(type.sourceName())}; this.handle( IProblem.DuplicateModifierForType, arguments, arguments, type.sourceStart(), type.sourceEnd()); } public void duplicateModifierForVariable(LocalDeclaration localDecl, boolean complainForArgument) { String[] arguments = new String[] {new String(localDecl.name)}; this.handle( complainForArgument ? IProblem.DuplicateModifierForArgument : IProblem.DuplicateModifierForVariable, arguments, arguments, localDecl.sourceStart, localDecl.sourceEnd); } public void duplicateNestedType(TypeDeclaration typeDecl) { String[] arguments = new String[] {new String(typeDecl.name)}; this.handle( IProblem.DuplicateNestedType, arguments, arguments, typeDecl.sourceStart, typeDecl.sourceEnd); } public void duplicateSuperinterface(SourceTypeBinding type, TypeDeclaration typeDecl, ReferenceBinding superType) { this.handle( IProblem.DuplicateSuperInterface, new String[] { new String(superType.readableName()), new String(type.sourceName())}, new String[] { new String(superType.shortReadableName()), new String(type.sourceName())}, typeDecl.sourceStart, typeDecl.sourceEnd); } public void duplicateTypeParameterInType(TypeParameter typeParameter) { this.handle( IProblem.DuplicateTypeVariable, new String[] { new String(typeParameter.name)}, new String[] { new String(typeParameter.name)}, typeParameter.sourceStart, typeParameter.sourceEnd); } public void duplicateTypes(CompilationUnitDeclaration compUnitDecl, TypeDeclaration typeDecl) { String[] arguments = new String[] {new String(compUnitDecl.getFileName()), new String(typeDecl.name)}; this.referenceContext = typeDecl; // report the problem against the type not the entire compilation unit this.handle( IProblem.DuplicateTypes, arguments, arguments, typeDecl.sourceStart, typeDecl.sourceEnd, compUnitDecl.compilationResult); } public void emptyControlFlowStatement(int sourceStart, int sourceEnd) { this.handle( IProblem.EmptyControlFlowStatement, NoArgument, NoArgument, sourceStart, sourceEnd); } public void enumAbstractMethodMustBeImplemented(AbstractMethodDeclaration method) { MethodBinding abstractMethod = method.binding; this.handle( // Must implement the inherited abstract method %1 // 8.4.3 - Every non-abstract subclass of an abstract type, A, must provide a concrete implementation of all of A's methods. IProblem.EnumAbstractMethodMustBeImplemented, new String[] { new String(abstractMethod.selector), typesAsString(abstractMethod.isVarargs(), abstractMethod.parameters, false), new String(abstractMethod.declaringClass.readableName()), }, new String[] { new String(abstractMethod.selector), typesAsString(abstractMethod.isVarargs(), abstractMethod.parameters, true), new String(abstractMethod.declaringClass.shortReadableName()), }, method.sourceStart(), method.sourceEnd()); } public void errorNoMethodFor(MessageSend messageSend, TypeBinding recType, TypeBinding[] params) { StringBuffer buffer = new StringBuffer(); StringBuffer shortBuffer = new StringBuffer(); for (int i = 0, length = params.length; i < length; i++) { if (i != 0){ buffer.append(", "); //$NON-NLS-1$ shortBuffer.append(", "); //$NON-NLS-1$ } buffer.append(new String(params[i].readableName())); shortBuffer.append(new String(params[i].shortReadableName())); } int id = recType.isArrayType() ? IProblem.NoMessageSendOnArrayType : IProblem.NoMessageSendOnBaseType; /* if ((messageSend.bits & ASTNode.InsideJavadoc) != 0) { id |= IProblem.Javadoc; if (!reportInvalidJavadocTagsVisibility()) return; } */ this.handle( id, new String[] {new String(recType.readableName()), new String(messageSend.selector), buffer.toString()}, new String[] {new String(recType.shortReadableName()), new String(messageSend.selector), shortBuffer.toString()}, messageSend.sourceStart, messageSend.sourceEnd); } public void errorThisSuperInStatic(ASTNode reference) { String[] arguments = new String[] {reference.isSuper() ? "super" : "this"}; //$NON-NLS-2$ //$NON-NLS-1$ this.handle( IProblem.ThisInStaticContext, arguments, arguments, reference.sourceStart, reference.sourceEnd); } public void cannotInvokeSuperConstructorInEnum(ExplicitConstructorCall constructorCall, MethodBinding enumConstructor) { this.handle( IProblem.CannotInvokeSuperConstructorInEnum, new String[] { new String(enumConstructor.declaringClass.sourceName()), typesAsString(enumConstructor.isVarargs(), enumConstructor.parameters, false), }, new String[] { new String(enumConstructor.declaringClass.sourceName()), typesAsString(enumConstructor.isVarargs(), enumConstructor.parameters, true), }, constructorCall.sourceStart, constructorCall.sourceEnd); } public void expressionShouldBeAVariable(Expression expression) { this.handle( IProblem.ExpressionShouldBeAVariable, NoArgument, NoArgument, expression.sourceStart, expression.sourceEnd); } public void fieldHiding(FieldDeclaration fieldDecl, Binding hiddenVariable) { FieldBinding field = fieldDecl.binding; if (CharOperation.equals(TypeConstants.SERIALVERSIONUID, field.name) && field.isStatic() && field.isFinal() && BaseTypes.LongBinding == field.type) { return; // do not report unused serialVersionUID field } if (CharOperation.equals(TypeConstants.SERIALPERSISTENTFIELDS, field.name) && field.isStatic() && field.isFinal() && field.type.dimensions() == 1 && CharOperation.equals(TypeConstants.CharArray_JAVA_IO_OBJECTSTREAMFIELD, field.type.leafComponentType().readableName())) { return; // do not report unused serialPersistentFields field } if (hiddenVariable instanceof LocalVariableBinding) { this.handle( IProblem.FieldHidingLocalVariable, new String[] {new String(field.declaringClass.readableName()), new String(field.name) }, new String[] {new String(field.declaringClass.shortReadableName()), new String(field.name) }, fieldDecl.sourceStart, fieldDecl.sourceEnd); } else if (hiddenVariable instanceof FieldBinding) { FieldBinding hiddenField = (FieldBinding) hiddenVariable; this.handle( IProblem.FieldHidingField, new String[] {new String(field.declaringClass.readableName()), new String(field.name) , new String(hiddenField.declaringClass.readableName()) }, new String[] {new String(field.declaringClass.shortReadableName()), new String(field.name) , new String(hiddenField.declaringClass.shortReadableName()) }, fieldDecl.sourceStart, fieldDecl.sourceEnd); } } private int fieldLocation(FieldBinding field, ASTNode node) { if (node instanceof QualifiedNameReference) { QualifiedNameReference ref = (QualifiedNameReference) node; FieldBinding[] bindings = ref.otherBindings; if (bindings != null) for (int i = bindings.length; --i >= 0;) if (bindings[i] == field) return (int) ref.sourcePositions[i + 1]; // first position is for the primary field } return node.sourceEnd; } public void fieldsOrThisBeforeConstructorInvocation(ThisReference reference) { this.handle( IProblem.ThisSuperDuringConstructorInvocation, NoArgument, NoArgument, reference.sourceStart, reference.sourceEnd); } public void finallyMustCompleteNormally(Block finallyBlock) { this.handle( IProblem.FinallyMustCompleteNormally, NoArgument, NoArgument, finallyBlock.sourceStart, finallyBlock.sourceEnd); } public void finalMethodCannotBeOverridden(MethodBinding currentMethod, MethodBinding inheritedMethod) { this.handle( // Cannot override the final method from %1 // 8.4.3.3 - Final methods cannot be overridden or hidden. IProblem.FinalMethodCannotBeOverridden, new String[] {new String(inheritedMethod.declaringClass.readableName())}, new String[] {new String(inheritedMethod.declaringClass.shortReadableName())}, currentMethod.sourceStart(), currentMethod.sourceEnd()); } public void finalVariableBound(TypeVariableBinding typeVariable, TypeReference typeRef) { this.handle( IProblem.FinalBoundForTypeVariable, new String[] { new String(typeVariable.sourceName), new String(typeRef.resolvedType.readableName())}, new String[] { new String(typeVariable.sourceName), new String(typeRef.resolvedType.shortReadableName())}, typeRef.sourceStart, typeRef.sourceEnd); } public void forbiddenReference(TypeBinding type, ASTNode location, String messageTemplate) { if (location == null) return; // this problem has a message template extracted from the access restriction rule this.handle( IProblem.ForbiddenReference, new String[] { new String(type.readableName()) }, // distinct from msg arg for quickfix purpose new String[] { Util.bindMessage(messageTemplate, new String[]{ new String(type.shortReadableName()) } ) }, location.sourceStart, location.sourceEnd); } public void forwardReference(Reference reference, int indexInQualification, TypeBinding type) { this.handle( IProblem.ReferenceToForwardField, NoArgument, NoArgument, reference.sourceStart, reference.sourceEnd); } public void forwardTypeVariableReference(ASTNode location, TypeVariableBinding type) { this.handle( IProblem.ReferenceToForwardTypeVariable, new String[] {new String(type.readableName())}, new String[] {new String(type.shortReadableName())}, location.sourceStart, location.sourceEnd); } public void genericTypeCannotExtendThrowable(TypeDeclaration typeDecl) { this.handle( IProblem.GenericTypeCannotExtendThrowable, new String[]{ new String(typeDecl.binding.readableName()) }, new String[]{ new String(typeDecl.binding.shortReadableName()) }, typeDecl.superclass.sourceStart, typeDecl.superclass.sourceEnd); } // use this private API when the compilation unit result can be found through the // reference context. Otherwise, use the other API taking a problem and a compilation result // as arguments private void handle( int problemId, String[] problemArguments, String[] messageArguments, int problemStartPosition, int problemEndPosition){ this.handle( problemId, problemArguments, messageArguments, problemStartPosition, problemEndPosition, this.referenceContext, this.referenceContext == null ? null : this.referenceContext.compilationResult()); this.referenceContext = null; } // use this private API when the compilation unit result cannot be found through the // reference context. private void handle( int problemId, String[] problemArguments, String[] messageArguments, int problemStartPosition, int problemEndPosition, CompilationResult unitResult){ this.handle( problemId, problemArguments, messageArguments, problemStartPosition, problemEndPosition, this.referenceContext, unitResult); this.referenceContext = null; } // use this private API when the compilation unit result can be found through the // reference context. Otherwise, use the other API taking a problem and a compilation result // as arguments private void handle( int problemId, String[] problemArguments, String[] messageArguments, int severity, int problemStartPosition, int problemEndPosition){ this.handle( problemId, problemArguments, messageArguments, severity, problemStartPosition, problemEndPosition, this.referenceContext, this.referenceContext == null ? null : this.referenceContext.compilationResult()); this.referenceContext = null; } public void hiddenCatchBlock(ReferenceBinding exceptionType, ASTNode location) { this.handle( IProblem.MaskedCatch, new String[] { new String(exceptionType.readableName()), }, new String[] { new String(exceptionType.shortReadableName()), }, location.sourceStart, location.sourceEnd); } public void hidingEnclosingType(TypeDeclaration typeDecl) { String[] arguments = new String[] {new String(typeDecl.name)}; this.handle( IProblem.HidingEnclosingType, arguments, arguments, typeDecl.sourceStart, typeDecl.sourceEnd); } public void hierarchyCircularity(SourceTypeBinding sourceType, ReferenceBinding superType, TypeReference reference) { int start = 0; int end = 0; if (reference == null) { // can only happen when java.lang.Object is busted start = sourceType.sourceStart(); end = sourceType.sourceEnd(); } else { start = reference.sourceStart; end = reference.sourceEnd; } if (sourceType == superType) this.handle( IProblem.HierarchyCircularitySelfReference, new String[] {new String(sourceType.readableName()) }, new String[] {new String(sourceType.shortReadableName()) }, start, end); else this.handle( IProblem.HierarchyCircularity, new String[] {new String(sourceType.readableName()), new String(superType.readableName())}, new String[] {new String(sourceType.shortReadableName()), new String(superType.shortReadableName())}, start, end); } public void hierarchyHasProblems(SourceTypeBinding type) { String[] arguments = new String[] {new String(type.sourceName())}; this.handle( IProblem.HierarchyHasProblems, arguments, arguments, type.sourceStart(), type.sourceEnd()); } public void illegalAbstractModifierCombinationForMethod(ReferenceBinding type, AbstractMethodDeclaration methodDecl) { String[] arguments = new String[] {new String(type.sourceName()), new String(methodDecl.selector)}; this.handle( IProblem.IllegalAbstractModifierCombinationForMethod, arguments, arguments, methodDecl.sourceStart, methodDecl.sourceEnd); } public void illegalClassLiteralForTypeVariable(TypeVariableBinding variable, ASTNode location) { String[] arguments = new String[] { new String(variable.sourceName) }; this.handle( IProblem.IllegalClassLiteralForTypeVariable, arguments, arguments, location.sourceStart, location.sourceEnd); } public void illegalExtendedDimensions(AnnotationMethodDeclaration annotationTypeMemberDeclaration) { this.handle( IProblem.IllegalExtendedDimensions, NoArgument, NoArgument, annotationTypeMemberDeclaration.sourceStart, annotationTypeMemberDeclaration.sourceEnd); } public void illegalExtendedDimensions(Argument argument) { this.handle( IProblem.IllegalExtendedDimensionsForVarArgs, NoArgument, NoArgument, argument.sourceStart, argument.sourceEnd); } public void illegalGenericArray(TypeBinding leadtComponentType, ASTNode location) { this.handle( IProblem.IllegalGenericArray, new String[]{ new String(leadtComponentType.readableName())}, new String[]{ new String(leadtComponentType.shortReadableName())}, location.sourceStart, location.sourceEnd); } public void illegalInstanceOfGenericType(TypeBinding checkedType, ASTNode location) { if (checkedType.isTypeVariable()) { this.handle( IProblem.IllegalInstanceofTypeParameter, new String[] { new String(checkedType.readableName()), new String(checkedType.erasure().readableName())}, new String[] { new String(checkedType.shortReadableName()), new String(checkedType.erasure().shortReadableName())}, location.sourceStart, location.sourceEnd); return; } this.handle( IProblem.IllegalInstanceofParameterizedType, new String[] { new String(checkedType.readableName()), new String(checkedType.erasure().sourceName())}, new String[] { new String(checkedType.shortReadableName()), new String(checkedType.erasure().sourceName())}, location.sourceStart, location.sourceEnd); } public void illegalModifierCombinationFinalAbstractForClass(SourceTypeBinding type) { String[] arguments = new String[] {new String(type.sourceName())}; this.handle( IProblem.IllegalModifierCombinationFinalAbstractForClass, arguments, arguments, type.sourceStart(), type.sourceEnd()); } public void illegalModifierCombinationFinalVolatileForField(ReferenceBinding type, FieldDeclaration fieldDecl) { String[] arguments = new String[] {new String(fieldDecl.name)}; this.handle( IProblem.IllegalModifierCombinationFinalVolatileForField, arguments, arguments, fieldDecl.sourceStart, fieldDecl.sourceEnd); } public void illegalModifierForClass(SourceTypeBinding type) { String[] arguments = new String[] {new String(type.sourceName())}; this.handle( IProblem.IllegalModifierForClass, arguments, arguments, type.sourceStart(), type.sourceEnd()); } public void illegalModifierForEnum(SourceTypeBinding type) { String[] arguments = new String[] {new String(type.sourceName())}; this.handle( IProblem.IllegalModifierForEnum, arguments, arguments, type.sourceStart(), type.sourceEnd()); } public void illegalModifierForLocalEnum(SourceTypeBinding type) { String[] arguments = new String[] {new String(type.sourceName())}; this.handle( IProblem.IllegalModifierForLocalEnum, arguments, arguments, type.sourceStart(), type.sourceEnd()); } public void illegalModifierForMemberEnum(SourceTypeBinding type) { String[] arguments = new String[] {new String(type.sourceName())}; this.handle( IProblem.IllegalModifierForMemberEnum, arguments, arguments, type.sourceStart(), type.sourceEnd()); } public void illegalModifierForEnumConstant(ReferenceBinding type, FieldDeclaration fieldDecl) { String[] arguments = new String[] {new String(fieldDecl.name)}; this.handle( IProblem.IllegalModifierForEnumConstant, arguments, arguments, fieldDecl.sourceStart, fieldDecl.sourceEnd); } public void illegalModifierForField(ReferenceBinding type, FieldDeclaration fieldDecl) { String[] arguments = new String[] {new String(fieldDecl.name)}; this.handle( IProblem.IllegalModifierForField, arguments, arguments, fieldDecl.sourceStart, fieldDecl.sourceEnd); } public void illegalModifierForInterface(SourceTypeBinding type) { String[] arguments = new String[] {new String(type.sourceName())}; this.handle( IProblem.IllegalModifierForInterface, arguments, arguments, type.sourceStart(), type.sourceEnd()); } public void illegalModifierForInterfaceField(FieldDeclaration fieldDecl) { String name = new String(fieldDecl.name); this.handle( IProblem.IllegalModifierForInterfaceField, new String[] { new String(fieldDecl.binding.declaringClass.readableName()), name, }, new String[] { new String(fieldDecl.binding.declaringClass.shortReadableName()), name, }, fieldDecl.sourceStart, fieldDecl.sourceEnd); } public void illegalModifierForInterfaceMethod(AbstractMethodDeclaration methodDecl) { this.handle( IProblem.IllegalModifierForInterfaceMethod, new String[] { new String(methodDecl.binding.declaringClass.readableName()), new String(methodDecl.selector), typesAsString(methodDecl.binding.isVarargs(), methodDecl.binding.parameters, false), }, new String[] { new String(methodDecl.binding.declaringClass.shortReadableName()), new String(methodDecl.selector), typesAsString(methodDecl.binding.isVarargs(), methodDecl.binding.parameters, true), }, methodDecl.sourceStart, methodDecl.sourceEnd); } public void illegalModifierForLocalClass(SourceTypeBinding type) { String[] arguments = new String[] {new String(type.sourceName())}; this.handle( IProblem.IllegalModifierForLocalClass, arguments, arguments, type.sourceStart(), type.sourceEnd()); } public void illegalModifierForMemberClass(SourceTypeBinding type) { String[] arguments = new String[] {new String(type.sourceName())}; this.handle( IProblem.IllegalModifierForMemberClass, arguments, arguments, type.sourceStart(), type.sourceEnd()); } public void illegalModifierForMemberInterface(SourceTypeBinding type) { String[] arguments = new String[] {new String(type.sourceName())}; this.handle( IProblem.IllegalModifierForMemberInterface, arguments, arguments, type.sourceStart(), type.sourceEnd()); } public void illegalModifierForAnnotationType(SourceTypeBinding type) { String[] arguments = new String[] {new String(type.sourceName())}; this.handle( IProblem.IllegalModifierForAnnotationType, arguments, arguments, type.sourceStart(), type.sourceEnd()); } public void illegalModifierForAnnotationMemberType(SourceTypeBinding type) { String[] arguments = new String[] {new String(type.sourceName())}; this.handle( IProblem.IllegalModifierForAnnotationMemberType, arguments, arguments, type.sourceStart(), type.sourceEnd()); } public void illegalModifierForAnnotationField(FieldDeclaration fieldDecl) { String name = new String(fieldDecl.name); this.handle( IProblem.IllegalModifierForAnnotationField, new String[] { new String(fieldDecl.binding.declaringClass.readableName()), name, }, new String[] { new String(fieldDecl.binding.declaringClass.shortReadableName()), name, }, fieldDecl.sourceStart, fieldDecl.sourceEnd); } public void illegalModifierForAnnotationMember(AbstractMethodDeclaration methodDecl) { this.handle( IProblem.IllegalModifierForAnnotationMethod, new String[] { new String(methodDecl.binding.declaringClass.readableName()), new String(methodDecl.selector), }, new String[] { new String(methodDecl.binding.declaringClass.shortReadableName()), new String(methodDecl.selector), }, methodDecl.sourceStart, methodDecl.sourceEnd); } public void illegalModifierForMethod(AbstractMethodDeclaration methodDecl) { this.handle( IProblem.IllegalModifierForMethod, new String[] { new String(methodDecl.selector), typesAsString(methodDecl.binding.isVarargs(), methodDecl.binding.parameters, false), new String(methodDecl.binding.declaringClass.readableName()), }, new String[] { new String(methodDecl.selector), typesAsString(methodDecl.binding.isVarargs(), methodDecl.binding.parameters, true), new String(methodDecl.binding.declaringClass.shortReadableName()), }, methodDecl.sourceStart, methodDecl.sourceEnd); } public void illegalModifierForVariable(LocalDeclaration localDecl, boolean complainAsArgument) { String[] arguments = new String[] {new String(localDecl.name)}; this.handle( complainAsArgument ? IProblem.IllegalModifierForArgument : IProblem.IllegalModifierForVariable, arguments, arguments, localDecl.sourceStart, localDecl.sourceEnd); } public void illegalPrimitiveOrArrayTypeForEnclosingInstance(TypeBinding enclosingType, ASTNode location) { this.handle( IProblem.IllegalPrimitiveOrArrayTypeForEnclosingInstance, new String[] {new String(enclosingType.readableName())}, new String[] {new String(enclosingType.shortReadableName())}, location.sourceStart, location.sourceEnd); } public void illegalStaticModifierForMemberType(SourceTypeBinding type) { String[] arguments = new String[] {new String(type.sourceName())}; this.handle( IProblem.IllegalStaticModifierForMemberType, arguments, arguments, type.sourceStart(), type.sourceEnd()); } public void illegalUsageOfQualifiedTypeReference(QualifiedTypeReference qualifiedTypeReference) { StringBuffer buffer = new StringBuffer(); char[][] tokens = qualifiedTypeReference.tokens; for (int i = 0; i < tokens.length; i++) { if (i > 0) buffer.append('.'); buffer.append(tokens[i]); } String[] arguments = new String[] { String.valueOf(buffer)}; this.handle( IProblem.IllegalUsageOfQualifiedTypeReference, arguments, arguments, qualifiedTypeReference.sourceStart, qualifiedTypeReference.sourceEnd); } public void illegalVararg(Argument argType, AbstractMethodDeclaration methodDecl) { String[] arguments = new String[] {CharOperation.toString(argType.type.getTypeName()), new String(methodDecl.selector)}; this.handle( IProblem.IllegalVararg, arguments, arguments, argType.sourceStart, argType.sourceEnd); } public void illegalVisibilityModifierCombinationForField(ReferenceBinding type, FieldDeclaration fieldDecl) { String[] arguments = new String[] {new String(fieldDecl.name)}; this.handle( IProblem.IllegalVisibilityModifierCombinationForField, arguments, arguments, fieldDecl.sourceStart, fieldDecl.sourceEnd); } public void illegalVisibilityModifierCombinationForMemberType(SourceTypeBinding type) { String[] arguments = new String[] {new String(type.sourceName())}; this.handle( IProblem.IllegalVisibilityModifierCombinationForMemberType, arguments, arguments, type.sourceStart(), type.sourceEnd()); } public void illegalVisibilityModifierCombinationForMethod(ReferenceBinding type, AbstractMethodDeclaration methodDecl) { String[] arguments = new String[] {new String(type.sourceName()), new String(methodDecl.selector)}; this.handle( IProblem.IllegalVisibilityModifierCombinationForMethod, arguments, arguments, methodDecl.sourceStart, methodDecl.sourceEnd); } public void illegalVisibilityModifierForInterfaceMemberType(SourceTypeBinding type) { String[] arguments = new String[] {new String(type.sourceName())}; this.handle( IProblem.IllegalVisibilityModifierForInterfaceMemberType, arguments, arguments, type.sourceStart(), type.sourceEnd()); } public void illegalVoidExpression(ASTNode location) { this.handle( IProblem.InvalidVoidExpression, NoArgument, NoArgument, location.sourceStart, location.sourceEnd); } public void importProblem(ImportReference importRef, Binding expectedImport) { if (expectedImport.problemId() == NotFound) { char[][] tokens = expectedImport instanceof ProblemReferenceBinding ? ((ProblemReferenceBinding) expectedImport).compoundName : importRef.tokens; String[] arguments = new String[]{CharOperation.toString(tokens)}; this.handle( IProblem.ImportNotFound, arguments, arguments, importRef.sourceStart, (int) importRef.sourcePositions[tokens.length - 1]); return; } if (expectedImport.problemId() == InvalidTypeForStaticImport) { char[][] tokens = importRef.tokens; String[] arguments = new String[]{CharOperation.toString(tokens)}; this.handle( IProblem.InvalidTypeForStaticImport, arguments, arguments, importRef.sourceStart, (int) importRef.sourcePositions[tokens.length - 1]); return; } invalidType(importRef, (TypeBinding)expectedImport); } public void incompatibleExceptionInThrowsClause(SourceTypeBinding type, MethodBinding currentMethod, MethodBinding inheritedMethod, ReferenceBinding exceptionType) { if (type == currentMethod.declaringClass) { int id; if (currentMethod.declaringClass.isInterface() && !inheritedMethod.isPublic()){ // interface inheriting Object protected method id = IProblem.IncompatibleExceptionInThrowsClauseForNonInheritedInterfaceMethod; } else { id = IProblem.IncompatibleExceptionInThrowsClause; } this.handle( // Exception %1 is not compatible with throws clause in %2 // 9.4.4 - The type of exception in the throws clause is incompatible. id, new String[] { new String(exceptionType.sourceName()), new String( CharOperation.concat( inheritedMethod.declaringClass.readableName(), inheritedMethod.readableName(), '.'))}, new String[] { new String(exceptionType.sourceName()), new String( CharOperation.concat( inheritedMethod.declaringClass.shortReadableName(), inheritedMethod.shortReadableName(), '.'))}, currentMethod.sourceStart(), currentMethod.sourceEnd()); } else this.handle( // Exception %1 in throws clause of %2 is not compatible with %3 // 9.4.4 - The type of exception in the throws clause is incompatible. IProblem.IncompatibleExceptionInInheritedMethodThrowsClause, new String[] { new String(exceptionType.sourceName()), new String( CharOperation.concat( currentMethod.declaringClass.sourceName(), currentMethod.readableName(), '.')), new String( CharOperation.concat( inheritedMethod.declaringClass.readableName(), inheritedMethod.readableName(), '.'))}, new String[] { new String(exceptionType.sourceName()), new String( CharOperation.concat( currentMethod.declaringClass.sourceName(), currentMethod.shortReadableName(), '.')), new String( CharOperation.concat( inheritedMethod.declaringClass.shortReadableName(), inheritedMethod.shortReadableName(), '.'))}, type.sourceStart(), type.sourceEnd()); } public void incompatibleReturnType(MethodBinding currentMethod, MethodBinding inheritedMethod) { StringBuffer methodSignature = new StringBuffer(); methodSignature .append(inheritedMethod.declaringClass.readableName()) .append('.') .append(inheritedMethod.readableName()); StringBuffer shortSignature = new StringBuffer(); shortSignature .append(inheritedMethod.declaringClass.shortReadableName()) .append('.') .append(inheritedMethod.shortReadableName()); int id; if (currentMethod.declaringClass.isInterface() && !inheritedMethod.isPublic()){ // interface inheriting Object protected method id = IProblem.IncompatibleReturnTypeForNonInheritedInterfaceMethod; } else { id = IProblem.IncompatibleReturnType; } this.handle( id, new String[] {methodSignature.toString()}, new String[] {shortSignature.toString()}, currentMethod.sourceStart(), currentMethod.sourceEnd()); } public void disallowedTargetForAnnotation(Annotation annotation) { this.handle( IProblem.DisallowedTargetForAnnotation, new String[] {new String(annotation.resolvedType.readableName())}, new String[] {new String(annotation.resolvedType.shortReadableName())}, annotation.sourceStart, annotation.sourceEnd); } public void incorrectArityForParameterizedType(ASTNode location, TypeBinding type, TypeBinding[] argumentTypes) { if (location == null) { this.handle( IProblem.IncorrectArityForParameterizedType, new String[] {new String(type.readableName()), typesAsString(false, argumentTypes, false)}, new String[] {new String(type.shortReadableName()), typesAsString(false, argumentTypes, true)}, AbortCompilation | Error, 0, 1); } this.handle( IProblem.IncorrectArityForParameterizedType, new String[] {new String(type.readableName()), typesAsString(false, argumentTypes, false)}, new String[] {new String(type.shortReadableName()), typesAsString(false, argumentTypes, true)}, location.sourceStart, location.sourceEnd); } public void incorrectLocationForNonEmptyDimension(ArrayAllocationExpression expression, int index) { this.handle( IProblem.IllegalDimension, NoArgument, NoArgument, expression.dimensions[index].sourceStart, expression.dimensions[index].sourceEnd); } public void incorrectSwitchType(Expression expression, TypeBinding testType) { this.handle( IProblem.IncorrectSwitchType, new String[] {new String(testType.readableName())}, new String[] {new String(testType.shortReadableName())}, expression.sourceStart, expression.sourceEnd); } public void indirectAccessToStaticField(ASTNode location, FieldBinding field){ this.handle( IProblem.IndirectAccessToStaticField, new String[] {new String(field.declaringClass.readableName()), new String(field.name)}, new String[] {new String(field.declaringClass.shortReadableName()), new String(field.name)}, location.sourceStart, fieldLocation(field, location)); } public void indirectAccessToStaticMethod(ASTNode location, MethodBinding method) { this.handle( IProblem.IndirectAccessToStaticMethod, new String[] {new String(method.declaringClass.readableName()), new String(method.selector), typesAsString(method.isVarargs(), method.parameters, false)}, new String[] {new String(method.declaringClass.shortReadableName()), new String(method.selector), typesAsString(method.isVarargs(), method.parameters, true)}, location.sourceStart, location.sourceEnd); } public void indirectAccessToStaticType(ASTNode location, ReferenceBinding type) { this.handle( IProblem.IndirectAccessToStaticMethod, new String[] {new String(type.enclosingType().readableName()), new String(type.sourceName) }, new String[] {new String(type.enclosingType().shortReadableName()), new String(type.sourceName) }, location.sourceStart, location.sourceEnd); } public void inheritedMethodsHaveNameClash(SourceTypeBinding type, MethodBinding oneMethod, MethodBinding twoMethod) { this.handle( IProblem.MethodNameClash, new String[] { new String(oneMethod.selector), typesAsString(oneMethod.original().isVarargs(), oneMethod.original().parameters, false), new String(oneMethod.declaringClass.readableName()), typesAsString(twoMethod.original().isVarargs(), twoMethod.original().parameters, false), new String(twoMethod.declaringClass.readableName()), }, new String[] { new String(oneMethod.selector), typesAsString(oneMethod.original().isVarargs(), oneMethod.original().parameters, true), new String(oneMethod.declaringClass.shortReadableName()), typesAsString(twoMethod.original().isVarargs(), twoMethod.original().parameters, true), new String(twoMethod.declaringClass.shortReadableName()), }, type.sourceStart(), type.sourceEnd()); } public void inheritedMethodReducesVisibility(SourceTypeBinding type, MethodBinding concreteMethod, MethodBinding[] abstractMethods) { StringBuffer concreteSignature = new StringBuffer(); concreteSignature .append(concreteMethod.declaringClass.readableName()) .append('.') .append(concreteMethod.readableName()); StringBuffer shortSignature = new StringBuffer(); shortSignature .append(concreteMethod.declaringClass.shortReadableName()) .append('.') .append(concreteMethod.shortReadableName()); this.handle( // The inherited method %1 cannot hide the public abstract method in %2 IProblem.InheritedMethodReducesVisibility, new String[] { concreteSignature.toString(), new String(abstractMethods[0].declaringClass.readableName())}, new String[] { new String(shortSignature.toString()), new String(abstractMethods[0].declaringClass.shortReadableName())}, type.sourceStart(), type.sourceEnd()); } public void inheritedMethodsHaveIncompatibleReturnTypes(SourceTypeBinding type, MethodBinding[] inheritedMethods, int length) { StringBuffer methodSignatures = new StringBuffer(); StringBuffer shortSignatures = new StringBuffer(); for (int i = length; --i >= 0;) { methodSignatures .append(inheritedMethods[i].declaringClass.readableName()) .append('.') .append(inheritedMethods[i].readableName()); shortSignatures .append(inheritedMethods[i].declaringClass.shortReadableName()) .append('.') .append(inheritedMethods[i].shortReadableName()); if (i != 0){ methodSignatures.append(", "); //$NON-NLS-1$ shortSignatures.append(", "); //$NON-NLS-1$ } } this.handle( // Return type is incompatible with %1 // 9.4.2 - The return type from the method is incompatible with the declaration. IProblem.IncompatibleReturnType, new String[] {methodSignatures.toString()}, new String[] {shortSignatures.toString()}, type.sourceStart(), type.sourceEnd()); } public void initializerMustCompleteNormally(FieldDeclaration fieldDecl) { this.handle( IProblem.InitializerMustCompleteNormally, NoArgument, NoArgument, fieldDecl.sourceStart, fieldDecl.sourceEnd); } public void innerTypesCannotDeclareStaticInitializers(ReferenceBinding innerType, ASTNode location) { this.handle( IProblem.CannotDefineStaticInitializerInLocalType, new String[] {new String(innerType.readableName())}, new String[] {new String(innerType.shortReadableName())}, location.sourceStart, location.sourceEnd); } public void interfaceCannotHaveConstructors(ConstructorDeclaration constructor) { this.handle( IProblem.InterfaceCannotHaveConstructors, NoArgument, NoArgument, constructor.sourceStart, constructor.sourceEnd, constructor, constructor.compilationResult()); } public void interfaceCannotHaveInitializers(SourceTypeBinding type, FieldDeclaration fieldDecl) { String[] arguments = new String[] {new String(type.sourceName())}; this.handle( IProblem.InterfaceCannotHaveInitializers, arguments, arguments, fieldDecl.sourceStart, fieldDecl.sourceEnd); } public void invalidAnnotationMemberType(MethodDeclaration methodDecl) { this.handle( IProblem.InvalidAnnotationMemberType, new String[] { new String(methodDecl.binding.returnType.readableName()), new String(methodDecl.selector), new String(methodDecl.binding.declaringClass.readableName()), }, new String[] { new String(methodDecl.binding.returnType.shortReadableName()), new String(methodDecl.selector), new String(methodDecl.binding.declaringClass.shortReadableName()), }, methodDecl.returnType.sourceStart, methodDecl.returnType.sourceEnd); } public void invalidBreak(ASTNode location) { this.handle( IProblem.InvalidBreak, NoArgument, NoArgument, location.sourceStart, location.sourceEnd); } public void invalidConstructor(Statement statement, MethodBinding targetConstructor) { boolean insideDefaultConstructor = (this.referenceContext instanceof ConstructorDeclaration) && ((ConstructorDeclaration)this.referenceContext).isDefaultConstructor(); boolean insideImplicitConstructorCall = (statement instanceof ExplicitConstructorCall) && (((ExplicitConstructorCall) statement).accessMode == ExplicitConstructorCall.ImplicitSuper); int sourceStart = statement.sourceStart; int sourceEnd = statement.sourceEnd; if (statement instanceof AllocationExpression) { AllocationExpression allocation = (AllocationExpression)statement; if (allocation.enumConstant != null) { sourceStart = allocation.enumConstant.sourceStart; sourceEnd = allocation.enumConstant.sourceEnd; } } int id = IProblem.UndefinedConstructor; //default... MethodBinding shownConstructor = targetConstructor; switch (targetConstructor.problemId()) { case NotFound : if (insideDefaultConstructor){ id = IProblem.UndefinedConstructorInDefaultConstructor; } else if (insideImplicitConstructorCall){ id = IProblem.UndefinedConstructorInImplicitConstructorCall; } else { id = IProblem.UndefinedConstructor; } break; case NotVisible : if (insideDefaultConstructor){ id = IProblem.NotVisibleConstructorInDefaultConstructor; } else if (insideImplicitConstructorCall){ id = IProblem.NotVisibleConstructorInImplicitConstructorCall; } else { id = IProblem.NotVisibleConstructor; } ProblemMethodBinding problemConstructor = (ProblemMethodBinding) targetConstructor; if (problemConstructor.closestMatch != null) { shownConstructor = problemConstructor.closestMatch.original(); } break; case Ambiguous : if (insideDefaultConstructor){ id = IProblem.AmbiguousConstructorInDefaultConstructor; } else if (insideImplicitConstructorCall){ id = IProblem.AmbiguousConstructorInImplicitConstructorCall; } else { id = IProblem.AmbiguousConstructor; } break; case ParameterBoundMismatch : problemConstructor = (ProblemMethodBinding) targetConstructor; ParameterizedGenericMethodBinding substitutedConstructor = (ParameterizedGenericMethodBinding) problemConstructor.closestMatch; shownConstructor = substitutedConstructor.original(); TypeBinding typeArgument = targetConstructor.parameters[0]; TypeVariableBinding typeParameter = (TypeVariableBinding) targetConstructor.parameters[1]; this.handle( IProblem.GenericConstructorTypeArgumentMismatch, new String[] { new String(shownConstructor.declaringClass.sourceName()), typesAsString(shownConstructor.isVarargs(), shownConstructor.parameters, false), new String(shownConstructor.declaringClass.readableName()), typesAsString(substitutedConstructor.isVarargs(), substitutedConstructor.parameters, false), new String(typeArgument.readableName()), new String(typeParameter.sourceName), parameterBoundAsString(typeParameter, false) }, new String[] { new String(shownConstructor.declaringClass.sourceName()), typesAsString(shownConstructor.isVarargs(), shownConstructor.parameters, true), new String(shownConstructor.declaringClass.shortReadableName()), typesAsString(substitutedConstructor.isVarargs(), substitutedConstructor.parameters, true), new String(typeArgument.shortReadableName()), new String(typeParameter.sourceName), parameterBoundAsString(typeParameter, true) }, sourceStart, sourceEnd); return; case TypeParameterArityMismatch : problemConstructor = (ProblemMethodBinding) targetConstructor; shownConstructor = problemConstructor.closestMatch; if (shownConstructor.typeVariables == TypeConstants.NoTypeVariables) { this.handle( IProblem.NonGenericConstructor, new String[] { new String(shownConstructor.declaringClass.sourceName()), typesAsString(shownConstructor.isVarargs(), shownConstructor.parameters, false), new String(shownConstructor.declaringClass.readableName()), typesAsString(targetConstructor.isVarargs(), targetConstructor.parameters, false) }, new String[] { new String(shownConstructor.declaringClass.sourceName()), typesAsString(shownConstructor.isVarargs(), shownConstructor.parameters, true), new String(shownConstructor.declaringClass.shortReadableName()), typesAsString(targetConstructor.isVarargs(), targetConstructor.parameters, true) }, sourceStart, sourceEnd); } else { this.handle( IProblem.IncorrectArityForParameterizedConstructor , new String[] { new String(shownConstructor.declaringClass.sourceName()), typesAsString(shownConstructor.isVarargs(), shownConstructor.parameters, false), new String(shownConstructor.declaringClass.readableName()), typesAsString(false, shownConstructor.typeVariables, false), typesAsString(targetConstructor.isVarargs(), targetConstructor.parameters, false) }, new String[] { new String(shownConstructor.declaringClass.sourceName()), typesAsString(shownConstructor.isVarargs(), shownConstructor.parameters, true), new String(shownConstructor.declaringClass.shortReadableName()), typesAsString(false, shownConstructor.typeVariables, true), typesAsString(targetConstructor.isVarargs(), targetConstructor.parameters, true) }, sourceStart, sourceEnd); } return; case ParameterizedMethodTypeMismatch : problemConstructor = (ProblemMethodBinding) targetConstructor; shownConstructor = problemConstructor.closestMatch; this.handle( IProblem.ParameterizedConstructorArgumentTypeMismatch, new String[] { new String(shownConstructor.declaringClass.sourceName()), typesAsString(shownConstructor.isVarargs(), shownConstructor.parameters, false), new String(shownConstructor.declaringClass.readableName()), typesAsString(false, ((ParameterizedGenericMethodBinding)shownConstructor).typeArguments, false), typesAsString(targetConstructor.isVarargs(), targetConstructor.parameters, false) }, new String[] { new String(shownConstructor.declaringClass.sourceName()), typesAsString(shownConstructor.isVarargs(), shownConstructor.parameters, true), new String(shownConstructor.declaringClass.shortReadableName()), typesAsString(false, ((ParameterizedGenericMethodBinding)shownConstructor).typeArguments, true), typesAsString(targetConstructor.isVarargs(), targetConstructor.parameters, true) }, sourceStart, sourceEnd); return; case TypeArgumentsForRawGenericMethod : problemConstructor = (ProblemMethodBinding) targetConstructor; shownConstructor = problemConstructor.closestMatch; this.handle( IProblem.TypeArgumentsForRawGenericConstructor, new String[] { new String(shownConstructor.declaringClass.sourceName()), typesAsString(shownConstructor.isVarargs(), shownConstructor.parameters, false), new String(shownConstructor.declaringClass.readableName()), typesAsString(targetConstructor.isVarargs(), targetConstructor.parameters, false) }, new String[] { new String(shownConstructor.declaringClass.sourceName()), typesAsString(shownConstructor.isVarargs(), shownConstructor.parameters, true), new String(shownConstructor.declaringClass.shortReadableName()), typesAsString(targetConstructor.isVarargs(), targetConstructor.parameters, true) }, sourceStart, sourceEnd); return; case NoError : // 0 default : needImplementation(); // want to fail to see why we were here... break; } this.handle( id, new String[] {new String(targetConstructor.declaringClass.readableName()), typesAsString(shownConstructor.isVarargs(), shownConstructor.parameters, false)}, new String[] {new String(targetConstructor.declaringClass.shortReadableName()), typesAsString(shownConstructor.isVarargs(), shownConstructor.parameters, true)}, sourceStart, sourceEnd); } public void invalidContinue(ASTNode location) { this.handle( IProblem.InvalidContinue, NoArgument, NoArgument, location.sourceStart, location.sourceEnd); } public void invalidEnclosingType(Expression expression, TypeBinding type, ReferenceBinding enclosingType) { if (enclosingType.isAnonymousType()) enclosingType = enclosingType.superclass(); int flag = IProblem.UndefinedType; // default switch (type.problemId()) { case NotFound : // 1 flag = IProblem.UndefinedType; break; case NotVisible : // 2 flag = IProblem.NotVisibleType; break; case Ambiguous : // 3 flag = IProblem.AmbiguousType; break; case InternalNameProvided : flag = IProblem.InternalTypeNameProvided; break; case NoError : // 0 default : needImplementation(); // want to fail to see why we were here... break; } this.handle( flag, new String[] {new String(enclosingType.readableName()) + "." + new String(type.readableName())}, //$NON-NLS-1$ new String[] {new String(enclosingType.shortReadableName()) + "." + new String(type.shortReadableName())}, //$NON-NLS-1$ expression.sourceStart, expression.sourceEnd); } public void invalidExplicitConstructorCall(ASTNode location) { this.handle( IProblem.InvalidExplicitConstructorCall, NoArgument, NoArgument, location.sourceStart, location.sourceEnd); } public void invalidExpressionAsStatement(Expression expression){ this.handle( IProblem.InvalidExpressionAsStatement, NoArgument, NoArgument, expression.sourceStart, expression.sourceEnd); } public void invalidField(FieldReference fieldRef, TypeBinding searchedType) { int id = IProblem.UndefinedField; FieldBinding field = fieldRef.binding; switch (field.problemId()) { case NotFound : id = IProblem.UndefinedField; /* also need to check that the searchedType is the receiver type if (searchedType.isHierarchyInconsistent()) severity = SecondaryError; */ break; case NotVisible : id = IProblem.NotVisibleField; break; case Ambiguous : id = IProblem.AmbiguousField; break; case NonStaticReferenceInStaticContext : id = IProblem.NonStaticFieldFromStaticInvocation; break; case NonStaticReferenceInConstructorInvocation : id = IProblem.InstanceFieldDuringConstructorInvocation; break; case InheritedNameHidesEnclosingName : id = IProblem.InheritedFieldHidesEnclosingName; break; case ReceiverTypeNotVisible : this.handle( IProblem.NotVisibleType, // cannot occur in javadoc comments new String[] {new String(searchedType.leafComponentType().readableName())}, new String[] {new String(searchedType.leafComponentType().shortReadableName())}, fieldRef.receiver.sourceStart, fieldRef.receiver.sourceEnd); return; case NoError : // 0 default : needImplementation(); // want to fail to see why we were here... break; } String[] arguments = new String[] {new String(field.readableName())}; this.handle( id, arguments, arguments, fieldRef.sourceStart, fieldRef.sourceEnd); } public void invalidField(NameReference nameRef, FieldBinding field) { int id = IProblem.UndefinedField; switch (field.problemId()) { case NotFound : id = IProblem.UndefinedField; break; case NotVisible : id = IProblem.NotVisibleField; break; case Ambiguous : id = IProblem.AmbiguousField; break; case NonStaticReferenceInStaticContext : id = IProblem.NonStaticFieldFromStaticInvocation; break; case NonStaticReferenceInConstructorInvocation : id = IProblem.InstanceFieldDuringConstructorInvocation; break; case InheritedNameHidesEnclosingName : id = IProblem.InheritedFieldHidesEnclosingName; break; case ReceiverTypeNotVisible : this.handle( IProblem.NotVisibleType, new String[] {new String(field.declaringClass.leafComponentType().readableName())}, new String[] {new String(field.declaringClass.leafComponentType().shortReadableName())}, nameRef.sourceStart, nameRef.sourceEnd); return; case NoError : // 0 default : needImplementation(); // want to fail to see why we were here... break; } String[] arguments = new String[] {new String(field.readableName())}; this.handle( id, arguments, arguments, nameRef.sourceStart, nameRef.sourceEnd); } public void invalidField(QualifiedNameReference nameRef, FieldBinding field, int index, TypeBinding searchedType) { //the resolution of the index-th field of qname failed //qname.otherBindings[index] is the binding that has produced the error //The different targetted errors should be : //UndefinedField //NotVisibleField //AmbiguousField if (searchedType.isBaseType()) { this.handle( IProblem.NoFieldOnBaseType, new String[] { new String(searchedType.readableName()), CharOperation.toString(CharOperation.subarray(nameRef.tokens, 0, index)), new String(nameRef.tokens[index])}, new String[] { new String(searchedType.sourceName()), CharOperation.toString(CharOperation.subarray(nameRef.tokens, 0, index)), new String(nameRef.tokens[index])}, nameRef.sourceStart, (int) nameRef.sourcePositions[index]); return; } int id = IProblem.UndefinedField; switch (field.problemId()) { case NotFound : id = IProblem.UndefinedField; /* also need to check that the searchedType is the receiver type if (searchedType.isHierarchyInconsistent()) severity = SecondaryError; */ break; case NotVisible : id = IProblem.NotVisibleField; break; case Ambiguous : id = IProblem.AmbiguousField; break; case NonStaticReferenceInStaticContext : id = IProblem.NonStaticFieldFromStaticInvocation; break; case NonStaticReferenceInConstructorInvocation : id = IProblem.InstanceFieldDuringConstructorInvocation; break; case InheritedNameHidesEnclosingName : id = IProblem.InheritedFieldHidesEnclosingName; break; case ReceiverTypeNotVisible : this.handle( IProblem.NotVisibleType, new String[] {new String(searchedType.leafComponentType().readableName())}, new String[] {new String(searchedType.leafComponentType().shortReadableName())}, nameRef.sourceStart, nameRef.sourceEnd); return; case NoError : // 0 default : needImplementation(); // want to fail to see why we were here... break; } String[] arguments = new String[] {CharOperation.toString(CharOperation.subarray(nameRef.tokens, 0, index + 1))}; this.handle( id, arguments, arguments, nameRef.sourceStart, (int) nameRef.sourcePositions[index]); } public void invalidFileNameForPackageAnnotations(Annotation annotation) { this.handle( IProblem.InvalidFileNameForPackageAnnotations, NoArgument, NoArgument, annotation.sourceStart, annotation.sourceEnd); } public void invalidMethod(MessageSend messageSend, MethodBinding method) { int id = IProblem.UndefinedMethod; //default... MethodBinding shownMethod = method; switch (method.problemId()) { case NotFound : id = IProblem.UndefinedMethod; ProblemMethodBinding problemMethod = (ProblemMethodBinding) method; if (problemMethod.closestMatch != null) { shownMethod = problemMethod.closestMatch; String closestParameterTypeNames = typesAsString(shownMethod.isVarargs(), shownMethod.parameters, false); String parameterTypeNames = typesAsString(method.isVarargs(), method.parameters, false); String closestParameterTypeShortNames = typesAsString(shownMethod.isVarargs(), shownMethod.parameters, true); String parameterTypeShortNames = typesAsString(method.isVarargs(), method.parameters, true); if (closestParameterTypeShortNames.equals(parameterTypeShortNames)){ closestParameterTypeShortNames = closestParameterTypeNames; parameterTypeShortNames = parameterTypeNames; } this.handle( IProblem.ParameterMismatch, new String[] { new String(shownMethod.declaringClass.readableName()), new String(shownMethod.selector), closestParameterTypeNames, parameterTypeNames }, new String[] { new String(shownMethod.declaringClass.shortReadableName()), new String(shownMethod.selector), closestParameterTypeShortNames, parameterTypeShortNames }, (int) (messageSend.nameSourcePosition >>> 32), (int) messageSend.nameSourcePosition); return; } break; case NotVisible : id = IProblem.NotVisibleMethod; problemMethod = (ProblemMethodBinding) method; if (problemMethod.closestMatch != null) { shownMethod = problemMethod.closestMatch.original(); } break; case Ambiguous : id = IProblem.AmbiguousMethod; break; case InheritedNameHidesEnclosingName : id = IProblem.InheritedMethodHidesEnclosingName; break; case NonStaticReferenceInConstructorInvocation : id = IProblem.InstanceMethodDuringConstructorInvocation; break; case NonStaticReferenceInStaticContext : id = IProblem.StaticMethodRequested; break; case ReceiverTypeNotVisible : this.handle( IProblem.NotVisibleType, // cannot occur in javadoc comments new String[] {new String(method.declaringClass.leafComponentType().readableName())}, new String[] {new String(method.declaringClass.leafComponentType().shortReadableName())}, messageSend.receiver.sourceStart, messageSend.receiver.sourceEnd); return; case ParameterBoundMismatch : problemMethod = (ProblemMethodBinding) method; ParameterizedGenericMethodBinding substitutedMethod = (ParameterizedGenericMethodBinding) problemMethod.closestMatch; shownMethod = substitutedMethod.original(); TypeBinding typeArgument = method.parameters[0]; TypeVariableBinding typeParameter = (TypeVariableBinding) method.parameters[1]; this.handle( IProblem.GenericMethodTypeArgumentMismatch, new String[] { new String(shownMethod.selector), typesAsString(shownMethod.isVarargs(), shownMethod.parameters, false), new String(shownMethod.declaringClass.readableName()), typesAsString(substitutedMethod.isVarargs(), substitutedMethod.parameters, false), new String(typeArgument.readableName()), new String(typeParameter.sourceName), parameterBoundAsString(typeParameter, false) }, new String[] { new String(shownMethod.selector), typesAsString(shownMethod.isVarargs(), shownMethod.parameters, true), new String(shownMethod.declaringClass.shortReadableName()), typesAsString(substitutedMethod.isVarargs(), substitutedMethod.parameters, true), new String(typeArgument.shortReadableName()), new String(typeParameter.sourceName), parameterBoundAsString(typeParameter, true) }, (int) (messageSend.nameSourcePosition >>> 32), (int) messageSend.nameSourcePosition); return; case TypeParameterArityMismatch : problemMethod = (ProblemMethodBinding) method; shownMethod = problemMethod.closestMatch; if (shownMethod.typeVariables == TypeConstants.NoTypeVariables) { this.handle( IProblem.NonGenericMethod , new String[] { new String(shownMethod.selector), typesAsString(shownMethod.isVarargs(), shownMethod.parameters, false), new String(shownMethod.declaringClass.readableName()), typesAsString(method.isVarargs(), method.parameters, false) }, new String[] { new String(shownMethod.selector), typesAsString(shownMethod.isVarargs(), shownMethod.parameters, true), new String(shownMethod.declaringClass.shortReadableName()), typesAsString(method.isVarargs(), method.parameters, true) }, (int) (messageSend.nameSourcePosition >>> 32), (int) messageSend.nameSourcePosition); } else { this.handle( IProblem.IncorrectArityForParameterizedMethod , new String[] { new String(shownMethod.selector), typesAsString(shownMethod.isVarargs(), shownMethod.parameters, false), new String(shownMethod.declaringClass.readableName()), typesAsString(false, shownMethod.typeVariables, false), typesAsString(method.isVarargs(), method.parameters, false) }, new String[] { new String(shownMethod.selector), typesAsString(shownMethod.isVarargs(), shownMethod.parameters, true), new String(shownMethod.declaringClass.shortReadableName()), typesAsString(false, shownMethod.typeVariables, true), typesAsString(method.isVarargs(), method.parameters, true) }, (int) (messageSend.nameSourcePosition >>> 32), (int) messageSend.nameSourcePosition); } return; case ParameterizedMethodTypeMismatch : problemMethod = (ProblemMethodBinding) method; shownMethod = problemMethod.closestMatch; this.handle( IProblem.ParameterizedMethodArgumentTypeMismatch, new String[] { new String(shownMethod.selector), typesAsString(shownMethod.isVarargs(), shownMethod.parameters, false), new String(shownMethod.declaringClass.readableName()), typesAsString(false, ((ParameterizedGenericMethodBinding)shownMethod).typeArguments, false), typesAsString(method.isVarargs(), method.parameters, false) }, new String[] { new String(shownMethod.selector), typesAsString(shownMethod.isVarargs(), shownMethod.parameters, true), new String(shownMethod.declaringClass.shortReadableName()), typesAsString(false, ((ParameterizedGenericMethodBinding)shownMethod).typeArguments, true), typesAsString(method.isVarargs(), method.parameters, true) }, (int) (messageSend.nameSourcePosition >>> 32), (int) messageSend.nameSourcePosition); return; case TypeArgumentsForRawGenericMethod : problemMethod = (ProblemMethodBinding) method; shownMethod = problemMethod.closestMatch; this.handle( IProblem.TypeArgumentsForRawGenericMethod , new String[] { new String(shownMethod.selector), typesAsString(shownMethod.isVarargs(), shownMethod.parameters, false), new String(shownMethod.declaringClass.readableName()), typesAsString(method.isVarargs(), method.parameters, false) }, new String[] { new String(shownMethod.selector), typesAsString(shownMethod.isVarargs(), shownMethod.parameters, true), new String(shownMethod.declaringClass.shortReadableName()), typesAsString(method.isVarargs(), method.parameters, true) }, (int) (messageSend.nameSourcePosition >>> 32), (int) messageSend.nameSourcePosition); return; case NoError : // 0 default : needImplementation(); // want to fail to see why we were here... break; } this.handle( id, new String[] { new String(method.declaringClass.readableName()), new String(shownMethod.selector), typesAsString(shownMethod.isVarargs(), shownMethod.parameters, false)}, new String[] { new String(method.declaringClass.shortReadableName()), new String(shownMethod.selector), typesAsString(shownMethod.isVarargs(), shownMethod.parameters, true)}, (int) (messageSend.nameSourcePosition >>> 32), (int) messageSend.nameSourcePosition); } public void invalidNullToSynchronize(Expression expression) { this.handle( IProblem.InvalidNullToSynchronized, NoArgument, NoArgument, expression.sourceStart, expression.sourceEnd); } public void invalidOperator(BinaryExpression expression, TypeBinding leftType, TypeBinding rightType) { String leftName = new String(leftType.readableName()); String rightName = new String(rightType.readableName()); String leftShortName = new String(leftType.shortReadableName()); String rightShortName = new String(rightType.shortReadableName()); if (leftShortName.equals(rightShortName)){ leftShortName = leftName; rightShortName = rightName; } this.handle( IProblem.InvalidOperator, new String[] { expression.operatorToString(), leftName + ", " + rightName}, //$NON-NLS-1$ new String[] { expression.operatorToString(), leftShortName + ", " + rightShortName}, //$NON-NLS-1$ expression.sourceStart, expression.sourceEnd); } public void invalidOperator(CompoundAssignment assign, TypeBinding leftType, TypeBinding rightType) { String leftName = new String(leftType.readableName()); String rightName = new String(rightType.readableName()); String leftShortName = new String(leftType.shortReadableName()); String rightShortName = new String(rightType.shortReadableName()); if (leftShortName.equals(rightShortName)){ leftShortName = leftName; rightShortName = rightName; } this.handle( IProblem.InvalidOperator, new String[] { assign.operatorToString(), leftName + ", " + rightName}, //$NON-NLS-1$ new String[] { assign.operatorToString(), leftShortName + ", " + rightShortName}, //$NON-NLS-1$ assign.sourceStart, assign.sourceEnd); } public void invalidOperator(UnaryExpression expression, TypeBinding type) { this.handle( IProblem.InvalidOperator, new String[] {expression.operatorToString(), new String(type.readableName())}, new String[] {expression.operatorToString(), new String(type.shortReadableName())}, expression.sourceStart, expression.sourceEnd); } public void invalidParameterizedExceptionType(TypeBinding exceptionType, ASTNode location) { this.handle( IProblem.InvalidParameterizedExceptionType, new String[] {new String(exceptionType.readableName())}, new String[] {new String(exceptionType.shortReadableName())}, location.sourceStart, location.sourceEnd); } public void invalidParenthesizedExpression(ASTNode reference) { this.handle( IProblem.InvalidParenthesizedExpression, NoArgument, NoArgument, reference.sourceStart, reference.sourceEnd); } public void invalidType(ASTNode location, TypeBinding type) { int id = IProblem.UndefinedType; // default switch (type.problemId()) { case NotFound : id = IProblem.UndefinedType; break; case NotVisible : id = IProblem.NotVisibleType; break; case Ambiguous : id = IProblem.AmbiguousType; break; case InternalNameProvided : id = IProblem.InternalTypeNameProvided; break; case InheritedNameHidesEnclosingName : id = IProblem.InheritedTypeHidesEnclosingName; break; case NonStaticReferenceInStaticContext : id = IProblem.TypeVariableReferenceFromStaticContext; break; case IllegalSuperTypeVariable : id = IProblem.IllegalTypeVariableSuperReference; break; case NoError : // 0 default : needImplementation(); // want to fail to see why we were here... break; } int end = location.sourceEnd; if (location instanceof QualifiedNameReference) { QualifiedNameReference ref = (QualifiedNameReference) location; if (ref.indexOfFirstFieldBinding >= 1) end = (int) ref.sourcePositions[ref.indexOfFirstFieldBinding - 1]; } else if (location instanceof ArrayQualifiedTypeReference) { if (!(location instanceof ParameterizedQualifiedTypeReference)) { ArrayQualifiedTypeReference arrayQualifiedTypeReference = (ArrayQualifiedTypeReference) location; long[] positions = arrayQualifiedTypeReference.sourcePositions; end = (int) positions[positions.length - 1]; } } else if (location instanceof QualifiedTypeReference) { QualifiedTypeReference ref = (QualifiedTypeReference) location; if (type instanceof ReferenceBinding) { char[][] name = ((ReferenceBinding) type).compoundName; end = (int) ref.sourcePositions[name.length - 1]; } } else if (location instanceof ImportReference) { ImportReference ref = (ImportReference) location; if (type instanceof ReferenceBinding) { char[][] name = ((ReferenceBinding) type).compoundName; end = (int) ref.sourcePositions[name.length - 1]; } } else if (location instanceof ArrayTypeReference) { if (!(location instanceof ParameterizedSingleTypeReference)) { ArrayTypeReference arrayTypeReference = (ArrayTypeReference) location; end = arrayTypeReference.originalSourceEnd; } } this.handle( id, new String[] {new String(type.leafComponentType().readableName()) }, new String[] {new String(type.leafComponentType().shortReadableName())}, location.sourceStart, end); } public void invalidTypeForCollection(Expression expression) { this.handle( IProblem.InvalidTypeForCollection, NoArgument, NoArgument, expression.sourceStart, expression.sourceEnd); } public void invalidTypeReference(Expression expression) { this.handle( IProblem.InvalidTypeExpression, NoArgument, NoArgument, expression.sourceStart, expression.sourceEnd); } public void invalidTypeToSynchronize(Expression expression, TypeBinding type) { this.handle( IProblem.InvalidTypeToSynchronized, new String[] {new String(type.readableName())}, new String[] {new String(type.shortReadableName())}, expression.sourceStart, expression.sourceEnd); } public void invalidTypeVariableAsException(TypeBinding exceptionType, ASTNode location) { this.handle( IProblem.InvalidTypeVariableExceptionType, new String[] {new String(exceptionType.readableName())}, new String[] {new String(exceptionType.shortReadableName())}, location.sourceStart, location.sourceEnd); } public void invalidUnaryExpression(Expression expression) { this.handle( IProblem.InvalidUnaryExpression, NoArgument, NoArgument, expression.sourceStart, expression.sourceEnd); } public void invalidUsageOfAnnotation(Annotation annotation) { this.handle( IProblem.InvalidUsageOfAnnotations, NoArgument, NoArgument, annotation.sourceStart, annotation.sourceEnd); } public void invalidUsageOfAnnotationDeclarations(TypeDeclaration annotationTypeDeclaration) { this.handle( IProblem.InvalidUsageOfAnnotationDeclarations, NoArgument, NoArgument, annotationTypeDeclaration.sourceStart, annotationTypeDeclaration.sourceEnd); } public void invalidUsageOfEnumDeclarations(TypeDeclaration enumDeclaration) { this.handle( IProblem.InvalidUsageOfEnumDeclarations, NoArgument, NoArgument, enumDeclaration.sourceStart, enumDeclaration.sourceEnd); } public void invalidUsageOfForeachStatements(LocalDeclaration elementVariable, Expression collection) { this.handle( IProblem.InvalidUsageOfForeachStatements, NoArgument, NoArgument, elementVariable.declarationSourceStart, collection.sourceEnd); } public void invalidUsageOfStaticImports(ImportReference staticImport) { this.handle( IProblem.InvalidUsageOfStaticImports, NoArgument, NoArgument, staticImport.declarationSourceStart, staticImport.declarationSourceEnd); } public void invalidUsageOfTypeArguments(TypeReference firstTypeReference, TypeReference lastTypeReference) { this.handle( IProblem.InvalidUsageOfTypeArguments, NoArgument, NoArgument, firstTypeReference.sourceStart, lastTypeReference.sourceEnd); } public void invalidUsageOfTypeParameters(TypeParameter firstTypeParameter, TypeParameter lastTypeParameter) { this.handle( IProblem.InvalidUsageOfTypeParameters, NoArgument, NoArgument, firstTypeParameter.declarationSourceStart, lastTypeParameter.declarationSourceEnd); } public void invalidUsageOfVarargs(Argument argument) { this.handle( IProblem.InvalidUsageOfVarargs, NoArgument, NoArgument, argument.type.sourceStart, argument.sourceEnd); } public void isClassPathCorrect(char[][] wellKnownTypeName, CompilationUnitDeclaration compUnitDecl) { this.referenceContext = compUnitDecl; String[] arguments = new String[] {CharOperation.toString(wellKnownTypeName)}; this.handle( IProblem.IsClassPathCorrect, arguments, arguments, AbortCompilation | Error, 0, 0); } private boolean isIdentifier(int token) { return token == TerminalTokens.TokenNameIdentifier; } private boolean isKeyword(int token) { switch(token) { case TerminalTokens.TokenNameabstract: case TerminalTokens.TokenNameassert: case TerminalTokens.TokenNamebyte: case TerminalTokens.TokenNamebreak: case TerminalTokens.TokenNameboolean: case TerminalTokens.TokenNamecase: case TerminalTokens.TokenNamechar: case TerminalTokens.TokenNamecatch: case TerminalTokens.TokenNameclass: case TerminalTokens.TokenNamecontinue: case TerminalTokens.TokenNamedo: case TerminalTokens.TokenNamedouble: case TerminalTokens.TokenNamedefault: case TerminalTokens.TokenNameelse: case TerminalTokens.TokenNameextends: case TerminalTokens.TokenNamefor: case TerminalTokens.TokenNamefinal: case TerminalTokens.TokenNamefloat: case TerminalTokens.TokenNamefalse: case TerminalTokens.TokenNamefinally: case TerminalTokens.TokenNameif: case TerminalTokens.TokenNameint: case TerminalTokens.TokenNameimport: case TerminalTokens.TokenNameinterface: case TerminalTokens.TokenNameimplements: case TerminalTokens.TokenNameinstanceof: case TerminalTokens.TokenNamelong: case TerminalTokens.TokenNamenew: case TerminalTokens.TokenNamenull: case TerminalTokens.TokenNamenative: case TerminalTokens.TokenNamepublic: case TerminalTokens.TokenNamepackage: case TerminalTokens.TokenNameprivate: case TerminalTokens.TokenNameprotected: case TerminalTokens.TokenNamereturn: case TerminalTokens.TokenNameshort: case TerminalTokens.TokenNamesuper: case TerminalTokens.TokenNamestatic: case TerminalTokens.TokenNameswitch: case TerminalTokens.TokenNamestrictfp: case TerminalTokens.TokenNamesynchronized: case TerminalTokens.TokenNametry: case TerminalTokens.TokenNamethis: case TerminalTokens.TokenNametrue: case TerminalTokens.TokenNamethrow: case TerminalTokens.TokenNamethrows: case TerminalTokens.TokenNametransient: case TerminalTokens.TokenNamevoid: case TerminalTokens.TokenNamevolatile: case TerminalTokens.TokenNamewhile: return true; default: return false; } } private boolean isLiteral(int token) { switch(token) { case TerminalTokens.TokenNameIntegerLiteral: case TerminalTokens.TokenNameLongLiteral: case TerminalTokens.TokenNameFloatingPointLiteral: case TerminalTokens.TokenNameDoubleLiteral: case TerminalTokens.TokenNameStringLiteral: case TerminalTokens.TokenNameCharacterLiteral: return true; default: return false; } } public void javadocAmbiguousMethodReference(int sourceStart, int sourceEnd, Binding fieldBinding, int modifiers) { int id = IProblem.JavadocAmbiguousMethodReference; if (javadocVisibility(this.options.reportInvalidJavadocTagsVisibility, modifiers)) { String[] arguments = new String[] {new String(fieldBinding.readableName())}; handle(id, arguments, arguments, sourceStart, sourceEnd); } } public void javadocDeprecatedField(FieldBinding field, ASTNode location, int modifiers) { if (javadocVisibility(this.options.reportInvalidJavadocTagsVisibility, modifiers)) { this.handle( IProblem.JavadocUsingDeprecatedField, new String[] {new String(field.declaringClass.readableName()), new String(field.name)}, new String[] {new String(field.declaringClass.shortReadableName()), new String(field.name)}, location.sourceStart, location.sourceEnd); } } public void javadocDeprecatedMethod(MethodBinding method, ASTNode location, int modifiers) { if (javadocVisibility(this.options.reportInvalidJavadocTagsVisibility, modifiers)) { if (method.isConstructor()) { this.handle( IProblem.JavadocUsingDeprecatedConstructor, new String[] {new String(method.declaringClass.readableName()), typesAsString(method.isVarargs(), method.parameters, false)}, new String[] {new String(method.declaringClass.shortReadableName()), typesAsString(method.isVarargs(), method.parameters, true)}, location.sourceStart, location.sourceEnd); } else { this.handle( IProblem.JavadocUsingDeprecatedMethod, new String[] {new String(method.declaringClass.readableName()), new String(method.selector), typesAsString(method.isVarargs(), method.parameters, false)}, new String[] {new String(method.declaringClass.shortReadableName()), new String(method.selector), typesAsString(method.isVarargs(), method.parameters, true)}, location.sourceStart, location.sourceEnd); } } } public void javadocDeprecatedType(TypeBinding type, ASTNode location, int modifiers) { if (location == null) return; // 1G828DN - no type ref for synthetic arguments if (javadocVisibility(this.options.reportInvalidJavadocTagsVisibility, modifiers)) { this.handle( IProblem.JavadocUsingDeprecatedType, new String[] {new String(type.readableName())}, new String[] {new String(type.shortReadableName())}, location.sourceStart, location.sourceEnd); } } public void javadocDuplicatedParamTag(char[] token, int sourceStart, int sourceEnd, int modifiers) { if (javadocVisibility(this.options.reportInvalidJavadocTagsVisibility, modifiers)) { String[] arguments = new String[] {String.valueOf(token)}; this.handle(IProblem.JavadocDuplicateParamName, arguments, arguments, sourceStart, sourceEnd); } } public void javadocDuplicatedReturnTag(int sourceStart, int sourceEnd){ this.handle(IProblem.JavadocDuplicateReturnTag, NoArgument, NoArgument, sourceStart, sourceEnd); } public void javadocDuplicatedThrowsClassName(TypeReference typeReference, int modifiers) { if (javadocVisibility(this.options.reportInvalidJavadocTagsVisibility, modifiers)) { String[] arguments = new String[] {String.valueOf(typeReference.resolvedType.sourceName())}; this.handle(IProblem.JavadocDuplicateThrowsClassName, arguments, arguments, typeReference.sourceStart, typeReference.sourceEnd); } } public void javadocEmptyReturnTag(int sourceStart, int sourceEnd) { this.handle(IProblem.JavadocEmptyReturnTag, NoArgument, NoArgument, sourceStart, sourceEnd); } public void javadocErrorNoMethodFor(MessageSend messageSend, TypeBinding recType, TypeBinding[] params, int modifiers) { StringBuffer buffer = new StringBuffer(); StringBuffer shortBuffer = new StringBuffer(); for (int i = 0, length = params.length; i < length; i++) { if (i != 0){ buffer.append(", "); //$NON-NLS-1$ shortBuffer.append(", "); //$NON-NLS-1$ } buffer.append(new String(params[i].readableName())); shortBuffer.append(new String(params[i].shortReadableName())); } int id = recType.isArrayType() ? IProblem.JavadocNoMessageSendOnArrayType : IProblem.JavadocNoMessageSendOnBaseType; if (javadocVisibility(this.options.reportInvalidJavadocTagsVisibility, modifiers)) { this.handle( id, new String[] {new String(recType.readableName()), new String(messageSend.selector), buffer.toString()}, new String[] {new String(recType.shortReadableName()), new String(messageSend.selector), shortBuffer.toString()}, messageSend.sourceStart, messageSend.sourceEnd); } } public void javadocInvalidConstructor(Statement statement, MethodBinding targetConstructor, int modifiers) { if (!javadocVisibility(this.options.reportInvalidJavadocTagsVisibility, modifiers)) return; int id = IProblem.JavadocUndefinedConstructor; //default... switch (targetConstructor.problemId()) { case NotFound : id = IProblem.JavadocUndefinedConstructor; break; case NotVisible : id = IProblem.JavadocNotVisibleConstructor; break; case Ambiguous : id = IProblem.JavadocAmbiguousConstructor; break; case NoError : // 0 default : needImplementation(); // want to fail to see why we were here... break; } this.handle( id, new String[] {new String(targetConstructor.declaringClass.readableName()), typesAsString(targetConstructor.isVarargs(), targetConstructor.parameters, false)}, new String[] {new String(targetConstructor.declaringClass.shortReadableName()), typesAsString(targetConstructor.isVarargs(), targetConstructor.parameters, true)}, statement.sourceStart, statement.sourceEnd); } /* * Similar implementation than invalidField(FieldReference...) * Note that following problem id cannot occur for Javadoc: * - NonStaticReferenceInStaticContext : * - NonStaticReferenceInConstructorInvocation : * - ReceiverTypeNotVisible : */ public void javadocInvalidField(int sourceStart, int sourceEnd, Binding fieldBinding, TypeBinding searchedType, int modifiers) { int id = IProblem.JavadocUndefinedField; switch (fieldBinding.problemId()) { case NotFound : id = IProblem.JavadocUndefinedField; break; case NotVisible : id = IProblem.JavadocNotVisibleField; break; case Ambiguous : id = IProblem.JavadocAmbiguousField; break; case InheritedNameHidesEnclosingName : id = IProblem.JavadocInheritedFieldHidesEnclosingName; break; case NoError : // 0 default : needImplementation(); // want to fail to see why we were here... break; } // report issue if (javadocVisibility(this.options.reportInvalidJavadocTagsVisibility, modifiers)) { String[] arguments = new String[] {new String(fieldBinding.readableName())}; handle(id, arguments, arguments, sourceStart, sourceEnd); } } /* * Similar implementation than invalidMethod(MessageSend...) * Note that following problem id cannot occur for Javadoc: * - NonStaticReferenceInStaticContext : * - NonStaticReferenceInConstructorInvocation : * - ReceiverTypeNotVisible : */ public void javadocInvalidMethod(MessageSend messageSend, MethodBinding method, int modifiers) { if (!javadocVisibility(this.options.reportInvalidJavadocTagsVisibility, modifiers)) return; // set problem id int id = IProblem.JavadocUndefinedMethod; //default... switch (method.problemId()) { case NotFound : id = IProblem.JavadocUndefinedMethod; break; case NotVisible : id = IProblem.JavadocNotVisibleMethod; break; case Ambiguous : id = IProblem.JavadocAmbiguousMethod; break; case InheritedNameHidesEnclosingName : id = IProblem.JavadocInheritedMethodHidesEnclosingName; break; case NoError : // 0 default : needImplementation(); // want to fail to see why we were here... break; } if (id == IProblem.JavadocUndefinedMethod) { ProblemMethodBinding problemMethod = (ProblemMethodBinding) method; if (problemMethod.closestMatch != null) { String closestParameterTypeNames = typesAsString(problemMethod.closestMatch.isVarargs(), problemMethod.closestMatch.parameters, false); String parameterTypeNames = typesAsString(method.isVarargs(), method.parameters, false); String closestParameterTypeShortNames = typesAsString(problemMethod.closestMatch.isVarargs(), problemMethod.closestMatch.parameters, true); String parameterTypeShortNames = typesAsString(method.isVarargs(), method.parameters, true); if (closestParameterTypeShortNames.equals(parameterTypeShortNames)){ closestParameterTypeShortNames = closestParameterTypeNames; parameterTypeShortNames = parameterTypeNames; } this.handle( IProblem.JavadocParameterMismatch, new String[] { new String(problemMethod.closestMatch.declaringClass.readableName()), new String(problemMethod.closestMatch.selector), closestParameterTypeNames, parameterTypeNames }, new String[] { new String(problemMethod.closestMatch.declaringClass.shortReadableName()), new String(problemMethod.closestMatch.selector), closestParameterTypeShortNames, parameterTypeShortNames }, (int) (messageSend.nameSourcePosition >>> 32), (int) messageSend.nameSourcePosition); return; } } // report issue this.handle( id, new String[] { new String(method.declaringClass.readableName()), new String(method.selector), typesAsString(method.isVarargs(), method.parameters, false)}, new String[] { new String(method.declaringClass.shortReadableName()), new String(method.selector), typesAsString(method.isVarargs(), method.parameters, true)}, (int) (messageSend.nameSourcePosition >>> 32), (int) messageSend.nameSourcePosition); } public void javadocInvalidParamTagName(int sourceStart, int sourceEnd) { this.handle(IProblem.JavadocInvalidParamTagName, NoArgument, NoArgument, sourceStart, sourceEnd); } public void javadocInvalidParamTypeParameter(int sourceStart, int sourceEnd) { this.handle(IProblem.JavadocInvalidParamTagTypeParameter, NoArgument, NoArgument, sourceStart, sourceEnd); } public void javadocInvalidReference(int sourceStart, int sourceEnd) { this.handle(IProblem.JavadocInvalidReference, NoArgument, NoArgument, sourceStart, sourceEnd); } public void javadocInvalidSeeReferenceArgs(int sourceStart, int sourceEnd) { this.handle(IProblem.JavadocInvalidSeeArgs, NoArgument, NoArgument, sourceStart, sourceEnd); } public void javadocInvalidSeeUrlReference(int sourceStart, int sourceEnd) { this.handle(IProblem.JavadocInvalidSeeHref, NoArgument, NoArgument, sourceStart, sourceEnd); } public void javadocInvalidTag(int sourceStart, int sourceEnd) { this.handle(IProblem.JavadocInvalidTag, NoArgument, NoArgument, sourceStart, sourceEnd); } public void javadocInvalidThrowsClass(int sourceStart, int sourceEnd) { this.handle(IProblem.JavadocInvalidThrowsClass, NoArgument, NoArgument, sourceStart, sourceEnd); } public void javadocInvalidThrowsClassName(TypeReference typeReference, int modifiers) { if (javadocVisibility(this.options.reportInvalidJavadocTagsVisibility, modifiers)) { String[] arguments = new String[] {String.valueOf(typeReference.resolvedType.sourceName())}; this.handle(IProblem.JavadocInvalidThrowsClassName, arguments, arguments, typeReference.sourceStart, typeReference.sourceEnd); } } public void javadocInvalidType(ASTNode location, TypeBinding type, int modifiers) { if (javadocVisibility(this.options.reportInvalidJavadocTagsVisibility, modifiers)) { int id = IProblem.JavadocUndefinedType; // default switch (type.problemId()) { case NotFound : id = IProblem.JavadocUndefinedType; break; case NotVisible : id = IProblem.JavadocNotVisibleType; break; case Ambiguous : id = IProblem.JavadocAmbiguousType; break; case InternalNameProvided : id = IProblem.JavadocInternalTypeNameProvided; break; case InheritedNameHidesEnclosingName : id = IProblem.JavadocInheritedNameHidesEnclosingTypeName; break; case NoError : // 0 default : needImplementation(); // want to fail to see why we were here... break; } this.handle( id, new String[] {new String(type.readableName())}, new String[] {new String(type.shortReadableName())}, location.sourceStart, location.sourceEnd); } } public void javadocInvalidValueReference(int sourceStart, int sourceEnd, int modifiers) { if (javadocVisibility(this.options.reportInvalidJavadocTagsVisibility, modifiers)) this.handle(IProblem.JavadocInvalidValueReference, NoArgument, NoArgument, sourceStart, sourceEnd); } public void javadocMalformedSeeReference(int sourceStart, int sourceEnd) { this.handle(IProblem.JavadocMalformedSeeReference, NoArgument, NoArgument, sourceStart, sourceEnd); } public void javadocMissing(int sourceStart, int sourceEnd, int modifiers){ boolean overriding = (modifiers & (CompilerModifiers.AccImplementing|CompilerModifiers.AccOverriding)) != 0; boolean report = (this.options.getSeverity(CompilerOptions.MissingJavadocComments) != ProblemSeverities.Ignore) && (!overriding || this.options.reportMissingJavadocCommentsOverriding); if (report) { String arg = javadocVisibilityArgument(this.options.reportMissingJavadocCommentsVisibility, modifiers); if (arg != null) { String[] arguments = new String[] { arg }; this.handle(IProblem.JavadocMissing, arguments, arguments, sourceStart, sourceEnd); } } } public void javadocMissingHashCharacter(int sourceStart, int sourceEnd, String ref){ String[] arguments = new String[] { ref }; this.handle(IProblem.JavadocMissingHashCharacter, arguments, arguments, sourceStart, sourceEnd); } public void javadocMissingParamName(int sourceStart, int sourceEnd, int modifiers){ if (javadocVisibility(this.options.reportInvalidJavadocTagsVisibility, modifiers)) this.handle(IProblem.JavadocMissingParamName, NoArgument, NoArgument, sourceStart, sourceEnd); } public void javadocMissingParamTag(char[] name, int sourceStart, int sourceEnd, int modifiers) { boolean overriding = (modifiers & (CompilerModifiers.AccImplementing|CompilerModifiers.AccOverriding)) != 0; boolean report = (this.options.getSeverity(CompilerOptions.MissingJavadocTags) != ProblemSeverities.Ignore) && (!overriding || this.options.reportMissingJavadocTagsOverriding); if (report && javadocVisibility(this.options.reportMissingJavadocTagsVisibility, modifiers)) { String[] arguments = new String[] { String.valueOf(name) }; this.handle(IProblem.JavadocMissingParamTag, arguments, arguments, sourceStart, sourceEnd); } } public void javadocMissingReference(int sourceStart, int sourceEnd, int modifiers){ if (javadocVisibility(this.options.reportInvalidJavadocTagsVisibility, modifiers)) this.handle(IProblem.JavadocMissingReference, NoArgument, NoArgument, sourceStart, sourceEnd); } public void javadocMissingReturnTag(int sourceStart, int sourceEnd, int modifiers){ boolean overriding = (modifiers & (CompilerModifiers.AccImplementing|CompilerModifiers.AccOverriding)) != 0; boolean report = (this.options.getSeverity(CompilerOptions.MissingJavadocTags) != ProblemSeverities.Ignore) && (!overriding || this.options.reportMissingJavadocTagsOverriding); if (report && javadocVisibility(this.options.reportMissingJavadocTagsVisibility, modifiers)) { this.handle(IProblem.JavadocMissingReturnTag, NoArgument, NoArgument, sourceStart, sourceEnd); } } public void javadocMissingThrowsClassName(int sourceStart, int sourceEnd, int modifiers){ if (javadocVisibility(this.options.reportInvalidJavadocTagsVisibility, modifiers)) this.handle(IProblem.JavadocMissingThrowsClassName, NoArgument, NoArgument, sourceStart, sourceEnd); } public void javadocMissingThrowsTag(TypeReference typeRef, int modifiers){ boolean overriding = (modifiers & (CompilerModifiers.AccImplementing|CompilerModifiers.AccOverriding)) != 0; boolean report = (this.options.getSeverity(CompilerOptions.MissingJavadocTags) != ProblemSeverities.Ignore) && (!overriding || this.options.reportMissingJavadocTagsOverriding); if (report && javadocVisibility(this.options.reportMissingJavadocTagsVisibility, modifiers)) { String[] arguments = new String[] { String.valueOf(typeRef.resolvedType.sourceName()) }; this.handle(IProblem.JavadocMissingThrowsTag, arguments, arguments, typeRef.sourceStart, typeRef.sourceEnd); } } public void javadocUndeclaredParamTagName(char[] token, int sourceStart, int sourceEnd, int modifiers) { if (javadocVisibility(this.options.reportInvalidJavadocTagsVisibility, modifiers)) { String[] arguments = new String[] {String.valueOf(token)}; this.handle(IProblem.JavadocInvalidParamName, arguments, arguments, sourceStart, sourceEnd); } } public void javadocUnexpectedTag(int sourceStart, int sourceEnd) { this.handle(IProblem.JavadocUnexpectedTag, NoArgument, NoArgument, sourceStart, sourceEnd); } public void javadocUnexpectedText(int sourceStart, int sourceEnd) { this.handle(IProblem.JavadocUnexpectedText, NoArgument, NoArgument, sourceStart, sourceEnd); } public void javadocUnterminatedInlineTag(int sourceStart, int sourceEnd) { this.handle(IProblem.JavadocUnterminatedInlineTag, NoArgument, NoArgument, sourceStart, sourceEnd); } private boolean javadocVisibility(int visibility, int modifiers) { if (modifiers < 0) return true; switch (modifiers & CompilerModifiers.AccVisibilityMASK) { case IConstants.AccPublic : return true; case IConstants.AccProtected: return (visibility != IConstants.AccPublic); case IConstants.AccDefault: return (visibility == IConstants.AccDefault || visibility == IConstants.AccPrivate); case IConstants.AccPrivate: return (visibility == IConstants.AccPrivate); } return true; } private String javadocVisibilityArgument(int visibility, int modifiers) { String argument = null; switch (modifiers & CompilerModifiers.AccVisibilityMASK) { case IConstants.AccPublic : argument = CompilerOptions.PUBLIC; break; case IConstants.AccProtected: if (visibility != IConstants.AccPublic) { argument = CompilerOptions.PROTECTED; } break; case IConstants.AccDefault: if (visibility == IConstants.AccDefault || visibility == IConstants.AccPrivate) { argument = CompilerOptions.DEFAULT; } break; case IConstants.AccPrivate: if (visibility == IConstants.AccPrivate) { argument = CompilerOptions.PRIVATE; } break; } return argument; } public void localVariableCannotBeNull(LocalVariableBinding local, ASTNode location) { String[] arguments = new String[] {new String(local.name) }; this.handle( IProblem.LocalVariableCannotBeNull, arguments, arguments, location.sourceStart, location.sourceEnd); } public void localVariableCanOnlyBeNull(LocalVariableBinding local, ASTNode location) { String[] arguments = new String[] {new String(local.name) }; this.handle( IProblem.LocalVariableCanOnlyBeNull, arguments, arguments, location.sourceStart, location.sourceEnd); } public void localVariableHiding(LocalDeclaration local, Binding hiddenVariable, boolean isSpecialArgHidingField) { if (hiddenVariable instanceof LocalVariableBinding) { String[] arguments = new String[] {new String(local.name) }; this.handle( (local instanceof Argument) ? IProblem.ArgumentHidingLocalVariable : IProblem.LocalVariableHidingLocalVariable, arguments, arguments, local.sourceStart, local.sourceEnd); } else if (hiddenVariable instanceof FieldBinding) { if (isSpecialArgHidingField && !this.options.reportSpecialParameterHidingField){ return; } FieldBinding field = (FieldBinding) hiddenVariable; this.handle( (local instanceof Argument) ? IProblem.ArgumentHidingField : IProblem.LocalVariableHidingField, new String[] {new String(local.name) , new String(field.declaringClass.readableName()) }, new String[] {new String(local.name), new String(field.declaringClass.shortReadableName()) }, local.sourceStart, local.sourceEnd); } } public void methodNameClash(MethodBinding currentMethod, MethodBinding inheritedMethod) { this.handle( IProblem.MethodNameClash, new String[] { new String(currentMethod.selector), typesAsString(currentMethod.original().isVarargs(), currentMethod.original().parameters, false), new String(currentMethod.declaringClass.readableName()), typesAsString(inheritedMethod.original().isVarargs(), inheritedMethod.original().parameters, false), new String(inheritedMethod.declaringClass.readableName()), }, new String[] { new String(currentMethod.selector), typesAsString(currentMethod.original().isVarargs(), currentMethod.original().parameters, true), new String(currentMethod.declaringClass.shortReadableName()), typesAsString(inheritedMethod.original().isVarargs(), inheritedMethod.original().parameters, true), new String(inheritedMethod.declaringClass.shortReadableName()), }, currentMethod.sourceStart(), currentMethod.sourceEnd()); } public void methodNeedBody(AbstractMethodDeclaration methodDecl) { this.handle( IProblem.MethodRequiresBody, NoArgument, NoArgument, methodDecl.sourceStart, methodDecl.sourceEnd); } public void methodNeedingNoBody(MethodDeclaration methodDecl) { this.handle( ((methodDecl.modifiers & IConstants.AccNative) != 0) ? IProblem.BodyForNativeMethod : IProblem.BodyForAbstractMethod, NoArgument, NoArgument, methodDecl.sourceStart, methodDecl.sourceEnd); } public void methodWithConstructorName(MethodDeclaration methodDecl) { this.handle( IProblem.MethodButWithConstructorName, NoArgument, NoArgument, methodDecl.sourceStart, methodDecl.sourceEnd); } public void parameterizedMemberTypeMissingArguments(ASTNode location, TypeBinding type) { if (location == null) { // binary case this.handle( IProblem.MissingArgumentsForParameterizedMemberType, new String[] {new String(type.readableName())}, new String[] {new String(type.shortReadableName())}, AbortCompilation | Error, 0, 1); return; } this.handle( IProblem.MissingArgumentsForParameterizedMemberType, new String[] {new String(type.readableName())}, new String[] {new String(type.shortReadableName())}, location.sourceStart, location.sourceEnd); } public void missingReturnType(AbstractMethodDeclaration methodDecl) { this.handle( IProblem.MissingReturnType, NoArgument, NoArgument, methodDecl.sourceStart, methodDecl.sourceEnd); } public void missingSemiColon(Expression expression){ this.handle( IProblem.MissingSemiColon, NoArgument, NoArgument, expression.sourceStart, expression.sourceEnd); } public void missingSerialVersion(TypeDeclaration typeDecl) { String[] arguments = new String[] {new String(typeDecl.name)}; this.handle( IProblem.MissingSerialVersion, arguments, arguments, typeDecl.sourceStart, typeDecl.sourceEnd); } public void missingValueForAnnotationMember(Annotation annotation, char[] memberName) { String memberString = new String(memberName); this.handle( IProblem.MissingValueForAnnotationMember, new String[] {new String(annotation.resolvedType.readableName()), memberString }, new String[] {new String(annotation.resolvedType.shortReadableName()), memberString}, annotation.sourceStart, annotation.sourceEnd); } public void mustDefineDimensionsOrInitializer(ArrayAllocationExpression expression) { this.handle( IProblem.MustDefineEitherDimensionExpressionsOrInitializer, NoArgument, NoArgument, expression.sourceStart, expression.sourceEnd); } public void mustSpecifyPackage(CompilationUnitDeclaration compUnitDecl) { String[] arguments = new String[] {new String(compUnitDecl.getFileName())}; this.handle( IProblem.MustSpecifyPackage, arguments, arguments, compUnitDecl.sourceStart, compUnitDecl.sourceStart + 1); } public void mustUseAStaticMethod(MessageSend messageSend, MethodBinding method) { this.handle( IProblem.StaticMethodRequested, new String[] {new String(method.declaringClass.readableName()), new String(method.selector), typesAsString(method.isVarargs(), method.parameters, false)}, new String[] {new String(method.declaringClass.shortReadableName()), new String(method.selector), typesAsString(method.isVarargs(), method.parameters, true)}, messageSend.sourceStart, messageSend.sourceEnd); } public void nativeMethodsCannotBeStrictfp(ReferenceBinding type, AbstractMethodDeclaration methodDecl) { String[] arguments = new String[] {new String(type.sourceName()), new String(methodDecl.selector)}; this.handle( IProblem.NativeMethodsCannotBeStrictfp, arguments, arguments, methodDecl.sourceStart, methodDecl.sourceEnd); } public void needImplementation() { this.abortDueToInternalError(Util.bind("abort.missingCode")); //$NON-NLS-1$ } public void needToEmulateFieldAccess(FieldBinding field, ASTNode location, boolean isReadAccess) { this.handle( isReadAccess ? IProblem.NeedToEmulateFieldReadAccess : IProblem.NeedToEmulateFieldWriteAccess, new String[] {new String(field.declaringClass.readableName()), new String(field.name)}, new String[] {new String(field.declaringClass.shortReadableName()), new String(field.name)}, location.sourceStart, location.sourceEnd); } public void needToEmulateMethodAccess( MethodBinding method, ASTNode location) { if (method.isConstructor()) this.handle( IProblem.NeedToEmulateConstructorAccess, new String[] { new String(method.declaringClass.readableName()), typesAsString(method.isVarargs(), method.parameters, false) }, new String[] { new String(method.declaringClass.shortReadableName()), typesAsString(method.isVarargs(), method.parameters, true) }, location.sourceStart, location.sourceEnd); else this.handle( IProblem.NeedToEmulateMethodAccess, new String[] { new String(method.declaringClass.readableName()), new String(method.selector), typesAsString(method.isVarargs(), method.parameters, false) }, new String[] { new String(method.declaringClass.shortReadableName()), new String(method.selector), typesAsString(method.isVarargs(), method.parameters, true) }, location.sourceStart, location.sourceEnd); } public void nestedClassCannotDeclareInterface(TypeDeclaration typeDecl) { String[] arguments = new String[] {new String(typeDecl.name)}; this.handle( IProblem.CannotDefineInterfaceInLocalType, arguments, arguments, typeDecl.sourceStart, typeDecl.sourceEnd); } public void noMoreAvailableSpaceForArgument(LocalVariableBinding local, ASTNode location) { String[] arguments = new String[]{ new String(local.name) }; this.handle( local instanceof SyntheticArgumentBinding ? IProblem.TooManySyntheticArgumentSlots : IProblem.TooManyArgumentSlots, arguments, arguments, Abort | Error, location.sourceStart, location.sourceEnd); } public void noMoreAvailableSpaceForConstant(TypeDeclaration typeDeclaration) { this.handle( IProblem.TooManyBytesForStringConstant, new String[]{ new String(typeDeclaration.binding.readableName())}, new String[]{ new String(typeDeclaration.binding.shortReadableName())}, Abort | Error, typeDeclaration.sourceStart, typeDeclaration.sourceEnd); } public void noMoreAvailableSpaceForLocal(LocalVariableBinding local, ASTNode location) { String[] arguments = new String[]{ new String(local.name) }; this.handle( IProblem.TooManyLocalVariableSlots, arguments, arguments, Abort | Error, location.sourceStart, location.sourceEnd); } public void noMoreAvailableSpaceInConstantPool(TypeDeclaration typeDeclaration) { this.handle( IProblem.TooManyConstantsInConstantPool, new String[]{ new String(typeDeclaration.binding.readableName())}, new String[]{ new String(typeDeclaration.binding.shortReadableName())}, Abort | Error, typeDeclaration.sourceStart, typeDeclaration.sourceEnd); } public void nonExternalizedStringLiteral(ASTNode location) { this.handle( IProblem.NonExternalizedStringLiteral, NoArgument, NoArgument, location.sourceStart, location.sourceEnd); } public void nonGenericTypeCannotBeParameterized(ASTNode location, TypeBinding type, TypeBinding[] argumentTypes) { if (location == null) { // binary case this.handle( IProblem.NonGenericType, new String[] {new String(type.readableName()), typesAsString(false, argumentTypes, false)}, new String[] {new String(type.shortReadableName()), typesAsString(false, argumentTypes, true)}, AbortCompilation | Error, 0, 1); return; } this.handle( IProblem.NonGenericType, new String[] {new String(type.readableName()), typesAsString(false, argumentTypes, false)}, new String[] {new String(type.shortReadableName()), typesAsString(false, argumentTypes, true)}, location.sourceStart, location.sourceEnd); } public void nonStaticAccessToStaticField(ASTNode location, FieldBinding field) { this.handle( IProblem.NonStaticAccessToStaticField, new String[] {new String(field.declaringClass.readableName()), new String(field.name)}, new String[] {new String(field.declaringClass.shortReadableName()), new String(field.name)}, location.sourceStart, fieldLocation(field, location)); } public void nonStaticAccessToStaticMethod(ASTNode location, MethodBinding method) { this.handle( IProblem.NonStaticAccessToStaticMethod, new String[] {new String(method.declaringClass.readableName()), new String(method.selector), typesAsString(method.isVarargs(), method.parameters, false)}, new String[] {new String(method.declaringClass.shortReadableName()), new String(method.selector), typesAsString(method.isVarargs(), method.parameters, true)}, location.sourceStart, location.sourceEnd); } public void noSuchEnclosingInstance(TypeBinding targetType, ASTNode location, boolean isConstructorCall) { int id; if (isConstructorCall) { //28 = No enclosing instance of type {0} is available due to some intermediate constructor invocation id = IProblem.EnclosingInstanceInConstructorCall; } else if ((location instanceof ExplicitConstructorCall) && ((ExplicitConstructorCall) location).accessMode == ExplicitConstructorCall.ImplicitSuper) { //20 = No enclosing instance of type {0} is accessible to invoke the super constructor. Must define a constructor and explicitly qualify its super constructor invocation with an instance of {0} (e.g. x.super() where x is an instance of {0}). id = IProblem.MissingEnclosingInstanceForConstructorCall; } else if (location instanceof AllocationExpression && (((AllocationExpression) location).binding.declaringClass.isMemberType() || (((AllocationExpression) location).binding.declaringClass.isAnonymousType() && ((AllocationExpression) location).binding.declaringClass.superclass().isMemberType()))) { //21 = No enclosing instance of type {0} is accessible. Must qualify the allocation with an enclosing instance of type {0} (e.g. x.new A() where x is an instance of {0}). id = IProblem.MissingEnclosingInstance; } else { // default //22 = No enclosing instance of the type {0} is accessible in scope id = IProblem.IncorrectEnclosingInstanceReference; } this.handle( id, new String[] { new String(targetType.readableName())}, new String[] { new String(targetType.shortReadableName())}, location.sourceStart, location.sourceEnd); } public void notCompatibleTypesError(EqualExpression expression, TypeBinding leftType, TypeBinding rightType) { String leftName = new String(leftType.readableName()); String rightName = new String(rightType.readableName()); String leftShortName = new String(leftType.shortReadableName()); String rightShortName = new String(rightType.shortReadableName()); if (leftShortName.equals(rightShortName)){ leftShortName = leftName; rightShortName = rightName; } this.handle( IProblem.IncompatibleTypesInEqualityOperator, new String[] {leftName, rightName }, new String[] {leftShortName, rightShortName }, expression.sourceStart, expression.sourceEnd); } public void notCompatibleTypesError(InstanceOfExpression expression, TypeBinding leftType, TypeBinding rightType) { String leftName = new String(leftType.readableName()); String rightName = new String(rightType.readableName()); String leftShortName = new String(leftType.shortReadableName()); String rightShortName = new String(rightType.shortReadableName()); if (leftShortName.equals(rightShortName)){ leftShortName = leftName; rightShortName = rightName; } this.handle( IProblem.IncompatibleTypesInConditionalOperator, new String[] {leftName, rightName }, new String[] {leftShortName, rightShortName }, expression.sourceStart, expression.sourceEnd); } public void notCompatibleTypesErrorInForeach(Expression expression, TypeBinding leftType, TypeBinding rightType) { String leftName = new String(leftType.readableName()); String rightName = new String(rightType.readableName()); String leftShortName = new String(leftType.shortReadableName()); String rightShortName = new String(rightType.shortReadableName()); if (leftShortName.equals(rightShortName)){ leftShortName = leftName; rightShortName = rightName; } this.handle( IProblem.IncompatibleTypesInForeach, new String[] {leftName, rightName }, new String[] {leftShortName, rightShortName }, expression.sourceStart, expression.sourceEnd); } public void objectCannotBeGeneric(TypeDeclaration typeDecl) { this.handle( IProblem.ObjectCannotBeGeneric, NoArgument, NoArgument, typeDecl.typeParameters[0].sourceStart, typeDecl.typeParameters[typeDecl.typeParameters.length-1].sourceEnd); } public void objectCannotHaveSuperTypes(SourceTypeBinding type) { this.handle( IProblem.ObjectCannotHaveSuperTypes, NoArgument, NoArgument, type.sourceStart(), type.sourceEnd()); } public void objectMustBeClass(SourceTypeBinding type) { this.handle( IProblem.ObjectMustBeClass, NoArgument, NoArgument, type.sourceStart(), type.sourceEnd()); } public void operatorOnlyValidOnNumericType(CompoundAssignment assignment, TypeBinding leftType, TypeBinding rightType) { String leftName = new String(leftType.readableName()); String rightName = new String(rightType.readableName()); String leftShortName = new String(leftType.shortReadableName()); String rightShortName = new String(rightType.shortReadableName()); if (leftShortName.equals(rightShortName)){ leftShortName = leftName; rightShortName = rightName; } this.handle( IProblem.TypeMismatch, new String[] {leftName, rightName }, new String[] {leftShortName, rightShortName }, assignment.sourceStart, assignment.sourceEnd); } public void overridesDeprecatedMethod(MethodBinding localMethod, MethodBinding inheritedMethod) { this.handle( IProblem.OverridingDeprecatedMethod, new String[] { new String( CharOperation.concat( localMethod.declaringClass.readableName(), localMethod.readableName(), '.')), new String(inheritedMethod.declaringClass.readableName())}, new String[] { new String( CharOperation.concat( localMethod.declaringClass.shortReadableName(), localMethod.shortReadableName(), '.')), new String(inheritedMethod.declaringClass.shortReadableName())}, localMethod.sourceStart(), localMethod.sourceEnd()); } public void overridesPackageDefaultMethod(MethodBinding localMethod, MethodBinding inheritedMethod) { this.handle( IProblem.OverridingNonVisibleMethod, new String[] { new String( CharOperation.concat( localMethod.declaringClass.readableName(), localMethod.readableName(), '.')), new String(inheritedMethod.declaringClass.readableName())}, new String[] { new String( CharOperation.concat( localMethod.declaringClass.shortReadableName(), localMethod.shortReadableName(), '.')), new String(inheritedMethod.declaringClass.shortReadableName())}, localMethod.sourceStart(), localMethod.sourceEnd()); } public void packageCollidesWithType(CompilationUnitDeclaration compUnitDecl) { String[] arguments = new String[] {CharOperation.toString(compUnitDecl.currentPackage.tokens)}; this.handle( IProblem.PackageCollidesWithType, arguments, arguments, compUnitDecl.currentPackage.sourceStart, compUnitDecl.currentPackage.sourceEnd); } public void packageIsNotExpectedPackage(CompilationUnitDeclaration compUnitDecl) { String[] arguments = new String[] {CharOperation.toString(compUnitDecl.compilationResult.compilationUnit.getPackageName())}; this.handle( IProblem.PackageIsNotExpectedPackage, arguments, arguments, compUnitDecl.currentPackage == null ? 0 : compUnitDecl.currentPackage.sourceStart, compUnitDecl.currentPackage == null ? 0 : compUnitDecl.currentPackage.sourceEnd); } private String parameterBoundAsString(TypeVariableBinding typeVariable, boolean makeShort) { StringBuffer nameBuffer = new StringBuffer(10); if (typeVariable.firstBound == typeVariable.superclass) { nameBuffer.append(makeShort ? typeVariable.superclass.shortReadableName() : typeVariable.superclass.readableName()); } int length; if ((length = typeVariable.superInterfaces.length) > 0) { for (int i = 0; i < length; i++) { if (i > 0 || typeVariable.firstBound == typeVariable.superclass) nameBuffer.append(" & "); //$NON-NLS-1$ nameBuffer.append(makeShort ? typeVariable.superInterfaces[i].shortReadableName() : typeVariable.superInterfaces[i].readableName()); } } return nameBuffer.toString(); } public void parseError( int startPosition, int endPosition, int currentToken, char[] currentTokenSource, String errorTokenName, String[] possibleTokens) { if (possibleTokens.length == 0) { //no suggestion available if (isKeyword(currentToken)) { String[] arguments = new String[] {new String(currentTokenSource)}; this.handle( IProblem.ParsingErrorOnKeywordNoSuggestion, arguments, arguments, // this is the current -invalid- token position startPosition, endPosition); return; } else { String[] arguments = new String[] {errorTokenName}; this.handle( IProblem.ParsingErrorNoSuggestion, arguments, arguments, // this is the current -invalid- token position startPosition, endPosition); return; } } //build a list of probable right tokens StringBuffer list = new StringBuffer(20); for (int i = 0, max = possibleTokens.length; i < max; i++) { if (i > 0) list.append(", "); //$NON-NLS-1$ list.append('"'); list.append(possibleTokens[i]); list.append('"'); } if (isKeyword(currentToken)) { String[] arguments = new String[] {new String(currentTokenSource), list.toString()}; this.handle( IProblem.ParsingErrorOnKeyword, arguments, arguments, // this is the current -invalid- token position startPosition, endPosition); return; } //extract the literal when it's a literal if (isLiteral(currentToken) || isIdentifier(currentToken)) { //$NON-NLS-1$ errorTokenName = new String(currentTokenSource); } String[] arguments = new String[] {errorTokenName, list.toString()}; this.handle( IProblem.ParsingError, arguments, arguments, // this is the current -invalid- token position startPosition, endPosition); } public void parseErrorDeleteToken( int start, int end, int currentKind, char[] errorTokenSource, String errorTokenName){ this.syntaxError( IProblem.ParsingErrorDeleteToken, start, end, currentKind, errorTokenSource, errorTokenName, null); } public void parseErrorDeleteTokens( int start, int end){ this.handle( IProblem.ParsingErrorDeleteTokens, NoArgument, NoArgument, start, end); } public void parseErrorInsertAfterToken( int start, int end, int currentKind, char[] errorTokenSource, String errorTokenName, String expectedToken){ this.syntaxError( IProblem.ParsingErrorInsertTokenAfter, start, end, currentKind, errorTokenSource, errorTokenName, expectedToken); } public void parseErrorInsertBeforeToken( int start, int end, int currentKind, char[] errorTokenSource, String errorTokenName, String expectedToken){ this.syntaxError( IProblem.ParsingErrorInsertTokenBefore, start, end, currentKind, errorTokenSource, errorTokenName, expectedToken); } public void parseErrorInsertToComplete( int start, int end, String inserted, String completed){ String[] arguments = new String[] {inserted, completed}; this.handle( IProblem.ParsingErrorInsertToComplete, arguments, arguments, start, end); } public void parseErrorInsertToCompletePhrase( int start, int end, String inserted){ String[] arguments = new String[] {inserted}; this.handle( IProblem.ParsingErrorInsertToCompletePhrase, arguments, arguments, start, end); } public void parseErrorInsertToCompleteScope( int start, int end, String inserted){ String[] arguments = new String[] {inserted}; this.handle( IProblem.ParsingErrorInsertToCompleteScope, arguments, arguments, start, end); } public void parseErrorInvalidToken( int start, int end, int currentKind, char[] errorTokenSource, String errorTokenName, String expectedToken){ this.syntaxError( IProblem.ParsingErrorInvalidToken, start, end, currentKind, errorTokenSource, errorTokenName, expectedToken); } public void parseErrorMergeTokens( int start, int end, String expectedToken){ String[] arguments = new String[] {expectedToken}; this.handle( IProblem.ParsingErrorMergeTokens, arguments, arguments, start, end); } public void parseErrorMisplacedConstruct( int start, int end){ this.handle( IProblem.ParsingErrorMisplacedConstruct, NoArgument, NoArgument, start, end); } public void parseErrorNoSuggestion( int start, int end, int currentKind, char[] errorTokenSource, String errorTokenName){ this.syntaxError( IProblem.ParsingErrorNoSuggestion, start, end, currentKind, errorTokenSource, errorTokenName, null); } public void parseErrorNoSuggestionForTokens( int start, int end){ this.handle( IProblem.ParsingErrorNoSuggestionForTokens, NoArgument, NoArgument, start, end); } public void parseErrorReplaceToken( int start, int end, int currentKind, char[] errorTokenSource, String errorTokenName, String expectedToken){ this.syntaxError( IProblem.ParsingError, start, end, currentKind, errorTokenSource, errorTokenName, expectedToken); } public void parseErrorReplaceTokens( int start, int end, String expectedToken){ String[] arguments = new String[] {expectedToken}; this.handle( IProblem.ParsingErrorReplaceTokens, arguments, arguments, start, end); } public void parseErrorUnexpectedEnd( int start, int end){ String[] arguments; if(this.referenceContext instanceof ConstructorDeclaration) { arguments = new String[] {Util.bind("parser.endOfConstructor")}; //$NON-NLS-1$ } else if(this.referenceContext instanceof MethodDeclaration) { arguments = new String[] {Util.bind("parser.endOfMethod")}; //$NON-NLS-1$ } else if(this.referenceContext instanceof TypeDeclaration) { arguments = new String[] {Util.bind("parser.endOfInitializer")}; //$NON-NLS-1$ } else { arguments = new String[] {Util.bind("parser.endOfFile")}; //$NON-NLS-1$ } this.handle( IProblem.ParsingErrorUnexpectedEOF, arguments, arguments, start, end); } public void possibleAccidentalBooleanAssignment(Assignment assignment) { this.handle( IProblem.PossibleAccidentalBooleanAssignment, NoArgument, NoArgument, assignment.sourceStart, assignment.sourceEnd); } public void publicClassMustMatchFileName(CompilationUnitDeclaration compUnitDecl, TypeDeclaration typeDecl) { this.referenceContext = typeDecl; // report the problem against the type not the entire compilation unit String[] arguments = new String[] {new String(compUnitDecl.getFileName()), new String(typeDecl.name)}; this.handle( IProblem.PublicClassMustMatchFileName, arguments, arguments, typeDecl.sourceStart, typeDecl.sourceEnd, compUnitDecl.compilationResult); } public void rawMemberTypeCannotBeParameterized(ASTNode location, ReferenceBinding type, TypeBinding[] argumentTypes) { if (location == null) { // binary case this.handle( IProblem.RawMemberTypeCannotBeParameterized, new String[] {new String(type.readableName()), typesAsString(false, argumentTypes, false), new String(type.enclosingType().readableName())}, new String[] {new String(type.shortReadableName()), typesAsString(false, argumentTypes, true), new String(type.enclosingType().shortReadableName())}, AbortCompilation | Error, 0, 1); return; } this.handle( IProblem.RawMemberTypeCannotBeParameterized, new String[] {new String(type.readableName()), typesAsString(false, argumentTypes, false), new String(type.enclosingType().readableName())}, new String[] {new String(type.shortReadableName()), typesAsString(false, argumentTypes, true), new String(type.enclosingType().shortReadableName())}, location.sourceStart, location.sourceEnd); } public void recursiveConstructorInvocation(ExplicitConstructorCall constructorCall) { this.handle( IProblem.RecursiveConstructorInvocation, new String[] { new String(constructorCall.binding.declaringClass.readableName()), typesAsString(constructorCall.binding.isVarargs(), constructorCall.binding.parameters, false) }, new String[] { new String(constructorCall.binding.declaringClass.shortReadableName()), typesAsString(constructorCall.binding.isVarargs(), constructorCall.binding.parameters, true) }, constructorCall.sourceStart, constructorCall.sourceEnd); } public void redefineArgument(Argument arg) { String[] arguments = new String[] {new String(arg.name)}; this.handle( IProblem.RedefinedArgument, arguments, arguments, arg.sourceStart, arg.sourceEnd); } public void redefineLocal(LocalDeclaration localDecl) { String[] arguments = new String[] {new String(localDecl.name)}; this.handle( IProblem.RedefinedLocal, arguments, arguments, localDecl.sourceStart, localDecl.sourceEnd); } public void referenceMustBeArrayTypeAt(TypeBinding arrayType, ArrayReference arrayRef) { this.handle( IProblem.ArrayReferenceRequired, new String[] {new String(arrayType.readableName())}, new String[] {new String(arrayType.shortReadableName())}, arrayRef.sourceStart, arrayRef.sourceEnd); } public void returnTypeCannotBeVoidArray(SourceTypeBinding type, MethodDeclaration methodDecl) { String[] arguments = new String[] {new String(methodDecl.selector)}; this.handle( IProblem.ReturnTypeCannotBeVoidArray, arguments, arguments, methodDecl.sourceStart, methodDecl.sourceEnd); } public void scannerError(Parser parser, String errorTokenName) { Scanner scanner = parser.scanner; int flag = IProblem.ParsingErrorNoSuggestion; int startPos = scanner.startPosition; //special treatment for recognized errors.... if (errorTokenName.equals(Scanner.END_OF_SOURCE)) flag = IProblem.EndOfSource; else if (errorTokenName.equals(Scanner.INVALID_HEXA)) flag = IProblem.InvalidHexa; else if (errorTokenName.equals(Scanner.INVALID_OCTAL)) flag = IProblem.InvalidOctal; else if (errorTokenName.equals(Scanner.INVALID_CHARACTER_CONSTANT)) flag = IProblem.InvalidCharacterConstant; else if (errorTokenName.equals(Scanner.INVALID_ESCAPE)) flag = IProblem.InvalidEscape; else if (errorTokenName.equals(Scanner.INVALID_UNICODE_ESCAPE)){ flag = IProblem.InvalidUnicodeEscape; // better locate the error message char[] source = scanner.source; int checkPos = scanner.currentPosition - 1; if (checkPos >= source.length) checkPos = source.length - 1; while (checkPos >= startPos){ if (source[checkPos] == '\\') break; checkPos --; } startPos = checkPos; } else if (errorTokenName.equals(Scanner.INVALID_FLOAT)) flag = IProblem.InvalidFloat; else if (errorTokenName.equals(Scanner.UNTERMINATED_STRING)) flag = IProblem.UnterminatedString; else if (errorTokenName.equals(Scanner.UNTERMINATED_COMMENT)) flag = IProblem.UnterminatedComment; else if (errorTokenName.equals(Scanner.INVALID_CHAR_IN_STRING)) flag = IProblem.UnterminatedString; else if (errorTokenName.equals(Scanner.INVALID_DIGIT)) flag = IProblem.InvalidDigit; String[] arguments = flag == IProblem.ParsingErrorNoSuggestion ? new String[] {errorTokenName} : NoArgument; this.handle( flag, arguments, arguments, // this is the current -invalid- token position startPos, scanner.currentPosition - 1, parser.compilationUnit.compilationResult); } public void shouldReturn(TypeBinding returnType, ASTNode location) { this.handle( IProblem.ShouldReturnValue, new String[] { new String (returnType.readableName())}, new String[] { new String (returnType.shortReadableName())}, location.sourceStart, location.sourceEnd); } public void signalNoImplicitStringConversionForCharArrayExpression(Expression expression) { this.handle( IProblem.NoImplicitStringConversionForCharArrayExpression, NoArgument, NoArgument, expression.sourceStart, expression.sourceEnd); } public void staticAndInstanceConflict(MethodBinding currentMethod, MethodBinding inheritedMethod) { if (currentMethod.isStatic()) this.handle( // This static method cannot hide the instance method from %1 // 8.4.6.4 - If a class inherits more than one method with the same signature a static (non-abstract) method cannot hide an instance method. IProblem.CannotHideAnInstanceMethodWithAStaticMethod, new String[] {new String(inheritedMethod.declaringClass.readableName())}, new String[] {new String(inheritedMethod.declaringClass.shortReadableName())}, currentMethod.sourceStart(), currentMethod.sourceEnd()); else this.handle( // This instance method cannot override the static method from %1 // 8.4.6.4 - If a class inherits more than one method with the same signature an instance (non-abstract) method cannot override a static method. IProblem.CannotOverrideAStaticMethodWithAnInstanceMethod, new String[] {new String(inheritedMethod.declaringClass.readableName())}, new String[] {new String(inheritedMethod.declaringClass.shortReadableName())}, currentMethod.sourceStart(), currentMethod.sourceEnd()); } public void staticFieldAccessToNonStaticVariable(ASTNode location, FieldBinding field) { String[] arguments = new String[] {new String(field.readableName())}; this.handle( IProblem.NonStaticFieldFromStaticInvocation, arguments, arguments, location.sourceStart, fieldLocation(field, location)); } public void staticInheritedMethodConflicts(SourceTypeBinding type, MethodBinding concreteMethod, MethodBinding[] abstractMethods) { this.handle( // The static method %1 conflicts with the abstract method in %2 // 8.4.6.4 - If a class inherits more than one method with the same signature it is an error for one to be static (non-abstract) and the other abstract. IProblem.StaticInheritedMethodConflicts, new String[] { new String(concreteMethod.readableName()), new String(abstractMethods[0].declaringClass.readableName())}, new String[] { new String(concreteMethod.readableName()), new String(abstractMethods[0].declaringClass.shortReadableName())}, type.sourceStart(), type.sourceEnd()); } public void staticMemberOfParameterizedType(ASTNode location, ReferenceBinding type) { if (location == null) { // binary case this.handle( IProblem.StaticMemberOfParameterizedType, new String[] {new String(type.readableName()), new String(type.enclosingType().readableName()), }, new String[] {new String(type.shortReadableName()), new String(type.enclosingType().shortReadableName()), }, AbortCompilation | Error, 0, 1); return; } this.handle( IProblem.StaticMemberOfParameterizedType, new String[] {new String(type.readableName()), new String(type.enclosingType().readableName()), }, new String[] {new String(type.shortReadableName()), new String(type.enclosingType().shortReadableName()), }, location.sourceStart, location.sourceEnd); } public void stringConstantIsExceedingUtf8Limit(ASTNode location) { this.handle( IProblem.StringConstantIsExceedingUtf8Limit, NoArgument, NoArgument, location.sourceStart, location.sourceEnd); } public void superclassMustBeAClass(SourceTypeBinding type, TypeReference superclassRef, ReferenceBinding superType) { this.handle( IProblem.SuperclassMustBeAClass, new String[] {new String(superType.readableName()), new String(type.sourceName())}, new String[] {new String(superType.shortReadableName()), new String(type.sourceName())}, superclassRef.sourceStart, superclassRef.sourceEnd); } public void superfluousSemicolon(int sourceStart, int sourceEnd) { this.handle( IProblem.SuperfluousSemicolon, NoArgument, NoArgument, sourceStart, sourceEnd); } public void superinterfaceMustBeAnInterface(SourceTypeBinding type, TypeReference superInterfaceRef, ReferenceBinding superType) { this.handle( IProblem.SuperInterfaceMustBeAnInterface, new String[] {new String(superType.readableName()), new String(type.sourceName())}, new String[] {new String(superType.shortReadableName()), new String(type.sourceName())}, superInterfaceRef.sourceStart, superInterfaceRef.sourceEnd); } public void superinterfacesCollide(ReferenceBinding type, TypeDeclaration typeDecl, ReferenceBinding superType, ReferenceBinding inheritedSuperType) { this.handle( IProblem.SuperInterfacesCollide, new String[] {new String(superType.readableName()), new String(inheritedSuperType.readableName()), new String(type.sourceName())}, new String[] {new String(superType.shortReadableName()), new String(inheritedSuperType.shortReadableName()), new String(type.sourceName())}, typeDecl.sourceStart, typeDecl.sourceEnd); } public void superTypeCannotUseWildcard(SourceTypeBinding type, TypeReference superclass, TypeBinding superTypeBinding) { String name = new String(type.sourceName()); String superTypeFullName = new String(superTypeBinding.readableName()); String superTypeShortName = new String(superTypeBinding.shortReadableName()); if (superTypeShortName.equals(name)) superTypeShortName = superTypeFullName; this.handle( IProblem.SuperTypeUsingWildcard, new String[] {superTypeFullName, name}, new String[] {superTypeShortName, name}, superclass.sourceStart, superclass.sourceEnd); } private void syntaxError( int id, int startPosition, int endPosition, int currentKind, char[] currentTokenSource, String errorTokenName, String expectedToken) { String eTokenName; if (isKeyword(currentKind) || isLiteral(currentKind) || isIdentifier(currentKind)) { //$NON-NLS-1$ eTokenName = new String(currentTokenSource); } else { eTokenName = errorTokenName; } String[] arguments; if(expectedToken != null) { arguments = new String[] {eTokenName, expectedToken}; } else { arguments = new String[] {eTokenName}; } this.handle( id, arguments, arguments, startPosition, endPosition); } public void task(String tag, String message, String priority, int start, int end){ this.handle( IProblem.Task, new String[] { tag, message, priority/*secret argument that is not surfaced in getMessage()*/}, new String[] { tag, message, priority/*secret argument that is not surfaced in getMessage()*/}, start, end); } public void tooManyDimensions(ASTNode expression) { this.handle( IProblem.TooManyArrayDimensions, NoArgument, NoArgument, expression.sourceStart, expression.sourceEnd); } public void tooManyFields(TypeDeclaration typeDeclaration) { this.handle( IProblem.TooManyFields, new String[]{ new String(typeDeclaration.binding.readableName())}, new String[]{ new String(typeDeclaration.binding.shortReadableName())}, Abort | Error, typeDeclaration.sourceStart, typeDeclaration.sourceEnd); } public void tooManyMethods(TypeDeclaration typeDeclaration) { this.handle( IProblem.TooManyMethods, new String[]{ new String(typeDeclaration.binding.readableName())}, new String[]{ new String(typeDeclaration.binding.shortReadableName())}, Abort | Error, typeDeclaration.sourceStart, typeDeclaration.sourceEnd); } public void typeCastError(CastExpression expression, TypeBinding leftType, TypeBinding rightType) { String leftName = new String(leftType.readableName()); String rightName = new String(rightType.readableName()); String leftShortName = new String(leftType.shortReadableName()); String rightShortName = new String(rightType.shortReadableName()); if (leftShortName.equals(rightShortName)){ leftShortName = leftName; rightShortName = rightName; } this.handle( IProblem.IllegalCast, new String[] { rightName, leftName }, new String[] { rightShortName, leftShortName }, expression.sourceStart, expression.sourceEnd); } public void typeCollidesWithPackage(CompilationUnitDeclaration compUnitDecl, TypeDeclaration typeDecl) { this.referenceContext = typeDecl; // report the problem against the type not the entire compilation unit String[] arguments = new String[] {new String(compUnitDecl.getFileName()), new String(typeDecl.name)}; this.handle( IProblem.TypeCollidesWithPackage, arguments, arguments, typeDecl.sourceStart, typeDecl.sourceEnd, compUnitDecl.compilationResult); } public void typeMismatchError(TypeBinding actualType, TypeBinding expectedType, ASTNode location) { this.handle( IProblem.TypeMismatch, new String[] {new String(actualType.readableName()), new String(expectedType.readableName())}, new String[] {new String(actualType.shortReadableName()), new String(expectedType.shortReadableName())}, location.sourceStart, location.sourceEnd); } public void typeMismatchError(TypeBinding typeArgument, TypeVariableBinding typeParameter, ReferenceBinding genericType, ASTNode location) { if (location == null) { // binary case this.handle( IProblem.TypeArgumentMismatch, new String[] { new String(typeArgument.readableName()), new String(genericType.readableName()), new String(typeParameter.sourceName), parameterBoundAsString(typeParameter, false) }, new String[] { new String(typeArgument.shortReadableName()), new String(genericType.shortReadableName()), new String(typeParameter.sourceName), parameterBoundAsString(typeParameter, true) }, AbortCompilation | Error, 0, 1); return; } this.handle( IProblem.TypeArgumentMismatch, new String[] { new String(typeArgument.readableName()), new String(genericType.readableName()), new String(typeParameter.sourceName), parameterBoundAsString(typeParameter, false) }, new String[] { new String(typeArgument.shortReadableName()), new String(genericType.shortReadableName()), new String(typeParameter.sourceName), parameterBoundAsString(typeParameter, true) }, location.sourceStart, location.sourceEnd); } private String typesAsString(boolean isVarargs, TypeBinding[] types, boolean makeShort) { StringBuffer buffer = new StringBuffer(10); for (int i = 0, length = types.length; i < length; i++) { if (i != 0) buffer.append(", "); //$NON-NLS-1$ TypeBinding type = types[i]; boolean isVarargType = isVarargs && i == length-1; if (isVarargType) type = ((ArrayBinding)type).elementsType(); buffer.append(new String(makeShort ? type.shortReadableName() : type.readableName())); if (isVarargType) buffer.append("..."); //$NON-NLS-1$ } return buffer.toString(); } public void undefinedAnnotationValue(TypeBinding annotationType, MemberValuePair memberValuePair) { String name = new String(memberValuePair.name); this.handle( IProblem.UndefinedAnnotationMember, new String[] { name, new String(annotationType.readableName())}, new String[] { name, new String(annotationType.shortReadableName())}, memberValuePair.sourceStart, memberValuePair.sourceEnd); } public void undefinedLabel(BranchStatement statement) { String[] arguments = new String[] {new String(statement.label)}; this.handle( IProblem.UndefinedLabel, arguments, arguments, statement.sourceStart, statement.sourceEnd); } // can only occur inside binaries public void undefinedTypeVariableSignature(char[] variableName, ReferenceBinding binaryType) { this.handle( IProblem.UndefinedTypeVariable, new String[] {new String(variableName), new String(binaryType.readableName()) }, new String[] {new String(variableName), new String(binaryType.shortReadableName())}, AbortCompilation | Error, 0, 1); } public void undocumentedEmptyBlock(int blockStart, int blockEnd) { this.handle( IProblem.UndocumentedEmptyBlock, NoArgument, NoArgument, blockStart, blockEnd); } public void unexpectedStaticModifierForField(SourceTypeBinding type, FieldDeclaration fieldDecl) { String[] arguments = new String[] {new String(fieldDecl.name)}; this.handle( IProblem.UnexpectedStaticModifierForField, arguments, arguments, fieldDecl.sourceStart, fieldDecl.sourceEnd); } public void unexpectedStaticModifierForMethod(ReferenceBinding type, AbstractMethodDeclaration methodDecl) { String[] arguments = new String[] {new String(type.sourceName()), new String(methodDecl.selector)}; this.handle( IProblem.UnexpectedStaticModifierForMethod, arguments, arguments, methodDecl.sourceStart, methodDecl.sourceEnd); } public void unhandledException(TypeBinding exceptionType, ASTNode location) { boolean insideDefaultConstructor = (this.referenceContext instanceof ConstructorDeclaration) && ((ConstructorDeclaration)this.referenceContext).isDefaultConstructor(); boolean insideImplicitConstructorCall = (location instanceof ExplicitConstructorCall) && (((ExplicitConstructorCall) location).accessMode == ExplicitConstructorCall.ImplicitSuper); this.handle( insideDefaultConstructor ? IProblem.UnhandledExceptionInDefaultConstructor : (insideImplicitConstructorCall ? IProblem.UndefinedConstructorInImplicitConstructorCall : IProblem.UnhandledException), new String[] {new String(exceptionType.readableName())}, new String[] {new String(exceptionType.shortReadableName())}, location.sourceStart, location.sourceEnd); } public void uninitializedBlankFinalField(FieldBinding binding, ASTNode location) { String[] arguments = new String[] {new String(binding.readableName())}; this.handle( IProblem.UninitializedBlankFinalField, arguments, arguments, location.sourceStart, fieldLocation(binding, location)); } public void uninitializedLocalVariable(LocalVariableBinding binding, ASTNode location) { String[] arguments = new String[] {new String(binding.readableName())}; this.handle( IProblem.UninitializedLocalVariable, arguments, arguments, location.sourceStart, location.sourceEnd); } public void unmatchedBracket(int position, ReferenceContext context, CompilationResult compilationResult) { this.handle( IProblem.UnmatchedBracket, NoArgument, NoArgument, position, position, context, compilationResult); } public void unnecessaryCast(CastExpression castExpression) { TypeBinding castedExpressionType = castExpression.expression.resolvedType; this.handle( IProblem.UnnecessaryCast, new String[]{ new String(castedExpressionType.readableName()), new String(castExpression.resolvedType.readableName())}, new String[]{ new String(castedExpressionType.shortReadableName()), new String(castExpression.resolvedType.shortReadableName())}, castExpression.sourceStart, castExpression.sourceEnd); } public void unnecessaryCastForArgument(CastExpression castExpression, TypeBinding parameterType) { TypeBinding castedExpressionType = castExpression.expression.resolvedType; this.handle( IProblem.UnnecessaryArgumentCast, new String[]{ new String(castedExpressionType.readableName()), new String(castExpression.resolvedType.readableName()), new String(parameterType.readableName())}, new String[]{ new String(castedExpressionType.shortReadableName()), new String(castExpression.resolvedType.shortReadableName()), new String(parameterType.shortReadableName())}, castExpression.sourceStart, castExpression.sourceEnd); } public void unnecessaryElse(ASTNode location) { this.handle( IProblem.UnnecessaryElse, NoArgument, NoArgument, location.sourceStart, location.sourceEnd); } public void unnecessaryEnclosingInstanceSpecification(Expression expression, ReferenceBinding targetType) { this.handle( IProblem.IllegalEnclosingInstanceSpecification, new String[]{ new String(targetType.readableName())}, new String[]{ new String(targetType.shortReadableName())}, expression.sourceStart, expression.sourceEnd); } public void unnecessaryInstanceof(InstanceOfExpression instanceofExpression, TypeBinding checkType) { TypeBinding expressionType = instanceofExpression.expression.resolvedType; this.handle( IProblem.UnnecessaryInstanceof, new String[]{ new String(expressionType.readableName()), new String(checkType.readableName())}, new String[]{ new String(expressionType.shortReadableName()), new String(checkType.shortReadableName())}, instanceofExpression.sourceStart, instanceofExpression.sourceEnd); } public void unqualifiedFieldAccess(NameReference reference, FieldBinding field) { int end = reference.sourceEnd; if (reference instanceof QualifiedNameReference) { QualifiedNameReference qref = (QualifiedNameReference) reference; end = (int) qref.sourcePositions[0]; } this.handle( IProblem.UnqualifiedFieldAccess, new String[] {new String(field.declaringClass.readableName()), new String(field.name)}, new String[] {new String(field.declaringClass.shortReadableName()), new String(field.name)}, reference.sourceStart, end); } public void unreachableCatchBlock(ReferenceBinding exceptionType, ASTNode location) { this.handle( IProblem.UnreachableCatch, new String[] { new String(exceptionType.readableName()), }, new String[] { new String(exceptionType.shortReadableName()), }, location.sourceStart, location.sourceEnd); } public void unreachableCode(Statement statement) { this.handle( IProblem.CodeCannotBeReached, NoArgument, NoArgument, statement.sourceStart, statement.sourceEnd); } public void unresolvableReference(NameReference nameRef, Binding binding) { int severity = Error; /* also need to check that the searchedType is the receiver type if (binding instanceof ProblemBinding) { ProblemBinding problem = (ProblemBinding) binding; if (problem.searchType != null && problem.searchType.isHierarchyInconsistent()) severity = SecondaryError; } */ String[] arguments = new String[] {new String(binding.readableName())}; int end = nameRef.sourceEnd; if (nameRef instanceof QualifiedNameReference) { QualifiedNameReference ref = (QualifiedNameReference) nameRef; if (ref.indexOfFirstFieldBinding >= 1) end = (int) ref.sourcePositions[ref.indexOfFirstFieldBinding - 1]; } this.handle( IProblem.UndefinedName, arguments, arguments, severity, nameRef.sourceStart, end); } public void unsafeCast(CastExpression castExpression) { TypeBinding castedExpressionType = castExpression.expression.resolvedType; this.handle( IProblem.UnsafeGenericCast, new String[]{ new String(castedExpressionType.readableName()), new String(castExpression.resolvedType.readableName())}, new String[]{ new String(castedExpressionType.shortReadableName()), new String(castExpression.resolvedType.shortReadableName())}, castExpression.sourceStart, castExpression.sourceEnd); } public void unsafeRawConversion(Expression expression, TypeBinding expressionType, TypeBinding expectedType) { this.handle( IProblem.UnsafeRawConversion, new String[] { new String(expressionType.readableName()), new String(expectedType.readableName()), new String(expectedType.erasure().readableName()) }, new String[] { new String(expressionType.shortReadableName()), new String(expectedType.shortReadableName()), new String(expectedType.erasure().shortReadableName()) }, expression.sourceStart, expression.sourceEnd); } public void unsafeRawFieldAssignment(FieldBinding rawField, TypeBinding expressionType, ASTNode location) { this.handle( IProblem.UnsafeRawFieldAssignment, new String[] { new String(expressionType.readableName()), new String(rawField.name), new String(rawField.declaringClass.readableName()), new String(rawField.declaringClass.erasure().readableName()) }, new String[] { new String(expressionType.shortReadableName()), new String(rawField.name), new String(rawField.declaringClass.shortReadableName()), new String(rawField.declaringClass.erasure().shortReadableName()) }, location.sourceStart, location.sourceEnd); } public void unsafeRawInvocation(ASTNode location, MethodBinding rawMethod) { if (rawMethod.isConstructor()) { this.handle( IProblem.UnsafeRawConstructorInvocation, new String[] { new String(rawMethod.declaringClass.readableName()), typesAsString(rawMethod.original().isVarargs(), rawMethod.parameters, false), new String(rawMethod.declaringClass.erasure().readableName()), }, new String[] { new String(rawMethod.declaringClass.shortReadableName()), typesAsString(rawMethod.original().isVarargs(), rawMethod.parameters, true), new String(rawMethod.declaringClass.erasure().shortReadableName()), }, location.sourceStart, location.sourceEnd); } else { this.handle( IProblem.UnsafeRawMethodInvocation, new String[] { new String(rawMethod.selector), typesAsString(rawMethod.original().isVarargs(), rawMethod.parameters, false), new String(rawMethod.declaringClass.readableName()), new String(rawMethod.declaringClass.erasure().readableName()), }, new String[] { new String(rawMethod.selector), typesAsString(rawMethod.original().isVarargs(), rawMethod.parameters, true), new String(rawMethod.declaringClass.shortReadableName()), new String(rawMethod.declaringClass.erasure().shortReadableName()), }, location.sourceStart, location.sourceEnd); } } public void unsafeReturnTypeOverride(MethodBinding currentMethod, MethodBinding inheritedMethod, ASTNode location) { this.handle( IProblem.UnsafeReturnTypeOverride, new String[] { new String(currentMethod.returnType.readableName()), new String(currentMethod.selector), typesAsString(currentMethod.original().isVarargs(), currentMethod.original().parameters, false), new String(currentMethod.declaringClass.readableName()), new String(inheritedMethod.returnType.readableName()), //new String(inheritedMethod.returnType.erasure().readableName()), }, new String[] { new String(currentMethod.returnType.shortReadableName()), new String(currentMethod.selector), typesAsString(currentMethod.original().isVarargs(), currentMethod.original().parameters, true), new String(currentMethod.declaringClass.shortReadableName()), new String(inheritedMethod.returnType.shortReadableName()), //new String(inheritedMethod.returnType.erasure().shortReadableName()), }, location.sourceStart, location.sourceEnd); } public void unusedArgument(LocalDeclaration localDecl) { String[] arguments = new String[] {new String(localDecl.name)}; this.handle( IProblem.ArgumentIsNeverUsed, arguments, arguments, localDecl.sourceStart, localDecl.sourceEnd); } public void unusedDeclaredThrownException(ReferenceBinding exceptionType, AbstractMethodDeclaration method, ASTNode location) { if (method.isConstructor()) { this.handle( IProblem.UnusedConstructorDeclaredThrownException, new String[] { new String(method.binding.declaringClass.readableName()), typesAsString(method.binding.isVarargs(), method.binding.parameters, false), new String(exceptionType.readableName()), }, new String[] { new String(method.binding.declaringClass.shortReadableName()), typesAsString(method.binding.isVarargs(), method.binding.parameters, true), new String(exceptionType.shortReadableName()), }, location.sourceStart, location.sourceEnd); } else { this.handle( IProblem.UnusedMethodDeclaredThrownException, new String[] { new String(method.binding.declaringClass.readableName()), new String(method.selector), typesAsString(method.binding.isVarargs(), method.binding.parameters, false), new String(exceptionType.readableName()), }, new String[] { new String(method.binding.declaringClass.shortReadableName()), new String(method.selector), typesAsString(method.binding.isVarargs(), method.binding.parameters, true), new String(exceptionType.shortReadableName()), }, location.sourceStart, location.sourceEnd); } } public void unusedImport(ImportReference importRef) { String[] arguments = new String[] { CharOperation.toString(importRef.tokens) }; this.handle( IProblem.UnusedImport, arguments, arguments, importRef.sourceStart, importRef.sourceEnd); } public void unusedLocalVariable(LocalDeclaration localDecl) { String[] arguments = new String[] {new String(localDecl.name)}; this.handle( IProblem.LocalVariableIsNeverUsed, arguments, arguments, localDecl.sourceStart, localDecl.sourceEnd); } public void unusedPrivateConstructor(ConstructorDeclaration constructorDecl) { if (computeSeverity(IProblem.UnusedPrivateConstructor) == Ignore) return; // no complaint for no-arg constructors (or default ones) - known pattern to block instantiation if (constructorDecl.arguments == null || constructorDecl.arguments.length == 0) return; MethodBinding constructor = constructorDecl.binding; this.handle( IProblem.UnusedPrivateConstructor, new String[] { new String(constructor.declaringClass.readableName()), typesAsString(constructor.isVarargs(), constructor.parameters, false) }, new String[] { new String(constructor.declaringClass.shortReadableName()), typesAsString(constructor.isVarargs(), constructor.parameters, true) }, constructorDecl.sourceStart, constructorDecl.sourceEnd); } public void unusedPrivateField(FieldDeclaration fieldDecl) { if (computeSeverity(IProblem.UnusedPrivateField) == Ignore) return; FieldBinding field = fieldDecl.binding; if (CharOperation.equals(TypeConstants.SERIALVERSIONUID, field.name) && field.isStatic() && field.isFinal() && BaseTypes.LongBinding == field.type) { return; // do not report unused serialVersionUID field } if (CharOperation.equals(TypeConstants.SERIALPERSISTENTFIELDS, field.name) && field.isStatic() && field.isFinal() && field.type.dimensions() == 1 && CharOperation.equals(TypeConstants.CharArray_JAVA_IO_OBJECTSTREAMFIELD, field.type.leafComponentType().readableName())) { return; // do not report unused serialPersistentFields field } this.handle( IProblem.UnusedPrivateField, new String[] { new String(field.declaringClass.readableName()), new String(field.name), }, new String[] { new String(field.declaringClass.shortReadableName()), new String(field.name), }, fieldDecl.sourceStart, fieldDecl.sourceEnd); } public void unusedPrivateMethod(AbstractMethodDeclaration methodDecl) { if (computeSeverity(IProblem.UnusedPrivateMethod) == Ignore) return; MethodBinding method = methodDecl.binding; // no report for serialization support 'void readObject(ObjectInputStream)' if (!method.isStatic() && BaseTypes.VoidBinding == method.returnType && method.parameters.length == 1 && method.parameters[0].dimensions() == 0 && CharOperation.equals(method.selector, TypeConstants.READOBJECT) && CharOperation.equals(TypeConstants.CharArray_JAVA_IO_OBJECTINPUTSTREAM, method.parameters[0].readableName())) { return; } // no report for serialization support 'void writeObject(ObjectOutputStream)' if (!method.isStatic() && BaseTypes.VoidBinding == method.returnType && method.parameters.length == 1 && method.parameters[0].dimensions() == 0 && CharOperation.equals(method.selector, TypeConstants.WRITEOBJECT) && CharOperation.equals(TypeConstants.CharArray_JAVA_IO_OBJECTOUTPUTSTREAM, method.parameters[0].readableName())) { return; } // no report for serialization support 'Object readResolve()' if (!method.isStatic() && TypeIds.T_JavaLangObject == method.returnType.id && method.parameters.length == 0 && CharOperation.equals(method.selector, TypeConstants.READRESOLVE)) { return; } // no report for serialization support 'Object writeReplace()' if (!method.isStatic() && TypeIds.T_JavaLangObject == method.returnType.id && method.parameters.length == 0 && CharOperation.equals(method.selector, TypeConstants.WRITEREPLACE)) { return; } this.handle( IProblem.UnusedPrivateMethod, new String[] { new String(method.declaringClass.readableName()), new String(method.selector), typesAsString(method.isVarargs(), method.parameters, false) }, new String[] { new String(method.declaringClass.shortReadableName()), new String(method.selector), typesAsString(method.isVarargs(), method.parameters, true) }, methodDecl.sourceStart, methodDecl.sourceEnd); } public void unusedPrivateType(TypeDeclaration typeDecl) { if (computeSeverity(IProblem.UnusedPrivateType) == Ignore) return; ReferenceBinding type = typeDecl.binding; this.handle( IProblem.UnusedPrivateType, new String[] { new String(type.readableName()), }, new String[] { new String(type.shortReadableName()), }, typeDecl.sourceStart, typeDecl.sourceEnd); } public void useAssertAsAnIdentifier(int sourceStart, int sourceEnd) { this.handle( IProblem.UseAssertAsAnIdentifier, NoArgument, NoArgument, sourceStart, sourceEnd); } public void useEnumAsAnIdentifier(int sourceStart, int sourceEnd) { this.handle( IProblem.UseEnumAsAnIdentifier, NoArgument, NoArgument, sourceStart, sourceEnd); } public void varargsArgumentNeedCast(MethodBinding method, TypeBinding argumentType, InvocationSite location) { TypeBinding lastParam = method.parameters[method.parameters.length-1]; if (method.isConstructor()) { this.handle( IProblem.ConstructorVarargsArgumentNeedCast, new String[] {new String(argumentType.readableName()), new String(lastParam.readableName()), new String(method.declaringClass.readableName()), typesAsString(method.isVarargs(), method.parameters, false), }, new String[] {new String(argumentType.shortReadableName()), new String(lastParam.shortReadableName()), new String(method.declaringClass.shortReadableName()), typesAsString(method.isVarargs(), method.parameters, true), }, location.sourceStart(), location.sourceEnd()); } else { this.handle( IProblem.MethodVarargsArgumentNeedCast, new String[] { new String(argumentType.readableName()), new String(lastParam.readableName()), new String(method.selector), typesAsString(method.isVarargs(), method.parameters, false), new String(method.declaringClass.readableName()), }, new String[] { new String(argumentType.shortReadableName()), new String(lastParam.shortReadableName()), new String(method.selector), typesAsString(method.isVarargs(), method.parameters, true), new String(method.declaringClass.shortReadableName()), }, location.sourceStart(), location.sourceEnd()); } } public void variableTypeCannotBeVoid(AbstractVariableDeclaration varDecl) { String[] arguments = new String[] {new String(varDecl.name)}; this.handle( IProblem.VariableTypeCannotBeVoid, arguments, arguments, varDecl.sourceStart, varDecl.sourceEnd); } public void variableTypeCannotBeVoidArray(AbstractVariableDeclaration varDecl) { String[] arguments = new String[] {new String(varDecl.name)}; this.handle( IProblem.VariableTypeCannotBeVoidArray, arguments, arguments, varDecl.sourceStart, varDecl.sourceEnd); } public void visibilityConflict(MethodBinding currentMethod, MethodBinding inheritedMethod) { this.handle( // Cannot reduce the visibility of the inherited method from %1 // 8.4.6.3 - The access modifier of an hiding method must provide at least as much access as the hidden method. // 8.4.6.3 - The access modifier of an overiding method must provide at least as much access as the overriden method. IProblem.MethodReducesVisibility, new String[] {new String(inheritedMethod.declaringClass.readableName())}, new String[] {new String(inheritedMethod.declaringClass.shortReadableName())}, currentMethod.sourceStart(), currentMethod.sourceEnd()); } public void wildcardAssignment(TypeBinding variableType, TypeBinding expressionType, ASTNode location) { this.handle( IProblem.WildcardFieldAssignment, new String[] { new String(expressionType.readableName()), new String(variableType.readableName()) }, new String[] { new String(expressionType.shortReadableName()), new String(variableType.shortReadableName()) }, location.sourceStart, location.sourceEnd); } public void wildcardInvocation(ASTNode location, TypeBinding receiverType, MethodBinding method, TypeBinding[] arguments) { TypeBinding offendingArgument = null; TypeBinding offendingParameter = null; for (int i = 0, length = method.parameters.length; i < length; i++) { TypeBinding parameter = method.parameters[i]; if (parameter.isWildcard() && (((WildcardBinding) parameter).kind != Wildcard.SUPER)) { offendingParameter = parameter; offendingArgument = arguments[i]; break; } } if (method.isConstructor()) { this.handle( IProblem.WildcardConstructorInvocation, new String[] { new String(receiverType.sourceName()), typesAsString(method.isVarargs(), method.parameters, false), new String(receiverType.readableName()), typesAsString(false, arguments, false), new String(offendingArgument.readableName()), new String(offendingParameter.readableName()), }, new String[] { new String(receiverType.sourceName()), typesAsString(method.isVarargs(), method.parameters, true), new String(receiverType.shortReadableName()), typesAsString(false, arguments, true), new String(offendingArgument.shortReadableName()), new String(offendingParameter.shortReadableName()), }, location.sourceStart, location.sourceEnd); } else { this.handle( IProblem.WildcardMethodInvocation, new String[] { new String(method.selector), typesAsString(method.isVarargs(), method.parameters, false), new String(receiverType.readableName()), typesAsString(false, arguments, false), new String(offendingArgument.readableName()), new String(offendingParameter.readableName()), }, new String[] { new String(method.selector), typesAsString(method.isVarargs(), method.parameters, true), new String(receiverType.shortReadableName()), typesAsString(false, arguments, true), new String(offendingArgument.shortReadableName()), new String(offendingParameter.shortReadableName()), }, location.sourceStart, location.sourceEnd); } } public void wrongSequenceOfExceptionTypesError(TryStatement statement, TypeBinding exceptionType, int under, TypeBinding hidingExceptionType) { //the two catch block under and upper are in an incorrect order. //under should be define BEFORE upper in the source TypeReference typeRef = statement.catchArguments[under].type; this.handle( IProblem.InvalidCatchBlockSequence, new String[] { new String(exceptionType.readableName()), new String(hidingExceptionType.readableName()), }, new String[] { new String(exceptionType.shortReadableName()), new String(hidingExceptionType.shortReadableName()), }, typeRef.sourceStart, typeRef.sourceEnd); } }