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The AspectJ weaver applies aspects to Java classes. It can be used as a Java agent in order to apply load-time
weaving (LTW) during class-loading and also contains the AspectJ runtime classes.
/* *******************************************************************
* Copyright (c) 2002 Palo Alto Research Center, Incorporated (PARC).
* All rights reserved.
* This program and the accompanying materials are made available
* under the terms of the Eclipse Public License v 2.0
* which accompanies this distribution and is available at
* https://www.eclipse.org/org/documents/epl-2.0/EPL-2.0.txt
*
* Contributors:
* PARC initial implementation
* ******************************************************************/
package org.aspectj.weaver.patterns;
import java.io.IOException;
import java.lang.reflect.Modifier;
import java.util.HashMap;
import java.util.Map;
import org.aspectj.bridge.IMessage;
import org.aspectj.bridge.MessageUtil;
import org.aspectj.util.FuzzyBoolean;
import org.aspectj.weaver.CompressingDataOutputStream;
import org.aspectj.weaver.ISourceContext;
import org.aspectj.weaver.IntMap;
import org.aspectj.weaver.ResolvedPointcutDefinition;
import org.aspectj.weaver.ResolvedType;
import org.aspectj.weaver.Shadow;
import org.aspectj.weaver.ShadowMunger;
import org.aspectj.weaver.TypeVariable;
import org.aspectj.weaver.TypeVariableReference;
import org.aspectj.weaver.UnresolvedType;
import org.aspectj.weaver.VersionedDataInputStream;
import org.aspectj.weaver.WeaverMessages;
import org.aspectj.weaver.World;
import org.aspectj.weaver.ast.Test;
/**
*/
// XXX needs check that arguments contains no WildTypePatterns
public class ReferencePointcut extends Pointcut {
public UnresolvedType onType;
public TypePattern onTypeSymbolic;
public String name;
public TypePatternList arguments;
/**
* if this is non-null then when the pointcut is concretized the result will be parameterized too.
*/
private Map typeVariableMap;
// public ResolvedPointcut binding;
public ReferencePointcut(TypePattern onTypeSymbolic, String name, TypePatternList arguments) {
this.onTypeSymbolic = onTypeSymbolic;
this.name = name;
this.arguments = arguments;
this.pointcutKind = REFERENCE;
}
public ReferencePointcut(UnresolvedType onType, String name, TypePatternList arguments) {
this.onType = onType;
this.name = name;
this.arguments = arguments;
this.pointcutKind = REFERENCE;
}
public int couldMatchKinds() {
return Shadow.ALL_SHADOW_KINDS_BITS;
}
// ??? do either of these match methods make any sense???
public FuzzyBoolean fastMatch(FastMatchInfo type) {
return FuzzyBoolean.MAYBE;
}
/**
* Do I really match this shadow?
*/
protected FuzzyBoolean matchInternal(Shadow shadow) {
return FuzzyBoolean.NO;
}
public String toString() {
StringBuilder buf = new StringBuilder();
if (onType != null) {
buf.append(onType);
buf.append(".");
// for (int i=0, len=fromType.length; i < len; i++) {
// buf.append(fromType[i]);
// buf.append(".");
// }
}
buf.append(name);
buf.append(arguments.toString());
return buf.toString();
}
public void write(CompressingDataOutputStream s) throws IOException {
// XXX ignores onType
s.writeByte(Pointcut.REFERENCE);
if (onType != null) {
s.writeBoolean(true);
onType.write(s);
} else {
s.writeBoolean(false);
}
s.writeUTF(name);
arguments.write(s);
writeLocation(s);
}
public static Pointcut read(VersionedDataInputStream s, ISourceContext context) throws IOException {
UnresolvedType onType = null;
if (s.readBoolean()) {
onType = UnresolvedType.read(s);
}
ReferencePointcut ret = new ReferencePointcut(onType, s.readUTF(), TypePatternList.read(s, context));
ret.readLocation(context, s);
return ret;
}
public void resolveBindings(IScope scope, Bindings bindings) {
if (onTypeSymbolic != null) {
onType = onTypeSymbolic.resolveExactType(scope, bindings);
// in this case we've already signaled an error
if (ResolvedType.isMissing(onType)) {
return;
}
}
ResolvedType searchType;
if (onType != null) {
searchType = scope.getWorld().resolve(onType);
} else {
searchType = scope.getEnclosingType();
}
if (searchType.isTypeVariableReference()) {
searchType = ((TypeVariableReference) searchType).getTypeVariable().getFirstBound().resolve(scope.getWorld());
}
arguments.resolveBindings(scope, bindings, true, true);
// XXX ensure that arguments has no ..'s in it
// check that I refer to a real pointcut declaration and that I match
ResolvedPointcutDefinition pointcutDef = searchType.findPointcut(name);
// if we're not a static reference, then do a lookup of outers
if (pointcutDef == null && onType == null) {
while (true) {
UnresolvedType declaringType = searchType.getDeclaringType();
if (declaringType == null) {
break;
}
searchType = declaringType.resolve(scope.getWorld());
pointcutDef = searchType.findPointcut(name);
if (pointcutDef != null) {
// make this a static reference
onType = searchType;
break;
}
}
}
if (pointcutDef == null) {
scope.message(IMessage.ERROR, this, "can't find referenced pointcut " + name);
return;
}
// check visibility
if (!pointcutDef.isVisible(scope.getEnclosingType())) {
scope.message(IMessage.ERROR, this, "pointcut declaration " + pointcutDef + " is not accessible");
return;
}
if (Modifier.isAbstract(pointcutDef.getModifiers())) {
if (onType != null && !onType.isTypeVariableReference()) {
scope.message(IMessage.ERROR, this, "can't make static reference to abstract pointcut");
return;
} else if (!searchType.isAbstract()) {
scope.message(IMessage.ERROR, this, "can't use abstract pointcut in concrete context");
return;
}
}
ResolvedType[] parameterTypes = scope.getWorld().resolve(pointcutDef.getParameterTypes());
if (parameterTypes.length != arguments.size()) {
scope.message(IMessage.ERROR, this, "incompatible number of arguments to pointcut, expected " + parameterTypes.length
+ " found " + arguments.size());
return;
}
// if (onType == null) onType = pointcutDef.getDeclaringType();
if (onType != null) {
if (onType.isParameterizedType()) {
// build a type map mapping type variable names in the generic type to
// the type parameters presented
typeVariableMap = new HashMap<>();
ResolvedType underlyingGenericType = ((ResolvedType) onType).getGenericType();
TypeVariable[] tVars = underlyingGenericType.getTypeVariables();
ResolvedType[] typeParams = ((ResolvedType) onType).getResolvedTypeParameters();
for (int i = 0; i < tVars.length; i++) {
typeVariableMap.put(tVars[i].getName(), typeParams[i]);
}
} else if (onType.isGenericType()) {
scope.message(MessageUtil.error(WeaverMessages.format(WeaverMessages.CANT_REFERENCE_POINTCUT_IN_RAW_TYPE),
getSourceLocation()));
}
}
for (int i = 0, len = arguments.size(); i < len; i++) {
TypePattern p = arguments.get(i);
// we are allowed to bind to pointcuts which use subtypes as this is type safe
if (typeVariableMap != null) {
p = p.parameterizeWith(typeVariableMap, scope.getWorld());
}
if (p == TypePattern.NO) {
scope.message(IMessage.ERROR, this, "bad parameter to pointcut reference");
return;
}
boolean reportProblem = false;
if (parameterTypes[i].isTypeVariableReference() && p.getExactType().isTypeVariableReference()) {
UnresolvedType One = ((TypeVariableReference) parameterTypes[i]).getTypeVariable().getFirstBound();
UnresolvedType Two = ((TypeVariableReference) p.getExactType()).getTypeVariable().getFirstBound();
reportProblem = !One.resolve(scope.getWorld()).isAssignableFrom(Two.resolve(scope.getWorld()));
} else {
reportProblem = !p.matchesSubtypes(parameterTypes[i]) && !p.getExactType().equals(UnresolvedType.OBJECT);
}
if (reportProblem) {
scope.message(IMessage.ERROR, this, "incompatible type, expected " + parameterTypes[i].getName() + " found " + p
+ ". Check the type specified in your pointcut");
return;
}
}
}
public void postRead(ResolvedType enclosingType) {
arguments.postRead(enclosingType);
}
protected Test findResidueInternal(Shadow shadow, ExposedState state) {
throw new RuntimeException("shouldn't happen");
}
// ??? This is not thread safe, but this class is not designed for multi-threading
private boolean concretizing = false;
// declaring type is the type that declared the member referencing this pointcut.
// If it declares a matching private pointcut, then that pointcut should be used
// and not one in a subtype that happens to have the same name.
public Pointcut concretize1(ResolvedType searchStart, ResolvedType declaringType, IntMap bindings) {
if (concretizing) {
// Thread.currentThread().dumpStack();
searchStart
.getWorld()
.getMessageHandler()
.handleMessage(
MessageUtil.error(WeaverMessages.format(WeaverMessages.CIRCULAR_POINTCUT, this), getSourceLocation()));
Pointcut p = Pointcut.makeMatchesNothing(Pointcut.CONCRETE);
p.sourceContext = sourceContext;
return p;
}
try {
concretizing = true;
ResolvedPointcutDefinition pointcutDec;
if (onType != null) {
searchStart = onType.resolve(searchStart.getWorld());
if (searchStart.isMissing()) {
return Pointcut.makeMatchesNothing(Pointcut.CONCRETE);
}
if (onType.isTypeVariableReference()) {
// need to replace on type with the binding for the type variable
// in the declaring type
if (declaringType.isParameterizedType()) {
TypeVariable[] tvs = declaringType.getGenericType().getTypeVariables();
String typeVariableName = ((TypeVariableReference) onType).getTypeVariable().getName();
for (int i = 0; i < tvs.length; i++) {
if (tvs[i].getName().equals(typeVariableName)) {
ResolvedType realOnType = declaringType.getTypeParameters()[i].resolve(declaringType.getWorld());
onType = realOnType;
searchStart = realOnType;
break;
}
}
}
}
}
if (declaringType == null) {
declaringType = searchStart;
}
pointcutDec = declaringType.findPointcut(name);
boolean foundMatchingPointcut = (pointcutDec != null && Modifier.isPrivate(pointcutDec.getModifiers()));
if (!foundMatchingPointcut) {
pointcutDec = searchStart.findPointcut(name);
if (pointcutDec == null) {
searchStart
.getWorld()
.getMessageHandler()
.handleMessage(
MessageUtil.error(
WeaverMessages.format(WeaverMessages.CANT_FIND_POINTCUT, name, searchStart.getName()),
getSourceLocation()));
return Pointcut.makeMatchesNothing(Pointcut.CONCRETE);
}
}
if (pointcutDec.isAbstract()) {
// Thread.currentThread().dumpStack();
ShadowMunger enclosingAdvice = bindings.getEnclosingAdvice();
searchStart.getWorld().showMessage(IMessage.ERROR,
WeaverMessages.format(WeaverMessages.ABSTRACT_POINTCUT, pointcutDec), getSourceLocation(),
(null == enclosingAdvice) ? null : enclosingAdvice.getSourceLocation());
return Pointcut.makeMatchesNothing(Pointcut.CONCRETE);
}
// System.err.println("start: " + searchStart);
// ResolvedType[] parameterTypes = searchStart.getWorld().resolve(pointcutDec.getParameterTypes());
TypePatternList arguments = this.arguments.resolveReferences(bindings);
IntMap newBindings = new IntMap();
for (int i = 0, len = arguments.size(); i < len; i++) {
TypePattern p = arguments.get(i);
if (p == TypePattern.NO) {
continue;
}
// we are allowed to bind to pointcuts which use subtypes as this is type safe
// this will be checked in ReferencePointcut.resolveBindings(). Can't check it here
// as we don't know about any new parents added via decp.
if (p instanceof BindingTypePattern) {
newBindings.put(i, ((BindingTypePattern) p).getFormalIndex());
}
}
if (searchStart.isParameterizedType()) {
// build a type map mapping type variable names in the generic type to
// the type parameters presented
typeVariableMap = new HashMap<>();
ResolvedType underlyingGenericType = searchStart.getGenericType();
TypeVariable[] tVars = underlyingGenericType.getTypeVariables();
ResolvedType[] typeParams = searchStart.getResolvedTypeParameters();
for (int i = 0; i < tVars.length; i++) {
typeVariableMap.put(tVars[i].getName(), typeParams[i]);
}
}
newBindings.copyContext(bindings);
newBindings.pushEnclosingDefinition(pointcutDec);
try {
Pointcut ret = pointcutDec.getPointcut();
if (typeVariableMap != null && !hasBeenParameterized) {
ret = ret.parameterizeWith(typeVariableMap, searchStart.getWorld());
ret.hasBeenParameterized = true;
}
return ret.concretize(searchStart, declaringType, newBindings);
} finally {
newBindings.popEnclosingDefinitition();
}
} finally {
concretizing = false;
}
}
/**
* make a version of this pointcut with any refs to typeVariables replaced by their entry in the map. Tricky thing is, we can't
* do this at the point in time this method will be called, so we make a version that will parameterize the pointcut it
* ultimately resolves to.
*/
public Pointcut parameterizeWith(Map typeVariableMap, World w) {
ReferencePointcut ret = new ReferencePointcut(onType, name, arguments);
ret.onTypeSymbolic = onTypeSymbolic;
ret.typeVariableMap = typeVariableMap;
return ret;
}
// We want to keep the original source location, not the reference location
protected boolean shouldCopyLocationForConcretize() {
return false;
}
public boolean equals(Object other) {
if (!(other instanceof ReferencePointcut)) {
return false;
}
if (this == other) {
return true;
}
ReferencePointcut o = (ReferencePointcut) other;
return o.name.equals(name) && o.arguments.equals(arguments)
&& ((o.onType == null) ? (onType == null) : o.onType.equals(onType));
}
public int hashCode() {
int result = 17;
result = 37 * result + ((onType == null) ? 0 : onType.hashCode());
result = 37 * result + arguments.hashCode();
result = 37 * result + name.hashCode();
return result;
}
public Object accept(PatternNodeVisitor visitor, Object data) {
return visitor.visit(this, data);
}
@Override
public Object traverse(PatternNodeVisitor visitor, Object data) {
Object ret = accept(visitor, data);
if (this.onTypeSymbolic != null)
this.onTypeSymbolic.traverse(visitor, ret);
if (this.arguments != null)
this.arguments.traverse(visitor, ret);
return ret;
}
}
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