bundles/org.eclipse.wst.jsdt.core/src/org/eclipse/wst/jsdt/internal/compiler/lookup/FieldBinding.java - jsdt/webtools.jsdt.core - Git at Google

 /*******************************************************************************
  * Copyright (c) 2000, 2008 IBM Corporation and others.
  * All rights reserved. This program and the accompanying materials
  * are made available under the terms of the Eclipse Public License v1.0
  * which accompanies this distribution, and is available at
  * http://www.eclipse.org/legal/epl-v10.html
  *
  * Contributors:
  *     IBM Corporation - initial API and implementation
  *******************************************************************************/
 package org.eclipse.wst.jsdt.internal.compiler.lookup;

 import org.eclipse.wst.jsdt.core.JavaScriptCore;
 import org.eclipse.wst.jsdt.core.compiler.CharOperation;
 import org.eclipse.wst.jsdt.core.infer.InferredAttribute;
 import org.eclipse.wst.jsdt.internal.compiler.ast.AbstractVariableDeclaration;
 import org.eclipse.wst.jsdt.internal.compiler.ast.FieldDeclaration;
 import org.eclipse.wst.jsdt.internal.compiler.ast.TypeDeclaration;
 import org.eclipse.wst.jsdt.internal.compiler.classfmt.ClassFileConstants;
 import org.eclipse.wst.jsdt.internal.compiler.impl.Constant;

 public class FieldBinding extends VariableBinding {
 	public ReferenceBinding declaringClass;
 protected FieldBinding() {
 	super(null, null, 0, null);
 	// for creating problem field
 }
 public FieldBinding(char[] name, TypeBinding type, int modifiers, ReferenceBinding declaringClass, Constant constant) {
 	super(name, type, modifiers, constant);
 	this.declaringClass = declaringClass;
 }
 public FieldBinding(InferredAttribute field, TypeBinding type, int modifiers, ReferenceBinding declaringClass) {
 	this(field.name, type, modifiers, declaringClass, null);
 	field.binding = this; // record binding in declaration
 }
 // special API used to change field declaring class for runtime visibility check
 public FieldBinding(FieldBinding initialFieldBinding, ReferenceBinding declaringClass) {
 	super(initialFieldBinding.name, initialFieldBinding.type, initialFieldBinding.modifiers, initialFieldBinding.constant());
 	this.declaringClass = declaringClass;
 	this.id = initialFieldBinding.id;
 }
 /* API
 * Answer the receiver's binding type from Binding.BindingID.
 */

 public final int kind() {
 	return FIELD;
 }
 /* Answer true if the receiver is visible to the invocationPackage.
 */

 public final boolean canBeSeenBy(PackageBinding invocationPackage) {
 	if (isPublic()) return true;
 	if (isPrivate()) return false;

 	// isProtected() or isDefault()
 	return invocationPackage == declaringClass.getPackage();
 }
 /* Answer true if the receiver is visible to the type provided by the scope.
 * InvocationSite implements isSuperAccess() to provide additional information
 * if the receiver is protected.
 *
 * NOTE: Cannot invoke this method with a compilation unit scope.
 */

 public final boolean canBeSeenBy(TypeBinding receiverType, InvocationSite invocationSite, Scope scope) {
 	if (isPublic() || !JavaScriptCore.IS_ECMASCRIPT4) return true;

 	SourceTypeBinding invocationType = scope.enclosingSourceType();
 	if (invocationType == declaringClass && invocationType == receiverType) return true;

 	if( (receiverType instanceof SourceTypeBinding) && ((SourceTypeBinding)receiverType).nextType!=null) {
 		SourceTypeBinding combinedBinding = (SourceTypeBinding) receiverType;
 		if (combinedBinding.contains(declaringClass)  && combinedBinding.contains(invocationType)) return true;

 	}

 	if (invocationType == null) // static import call
 		return !isPrivate() && scope.getCurrentPackage() == declaringClass.fPackage;

 	if (isProtected()) {
 		// answer true if the invocationType is the declaringClass or they are in the same package
 		// OR the invocationType is a subclass of the declaringClass
 		//    AND the receiverType is the invocationType or its subclass
 		//    OR the method is a static method accessed directly through a type
 		//    OR previous assertions are true for one of the enclosing type
 		if (invocationType == declaringClass) return true;
 		if (invocationType.fPackage == declaringClass.fPackage) return true;

 		ReferenceBinding currentType = invocationType;
 		int depth = 0;
 		ReferenceBinding receiverErasure = (ReferenceBinding)receiverType.erasure();
 		ReferenceBinding declaringErasure = (ReferenceBinding) declaringClass.erasure();
 		do {
 			if (currentType.findSuperTypeWithSameErasure(declaringErasure) != null) {
 				if (invocationSite.isSuperAccess())
 					return true;
 				// receiverType can be an array binding in one case... see if you can change it
 				if (receiverType instanceof ArrayBinding)
 					return false;
 				if (isStatic()) {
 					if (depth > 0) invocationSite.setDepth(depth);
 					return true; // see 1FMEPDL - return invocationSite.isTypeAccess();
 				}
 				if (currentType == receiverErasure || receiverErasure.findSuperTypeWithSameErasure(currentType) != null) {
 					if (depth > 0) invocationSite.setDepth(depth);
 					return true;
 				}
 			}
 			depth++;
 			currentType = currentType.enclosingType();
 		} while (currentType != null);
 		return false;
 	}

 	if (isPrivate()) {
 		// answer true if the receiverType is the declaringClass
 		// AND the invocationType and the declaringClass have a common enclosingType
 		receiverCheck: {
 			if (receiverType != declaringClass) {
 				// special tolerance for type variable direct bounds
 				if (receiverType.isTypeVariable() && ((TypeVariableBinding) receiverType).isErasureBoundTo(declaringClass.erasure()))
 					break receiverCheck;
 				return false;
 			}
 		}

 		if (invocationType != declaringClass) {
 			ReferenceBinding outerInvocationType = invocationType;
 			ReferenceBinding temp = outerInvocationType.enclosingType();
 			while (temp != null) {
 				outerInvocationType = temp;
 				temp = temp.enclosingType();
 			}

 			ReferenceBinding outerDeclaringClass = (ReferenceBinding) declaringClass.erasure();
 			temp = outerDeclaringClass.enclosingType();
 			while (temp != null) {
 				outerDeclaringClass = temp;
 				temp = temp.enclosingType();
 			}
 			if (outerInvocationType != outerDeclaringClass) return false;
 		}
 		return true;
 	}

 	// isDefault()
 	PackageBinding declaringPackage = declaringClass.fPackage;
 	if (invocationType.fPackage != declaringPackage) return false;

 	// receiverType can be an array binding in one case... see if you can change it
 	if (receiverType instanceof ArrayBinding)
 		return false;
 	ReferenceBinding currentType = (ReferenceBinding) receiverType;
 	do {
 		if (declaringClass == currentType) return true;
 		PackageBinding currentPackage = currentType.fPackage;
 		// package could be null for wildcards/intersection types, ignore and recurse in superclass
 		if (currentPackage != null && currentPackage != declaringPackage) return false;
 	} while ((currentType = currentType.superclass()) != null);
 	return false;
 }
 /*
  * declaringUniqueKey dot fieldName ) returnTypeUniqueKey
  * p.X { X<T> x} --> Lp/X;.x)p/X<TT;>;
  */
 public char[] computeUniqueKey(boolean isLeaf) {
 	// declaring key
 	char[] declaringKey =
 		this.declaringClass == null /*case of length field for an array*/
 			? CharOperation.NO_CHAR
 			: this.declaringClass.computeUniqueKey(false/*not a leaf*/);
 	int declaringLength = declaringKey.length;

 	// name
 	int nameLength = this.name.length;

 	// return type
 	char[] returnTypeKey = this.type == null ? new char[] {'V'} : this.type.computeUniqueKey(false/*not a leaf*/);
 	int returnTypeLength = returnTypeKey.length;

 	char[] uniqueKey = new char[declaringLength + 1 + nameLength + 1 + returnTypeLength];
 	int index = 0;
 	System.arraycopy(declaringKey, 0, uniqueKey, index, declaringLength);
 	index += declaringLength;
 	uniqueKey[index++] = '.';
 	System.arraycopy(this.name, 0, uniqueKey, index, nameLength);
 	index += nameLength;
 	uniqueKey[index++] = ')';
 	System.arraycopy(returnTypeKey, 0, uniqueKey, index, returnTypeLength);
 	return uniqueKey;
 }

 public Constant constant() {
 	Constant fieldConstant = this.constant;
 	if (fieldConstant == null) {
 		if (this.isFinal()) {
 			//The field has not been yet type checked.
 			//It also means that the field is not coming from a class that
 			//has already been compiled. It can only be from a class within
 			//compilation units to process. Thus the field is NOT from a BinaryTypeBinbing
 			FieldBinding originalField = this.original();
 			if (originalField.declaringClass instanceof SourceTypeBinding) {
 				SourceTypeBinding sourceType = (SourceTypeBinding) originalField.declaringClass;
 				if (sourceType.scope != null) {
 					TypeDeclaration typeDecl = sourceType.classScope.referenceContext;
 					FieldDeclaration fieldDecl = typeDecl.declarationOf(originalField);
 					fieldDecl.resolve(originalField.isStatic() //side effect on binding
 							? typeDecl.staticInitializerScope
 							: typeDecl.initializerScope);
 					fieldConstant = originalField.constant();
 				} else {
 					fieldConstant = Constant.NotAConstant; // shouldn't occur per construction (paranoid null check)
 				}
 			} else {
 				fieldConstant = Constant.NotAConstant; // shouldn't occur per construction (paranoid null check)
 			}
 		} else {
 			fieldConstant = Constant.NotAConstant;
 		}
 		this.constant = fieldConstant;
 	}
 	return fieldConstant;
 }
 /**
  * X<T> t   -->  LX<TT;>;
  */
 public char[] genericSignature() {
     if ((this.modifiers & ExtraCompilerModifiers.AccGenericSignature) == 0) return null;
     return this.type.genericTypeSignature();
 }

 public final int getAccessFlags() {
 	return modifiers & ExtraCompilerModifiers.AccJustFlag;
 }

 /**
  * Compute the tagbits for standard annotations. For source types, these could require
  * lazily resolving corresponding annotation nodes, in case of forward references.
  * @see org.eclipse.wst.jsdt.internal.compiler.lookup.Binding#getAnnotationTagBits()
  */
 public long getAnnotationTagBits() {
 	FieldBinding originalField = this.original();
 	if ((originalField.tagBits & TagBits.AnnotationResolved) == 0 && originalField.declaringClass instanceof SourceTypeBinding) {
 		ClassScope scope = ((SourceTypeBinding) originalField.declaringClass).classScope;
 		if (scope == null) { // synthetic fields do not have a scope nor any annotations
 			this.tagBits |= (TagBits.AnnotationResolved | TagBits.DeprecatedAnnotationResolved);
 			return 0;
 		}
 //		TypeDeclaration typeDecl = scope.referenceContext;
 //		FieldDeclaration fieldDecl = typeDecl.declarationOf(originalField);
 //		if (fieldDecl != null) {
 //			MethodScope initializationScope = isStatic() ? typeDecl.staticInitializerScope : typeDecl.initializerScope;
 //			FieldBinding previousField = initializationScope.initializedField;
 //			int previousFieldID = initializationScope.lastVisibleFieldID;
 //			try {
 //				initializationScope.initializedField = originalField;
 //				initializationScope.lastVisibleFieldID = originalField.id;
 //				ASTNode.resolveAnnotations(initializationScope, fieldDecl.annotations, originalField);
 //			} finally {
 //				initializationScope.initializedField = previousField;
 //				initializationScope.lastVisibleFieldID = previousFieldID;
 //			}
 //		}
 	}
 	return originalField.tagBits;
 }


 /* Answer true if the receiver has default visibility
 */

 public final boolean isDefault() {
 	return !isPublic() && !isProtected() && !isPrivate();
 }
 /* Answer true if the receiver is a deprecated field
 */

 public final boolean isDeprecated() {
 	return (modifiers & ClassFileConstants.AccDeprecated) != 0;
 }
 /* Answer true if the receiver has private visibility
 */

 public final boolean isPrivate() {
 	return (modifiers & ClassFileConstants.AccPrivate) != 0;
 }
 /* Answer true if the receiver has private visibility and is used locally
 */

 public final boolean isUsed() {
 	return (modifiers & ExtraCompilerModifiers.AccLocallyUsed) != 0;
 }
 /* Answer true if the receiver has protected visibility
 */

 public final boolean isProtected() {
 	return (modifiers & ClassFileConstants.AccProtected) != 0;
 }
 /* Answer true if the receiver has public visibility
 */

 public final boolean isPublic() {
 	return (modifiers & ClassFileConstants.AccPublic) != 0;
 }
 /* Answer true if the receiver is a static field
 */

 public final boolean isStatic() {
 	return (modifiers & ClassFileConstants.AccStatic) != 0;
 }
 /* Answer true if the receiver is not defined in the source of the declaringClass
 */

 public final boolean isSynthetic() {
 	return (modifiers & ClassFileConstants.AccSynthetic) != 0;
 }
 /* Answer true if the receiver is a transient field
 */

 public final boolean isTransient() {
 	return (modifiers & ClassFileConstants.AccTransient) != 0;
 }
 /* Answer true if the receiver's declaring type is deprecated (or any of its enclosing types)
 */

 public final boolean isViewedAsDeprecated() {
 	return (modifiers & (ClassFileConstants.AccDeprecated | ExtraCompilerModifiers.AccDeprecatedImplicitly)) != 0;
 }
 /* Answer true if the receiver is a volatile field
 */

 public final boolean isVolatile() {
 	return (modifiers & ClassFileConstants.AccVolatile) != 0;
 }
 /**
  * Returns the original field (as opposed to parameterized instances)
  */
 public FieldBinding original() {
 	return this;
 }
 public void setAnnotations(AnnotationBinding[] annotations) {
 	this.declaringClass.storeAnnotations(this, annotations);
 }
 public  boolean isFor(AbstractVariableDeclaration variableDeclaration)
 {
 	return false;
 }
 //public FieldDeclaration sourceField() {
 //	SourceTypeBinding sourceType;
 //	try {
 //		sourceType = (SourceTypeBinding) declaringClass;
 //	} catch (ClassCastException e) {
 //		return null;
 //	}
 //
 //	FieldDeclaration[] fields = sourceType.scope.referenceContext.fields;
 //	if (fields != null) {
 //		for (int i = fields.length; --i >= 0;)
 //			if (this == fields[i].binding)
 //				return fields[i];
 //	}
 //	return null;
 //}
 }
	/*******************************************************************************
	* Copyright (c) 2000, 2008 IBM Corporation and others.
	* All rights reserved. This program and the accompanying materials
	* are made available under the terms of the Eclipse Public License v1.0
	* which accompanies this distribution, and is available at
	* http://www.eclipse.org/legal/epl-v10.html
	*
	* Contributors:
	* IBM Corporation - initial API and implementation
	*******************************************************************************/
	package org.eclipse.wst.jsdt.internal.compiler.lookup;

	import org.eclipse.wst.jsdt.core.JavaScriptCore;
	import org.eclipse.wst.jsdt.core.compiler.CharOperation;
	import org.eclipse.wst.jsdt.core.infer.InferredAttribute;
	import org.eclipse.wst.jsdt.internal.compiler.ast.AbstractVariableDeclaration;
	import org.eclipse.wst.jsdt.internal.compiler.ast.FieldDeclaration;
	import org.eclipse.wst.jsdt.internal.compiler.ast.TypeDeclaration;
	import org.eclipse.wst.jsdt.internal.compiler.classfmt.ClassFileConstants;
	import org.eclipse.wst.jsdt.internal.compiler.impl.Constant;

	public class FieldBinding extends VariableBinding {
	public ReferenceBinding declaringClass;
	protected FieldBinding() {
	super(null, null, 0, null);
	// for creating problem field
	}
	public FieldBinding(char[] name, TypeBinding type, int modifiers, ReferenceBinding declaringClass, Constant constant) {
	super(name, type, modifiers, constant);
	this.declaringClass = declaringClass;
	}
	public FieldBinding(InferredAttribute field, TypeBinding type, int modifiers, ReferenceBinding declaringClass) {
	this(field.name, type, modifiers, declaringClass, null);
	field.binding = this; // record binding in declaration
	}
	// special API used to change field declaring class for runtime visibility check
	public FieldBinding(FieldBinding initialFieldBinding, ReferenceBinding declaringClass) {
	super(initialFieldBinding.name, initialFieldBinding.type, initialFieldBinding.modifiers, initialFieldBinding.constant());
	this.declaringClass = declaringClass;
	this.id = initialFieldBinding.id;
	}
	/* API
	* Answer the receiver's binding type from Binding.BindingID.
	*/

	public final int kind() {
	return FIELD;
	}
	/* Answer true if the receiver is visible to the invocationPackage.
	*/

	public final boolean canBeSeenBy(PackageBinding invocationPackage) {
	if (isPublic()) return true;
	if (isPrivate()) return false;

	// isProtected() or isDefault()
	return invocationPackage == declaringClass.getPackage();
	}
	/* Answer true if the receiver is visible to the type provided by the scope.
	* InvocationSite implements isSuperAccess() to provide additional information
	* if the receiver is protected.
	*
	* NOTE: Cannot invoke this method with a compilation unit scope.
	*/

	public final boolean canBeSeenBy(TypeBinding receiverType, InvocationSite invocationSite, Scope scope) {
	if (isPublic() \|\| !JavaScriptCore.IS_ECMASCRIPT4) return true;

	SourceTypeBinding invocationType = scope.enclosingSourceType();
	if (invocationType == declaringClass && invocationType == receiverType) return true;

	if( (receiverType instanceof SourceTypeBinding) && ((SourceTypeBinding)receiverType).nextType!=null) {
	SourceTypeBinding combinedBinding = (SourceTypeBinding) receiverType;
	if (combinedBinding.contains(declaringClass) && combinedBinding.contains(invocationType)) return true;

	}

	if (invocationType == null) // static import call
	return !isPrivate() && scope.getCurrentPackage() == declaringClass.fPackage;

	if (isProtected()) {
	// answer true if the invocationType is the declaringClass or they are in the same package
	// OR the invocationType is a subclass of the declaringClass
	// AND the receiverType is the invocationType or its subclass
	// OR the method is a static method accessed directly through a type
	// OR previous assertions are true for one of the enclosing type
	if (invocationType == declaringClass) return true;
	if (invocationType.fPackage == declaringClass.fPackage) return true;

	ReferenceBinding currentType = invocationType;
	int depth = 0;
	ReferenceBinding receiverErasure = (ReferenceBinding)receiverType.erasure();
	ReferenceBinding declaringErasure = (ReferenceBinding) declaringClass.erasure();
	do {
	if (currentType.findSuperTypeWithSameErasure(declaringErasure) != null) {
	if (invocationSite.isSuperAccess())
	return true;
	// receiverType can be an array binding in one case... see if you can change it
	if (receiverType instanceof ArrayBinding)
	return false;
	if (isStatic()) {
	if (depth > 0) invocationSite.setDepth(depth);
	return true; // see 1FMEPDL - return invocationSite.isTypeAccess();
	}
	if (currentType == receiverErasure \|\| receiverErasure.findSuperTypeWithSameErasure(currentType) != null) {
	if (depth > 0) invocationSite.setDepth(depth);
	return true;
	}
	}
	depth++;
	currentType = currentType.enclosingType();
	} while (currentType != null);
	return false;
	}

	if (isPrivate()) {
	// answer true if the receiverType is the declaringClass
	// AND the invocationType and the declaringClass have a common enclosingType
	receiverCheck: {
	if (receiverType != declaringClass) {
	// special tolerance for type variable direct bounds
	if (receiverType.isTypeVariable() && ((TypeVariableBinding) receiverType).isErasureBoundTo(declaringClass.erasure()))
	break receiverCheck;
	return false;
	}
	}

	if (invocationType != declaringClass) {
	ReferenceBinding outerInvocationType = invocationType;
	ReferenceBinding temp = outerInvocationType.enclosingType();
	while (temp != null) {
	outerInvocationType = temp;
	temp = temp.enclosingType();
	}

	ReferenceBinding outerDeclaringClass = (ReferenceBinding) declaringClass.erasure();
	temp = outerDeclaringClass.enclosingType();
	while (temp != null) {
	outerDeclaringClass = temp;
	temp = temp.enclosingType();
	}
	if (outerInvocationType != outerDeclaringClass) return false;
	}
	return true;
	}

	// isDefault()
	PackageBinding declaringPackage = declaringClass.fPackage;
	if (invocationType.fPackage != declaringPackage) return false;

	// receiverType can be an array binding in one case... see if you can change it
	if (receiverType instanceof ArrayBinding)
	return false;
	ReferenceBinding currentType = (ReferenceBinding) receiverType;
	do {
	if (declaringClass == currentType) return true;
	PackageBinding currentPackage = currentType.fPackage;
	// package could be null for wildcards/intersection types, ignore and recurse in superclass
	if (currentPackage != null && currentPackage != declaringPackage) return false;
	} while ((currentType = currentType.superclass()) != null);
	return false;
	}
	/*
	* declaringUniqueKey dot fieldName ) returnTypeUniqueKey
	* p.X { X<T> x} --> Lp/X;.x)p/X<TT;>;
	*/
	public char[] computeUniqueKey(boolean isLeaf) {
	// declaring key
	char[] declaringKey =
	this.declaringClass == null /case of length field for an array/
	? CharOperation.NO_CHAR
	: this.declaringClass.computeUniqueKey(false/not a leaf/);
	int declaringLength = declaringKey.length;

	// name
	int nameLength = this.name.length;

	// return type
	char[] returnTypeKey = this.type == null ? new char[] {'V'} : this.type.computeUniqueKey(false/not a leaf/);
	int returnTypeLength = returnTypeKey.length;

	char[] uniqueKey = new char[declaringLength + 1 + nameLength + 1 + returnTypeLength];
	int index = 0;
	System.arraycopy(declaringKey, 0, uniqueKey, index, declaringLength);
	index += declaringLength;
	uniqueKey[index++] = '.';
	System.arraycopy(this.name, 0, uniqueKey, index, nameLength);
	index += nameLength;
	uniqueKey[index++] = ')';
	System.arraycopy(returnTypeKey, 0, uniqueKey, index, returnTypeLength);
	return uniqueKey;
	}

	public Constant constant() {
	Constant fieldConstant = this.constant;
	if (fieldConstant == null) {
	if (this.isFinal()) {
	//The field has not been yet type checked.
	//It also means that the field is not coming from a class that
	//has already been compiled. It can only be from a class within
	//compilation units to process. Thus the field is NOT from a BinaryTypeBinbing
	FieldBinding originalField = this.original();
	if (originalField.declaringClass instanceof SourceTypeBinding) {
	SourceTypeBinding sourceType = (SourceTypeBinding) originalField.declaringClass;
	if (sourceType.scope != null) {
	TypeDeclaration typeDecl = sourceType.classScope.referenceContext;
	FieldDeclaration fieldDecl = typeDecl.declarationOf(originalField);
	fieldDecl.resolve(originalField.isStatic() //side effect on binding
	? typeDecl.staticInitializerScope
	: typeDecl.initializerScope);
	fieldConstant = originalField.constant();
	} else {
	fieldConstant = Constant.NotAConstant; // shouldn't occur per construction (paranoid null check)
	}
	} else {
	fieldConstant = Constant.NotAConstant; // shouldn't occur per construction (paranoid null check)
	}
	} else {
	fieldConstant = Constant.NotAConstant;
	}
	this.constant = fieldConstant;
	}
	return fieldConstant;
	}
	/**
	* X<T> t --> LX<TT;>;
	*/
	public char[] genericSignature() {
	if ((this.modifiers & ExtraCompilerModifiers.AccGenericSignature) == 0) return null;
	return this.type.genericTypeSignature();
	}

	public final int getAccessFlags() {
	return modifiers & ExtraCompilerModifiers.AccJustFlag;
	}

	/**
	* Compute the tagbits for standard annotations. For source types, these could require
	* lazily resolving corresponding annotation nodes, in case of forward references.
	* @see org.eclipse.wst.jsdt.internal.compiler.lookup.Binding#getAnnotationTagBits()
	*/
	public long getAnnotationTagBits() {
	FieldBinding originalField = this.original();
	if ((originalField.tagBits & TagBits.AnnotationResolved) == 0 && originalField.declaringClass instanceof SourceTypeBinding) {
	ClassScope scope = ((SourceTypeBinding) originalField.declaringClass).classScope;
	if (scope == null) { // synthetic fields do not have a scope nor any annotations
	this.tagBits \|= (TagBits.AnnotationResolved \| TagBits.DeprecatedAnnotationResolved);
	return 0;
	}
	// TypeDeclaration typeDecl = scope.referenceContext;
	// FieldDeclaration fieldDecl = typeDecl.declarationOf(originalField);
	// if (fieldDecl != null) {
	// MethodScope initializationScope = isStatic() ? typeDecl.staticInitializerScope : typeDecl.initializerScope;
	// FieldBinding previousField = initializationScope.initializedField;
	// int previousFieldID = initializationScope.lastVisibleFieldID;
	// try {
	// initializationScope.initializedField = originalField;
	// initializationScope.lastVisibleFieldID = originalField.id;
	// ASTNode.resolveAnnotations(initializationScope, fieldDecl.annotations, originalField);
	// } finally {
	// initializationScope.initializedField = previousField;
	// initializationScope.lastVisibleFieldID = previousFieldID;
	// }
	// }
	}
	return originalField.tagBits;
	}


	/* Answer true if the receiver has default visibility
	*/

	public final boolean isDefault() {
	return !isPublic() && !isProtected() && !isPrivate();
	}
	/* Answer true if the receiver is a deprecated field
	*/

	public final boolean isDeprecated() {
	return (modifiers & ClassFileConstants.AccDeprecated) != 0;
	}
	/* Answer true if the receiver has private visibility
	*/

	public final boolean isPrivate() {
	return (modifiers & ClassFileConstants.AccPrivate) != 0;
	}
	/* Answer true if the receiver has private visibility and is used locally
	*/

	public final boolean isUsed() {
	return (modifiers & ExtraCompilerModifiers.AccLocallyUsed) != 0;
	}
	/* Answer true if the receiver has protected visibility
	*/

	public final boolean isProtected() {
	return (modifiers & ClassFileConstants.AccProtected) != 0;
	}
	/* Answer true if the receiver has public visibility
	*/

	public final boolean isPublic() {
	return (modifiers & ClassFileConstants.AccPublic) != 0;
	}
	/* Answer true if the receiver is a static field
	*/

	public final boolean isStatic() {
	return (modifiers & ClassFileConstants.AccStatic) != 0;
	}
	/* Answer true if the receiver is not defined in the source of the declaringClass
	*/

	public final boolean isSynthetic() {
	return (modifiers & ClassFileConstants.AccSynthetic) != 0;
	}
	/* Answer true if the receiver is a transient field
	*/

	public final boolean isTransient() {
	return (modifiers & ClassFileConstants.AccTransient) != 0;
	}
	/* Answer true if the receiver's declaring type is deprecated (or any of its enclosing types)
	*/

	public final boolean isViewedAsDeprecated() {
	return (modifiers & (ClassFileConstants.AccDeprecated \| ExtraCompilerModifiers.AccDeprecatedImplicitly)) != 0;
	}
	/* Answer true if the receiver is a volatile field
	*/

	public final boolean isVolatile() {
	return (modifiers & ClassFileConstants.AccVolatile) != 0;
	}
	/**
	* Returns the original field (as opposed to parameterized instances)
	*/
	public FieldBinding original() {
	return this;
	}
	public void setAnnotations(AnnotationBinding[] annotations) {
	this.declaringClass.storeAnnotations(this, annotations);
	}
	public boolean isFor(AbstractVariableDeclaration variableDeclaration)
	{
	return false;
	}
	//public FieldDeclaration sourceField() {
	// SourceTypeBinding sourceType;
	// try {
	// sourceType = (SourceTypeBinding) declaringClass;
	// } catch (ClassCastException e) {
	// return null;
	// }
	//
	// FieldDeclaration[] fields = sourceType.scope.referenceContext.fields;
	// if (fields != null) {
	// for (int i = fields.length; --i >= 0;)
	// if (this == fields[i].binding)
	// return fields[i];
	// }
	// return null;
	//}
	}