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/* *******************************************************************
* Copyright (c) 1999-2001 Xerox Corporation,
* 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:
* Xerox/PARC initial implementation
* ******************************************************************/
package org.aspectj.runtime.reflect;
import java.util.Stack;
import org.aspectj.lang.JoinPoint;
import org.aspectj.lang.ProceedingJoinPoint;
import org.aspectj.lang.Signature;
import org.aspectj.lang.reflect.SourceLocation;
import org.aspectj.runtime.internal.AroundClosure;
class JoinPointImpl implements ProceedingJoinPoint {
static class StaticPartImpl implements JoinPoint.StaticPart {
String kind;
Signature signature;
SourceLocation sourceLocation;
private int id;
public StaticPartImpl(int id, String kind, Signature signature, SourceLocation sourceLocation) {
this.kind = kind;
this.signature = signature;
this.sourceLocation = sourceLocation;
this.id = id;
}
public int getId() {
return id;
}
public String getKind() {
return kind;
}
public Signature getSignature() {
return signature;
}
public SourceLocation getSourceLocation() {
return sourceLocation;
}
String toString(StringMaker sm) {
StringBuilder buf = new StringBuilder();
buf.append(sm.makeKindName(getKind()));
buf.append("(");
buf.append(((SignatureImpl) getSignature()).toString(sm));
buf.append(")");
return buf.toString();
}
public final String toString() {
return toString(StringMaker.middleStringMaker);
}
public final String toShortString() {
return toString(StringMaker.shortStringMaker);
}
public final String toLongString() {
return toString(StringMaker.longStringMaker);
}
}
static class EnclosingStaticPartImpl extends StaticPartImpl implements EnclosingStaticPart {
public EnclosingStaticPartImpl(int count, String kind, Signature signature, SourceLocation sourceLocation) {
super(count, kind, signature, sourceLocation);
}
}
static class InheritableThreadLocalAroundClosureStack extends InheritableThreadLocal> {
@Override
protected Stack initialValue() {
return new Stack<>();
}
@Override
protected Stack childValue(Stack parentValue) {
return (Stack) parentValue.clone();
}
}
Object _this;
Object target;
Object[] args;
org.aspectj.lang.JoinPoint.StaticPart staticPart;
public JoinPointImpl(org.aspectj.lang.JoinPoint.StaticPart staticPart, Object _this, Object target, Object[] args) {
this.staticPart = staticPart;
this._this = _this;
this.target = target;
this.args = args;
}
public Object getThis() {
return _this;
}
public Object getTarget() {
return target;
}
public Object[] getArgs() {
if (args == null) {
args = new Object[0];
}
Object[] argsCopy = new Object[args.length];
System.arraycopy(args, 0, argsCopy, 0, args.length);
return argsCopy;
}
public org.aspectj.lang.JoinPoint.StaticPart getStaticPart() {
return staticPart;
}
public String getKind() {
return staticPart.getKind();
}
public Signature getSignature() {
return staticPart.getSignature();
}
public SourceLocation getSourceLocation() {
return staticPart.getSourceLocation();
}
public final String toString() {
return staticPart.toString();
}
public final String toShortString() {
return staticPart.toShortString();
}
public final String toLongString() {
return staticPart.toLongString();
}
// To proceed we need a closure to proceed on. Generated code
// will either be using arc or arcs but not both. arcs being non-null
// indicates it is in use (even if an empty stack)
private AroundClosure arc = null;
private InheritableThreadLocalAroundClosureStack arcs = null;
public void set$AroundClosure(AroundClosure arc) {
this.arc = arc;
}
public void stack$AroundClosure(AroundClosure arc) {
// If input parameter arc is null this is the 'unlink' call from AroundClosure
if (arcs == null) {
arcs = new InheritableThreadLocalAroundClosureStack();
}
if (arc==null) {
this.arcs.get().pop();
} else {
this.arcs.get().push(arc);
}
}
public Object proceed() throws Throwable {
// when called from a before advice, but be a no-op
if (arcs == null) {
if (arc == null) {
return null;
} else {
return arc.run(arc.getState());
}
} else {
final AroundClosure ac = arcs.get().peek();
return ac.run(ac.getState());
}
}
public Object proceed(Object[] adviceBindings) throws Throwable {
// when called from a before advice, but be a no-op
AroundClosure ac = null;
if (arcs == null) {
ac = arc;
} else {
ac = arcs.get().peek();
}
if (ac == null) {
return null;
} else {
// Based on the bit flags in the AroundClosure we can determine what to
// expect in the adviceBindings array. We may or may not be expecting
// the first value to be a new this or a new target... (see pr126167)
int flags = ac.getFlags();
boolean unset = (flags & 0x100000) != 0;
boolean thisTargetTheSame = (flags & 0x010000) != 0;
boolean hasThis = (flags & 0x001000) != 0;
boolean bindsThis = (flags & 0x000100) != 0;
boolean hasTarget = (flags & 0x000010) != 0;
boolean bindsTarget = (flags & 0x000001) != 0;
// state is always consistent with caller?,callee?,formals...,jp
Object[] state = ac.getState();
// these next two numbers can differ because some join points have a this and
// target that are the same (eg. call) - and yet you can bind this and target
// separately.
// In the state array, [0] may be this, [1] may be target
int firstArgumentIndexIntoAdviceBindings = 0;
int firstArgumentIndexIntoState = 0;
firstArgumentIndexIntoState += (hasThis ? 1 : 0);
firstArgumentIndexIntoState += (hasTarget && !thisTargetTheSame ? 1 : 0);
if (hasThis) {
if (bindsThis) {
// replace [0] (this)
firstArgumentIndexIntoAdviceBindings = 1;
state[0] = adviceBindings[0];
} else {
// leave state[0] alone, its OK
}
}
if (hasTarget) {
if (bindsTarget) {
if (thisTargetTheSame) {
// this and target are the same so replace state[0]
firstArgumentIndexIntoAdviceBindings = 1 + (bindsThis ? 1 : 0);
state[0] = adviceBindings[(bindsThis ? 1 : 0)];
} else {
// need to replace the target, and it is different to this, whether
// that means replacing state[0] or state[1] depends on whether
// the join point has a this
// This previous variant doesn't seem to cope with only binding target at a joinpoint
// which has both this and target. It forces you to supply this even if you didn't bind
// it.
// firstArgumentIndexIntoAdviceBindings = (hasThis ? 1 : 0) + 1;
// state[hasThis ? 1 : 0] = adviceBindings[hasThis ? 1 : 0];
int targetPositionInAdviceBindings = (hasThis && bindsThis) ? 1 : 0;
firstArgumentIndexIntoAdviceBindings = ((hasThis&&bindsThis)?1:0)+((hasTarget&&bindsTarget&&!thisTargetTheSame)?1:0);
state[hasThis ? 1 : 0] = adviceBindings[targetPositionInAdviceBindings];
}
} else {
// leave state[0]/state[1] alone, they are OK
}
}
// copy the rest across
for (int i = firstArgumentIndexIntoAdviceBindings; i < adviceBindings.length; i++) {
state[firstArgumentIndexIntoState + (i - firstArgumentIndexIntoAdviceBindings)] = adviceBindings[i];
}
// old code that did this, didnt allow this/target overriding
// for (int i = state.length-2; i >= 0; i--) {
// int formalIndex = (adviceBindings.length - 1) - (state.length-2) + i;
// if (formalIndex >= 0 && formalIndex < adviceBindings.length) {
// state[i] = adviceBindings[formalIndex];
// }
// }
return ac.run(state);
}
}
}