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/*
* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS HEADER.
*
* Copyright (c) 1997-2010 Oracle and/or its affiliates. All rights reserved.
*
* The contents of this file are subject to the terms of either the GNU
* General Public License Version 2 only ("GPL") or the Common Development
* and Distribution License("CDDL") (collectively, the "License"). You
* may not use this file except in compliance with the License. You can
* obtain a copy of the License at
* https://glassfish.dev.java.net/public/CDDL+GPL_1_1.html
* or packager/legal/LICENSE.txt. See the License for the specific
* language governing permissions and limitations under the License.
*
* When distributing the software, include this License Header Notice in each
* file and include the License file at packager/legal/LICENSE.txt.
*
* GPL Classpath Exception:
* Oracle designates this particular file as subject to the "Classpath"
* exception as provided by Oracle in the GPL Version 2 section of the License
* file that accompanied this code.
*
* Modifications:
* If applicable, add the following below the License Header, with the fields
* enclosed by brackets [] replaced by your own identifying information:
* "Portions Copyright [year] [name of copyright owner]"
*
* Contributor(s):
* If you wish your version of this file to be governed by only the CDDL or
* only the GPL Version 2, indicate your decision by adding "[Contributor]
* elects to include this software in this distribution under the [CDDL or GPL
* Version 2] license." If you don't indicate a single choice of license, a
* recipient has the option to distribute your version of this file under
* either the CDDL, the GPL Version 2 or to extend the choice of license to
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*/
package com.sun.jdo.api.persistence.enhancer.impl;
import java.util.Map;
import java.util.HashMap;
import java.util.Vector;
import java.util.Stack;
import java.util.Enumeration;
import com.sun.jdo.api.persistence.enhancer.classfile.*;
import com.sun.jdo.api.persistence.enhancer.util.Support;
import com.sun.jdo.api.persistence.enhancer.util.InternalError;
import com.sun.jdo.api.persistence.enhancer.util.ClassFileSource;
//@olsen: added import
import com.sun.jdo.api.persistence.enhancer.meta.JDOMetaData;
//@olsen: cosmetics
//@olsen: moved: this class -> package impl
//@olsen: subst: (object)state -> flags
//@olsen: subst: JDOFlags -> jdoFlags
//@olsen: subst: JDO[gs]etFlags -> jdo[GS]etFlags
//@olsen: subst: (object)reference -> stateManager
//@olsen: subst: [Nn]eedsJDORefMethods -> [Nn]eedsJDOStateManagerMethods
//@olsen: subst: JDORef -> jdoStateManager
//@olsen: subst: JDO[gs]etRef -> jdo[GS]etStateManager
//@olsen: subst: [iI]Persistent -> [pP]ersistenceCapable
//@olsen: subst: PersistentAux -> StateManager
//@olsen: subst: jdo/ -> com/sun/forte4j/persistence/internal/
//@olsen: subst: /* ... */ -> // ...
//@olsen: subst: FilterEnv -> Environment
//@olsen: dropped parameter 'Environment env', use association instead
//@olsen: subst: Hashtable -> Map, HashMap
//@olsen: subst: absolut jdo types and names -> constants from JDOMetaData
//@olsen: subst: .classControl(). -> .
//@olsen: subst: noteList -> note
//@olsen: added: support for I18N
//@olsen: subst: FilterError -> UserException, affirm()
//@olsen: removed: proprietary support for HashCode
//@olsen: removed: support for [No]AnnotateField
//@olsen: removed: old, disabled ODI code
/*
* The current code annotation strategy
* 1) getfield instructions operating on persistent types cause a fetch
* 2) putfield instructions operating on persistent types cause a dirty
* 3) fetches which can be identified to be a fetch of "this" are moved
* to the start of the method.
* 3) dirties which can be identified to be a dirty of "this" are moved
* to the start of the method only if the code path to the dirty is
* unconditional.
* 4) Array loads cause array fetches
* 5) Array stores cause array dirtys
* 6) Each array fetch/dirty call which occurs in a loop construct
* is allocated a dedicated local variable which is used to cache
* the last array dirtied or fetched by the instruction in order to
* minimize the overhead in array manipulation within a loop.
* 7) In calls to methods in non-persistence-aware classes which are
* declared to take array parameters, the array parameter is fetched.
* If the called code stores to the array, the user must manually
* annotate.
* 8) Certain method invocations trigger fetches or dirties of arguments.
* These special cases are listed in InvokeAnnotation.java.
*
* Possible Alternative Code Annotation strategy
* 1) non-static non-private methods always fetch/dirty "this"
* 2) non-static private methods never fetch but may dirty "this"
* 3) invocations of private methods from static methods fetch the target
* 4) invocations of private methods from non-static methods fetch the
* target if it can't be identified as "this"
* 5) putfields always cause dirtying of the target but if the
* target is known to be this, promote to a dirty of this.
* 6) getfields only cause fetching of the target if the
* target is not known to be this
* 7) Array loads cause array fetches
* 8) Array stores cause array dirtys
*/
/**
* MethodAnnotater controls the code annotation for a single method
* within a class.
*/
//^olsen: move code -> MethodAction
class MethodAnnotater
extends Support
implements AnnotationConstants {
//@olsen: made final
private final ClassAction ca;
//@olsen: made final
private final ClassMethod method;
//@olsen: made final
private final ConstantPool pool;
/* Central repository for the options and classes */
//@olsen: added association
//@olsen: made final
private final Environment env;
/* What types of annotation will be done on the method? */
private int annotate;
/* List of single element register values (Integer) for temporaries */
private Vector tmpRegisters;
/* List of double element register values (Integer) for temporaries */
private Vector tmpDoubleRegisters;
/* List of single word register values which cache fetches/stores
* Each of these registers must be initialized to null at the start of
* the method */
//@olsen: disabled feature
/*
private Vector caches;
*/
/* The maximum amount of stack needed by any specific annotation sequence,
* less the amount of stack which the annotated instruction is known to
* need, if any */
private short annotationStack = 0;
/* If true, the method will contain an unconditional fetch(this) */
//@olsen: disabled feature
/*
private boolean fetchThis = false;
*/
/* If true, the method will contain an unconditional dirty(this) */
//@olsen: disabled feature
/*
private boolean dirtyThis = false;
*/
/* Table mapping Insn to InsnNote - allows annotation computations to
* be attached to instructions non-intrusively */
private Map insnNotes = new HashMap(11);
/* The largest loop contained within the method, or null. */
//@olsen: disabled feature
/*
private Loop largestLoop;
*/
// package accessors
/**
* Is any annotation needed for this method? The result of this
* method isn't valid until after checkMethod has been run.
*/
boolean needsAnnotation() {
return annotate != 0;
}
/**
* Constructor
*/
//@olsen: added parameter 'env' for association
MethodAnnotater(ClassAction ca,
ClassMethod method,
Environment env) {
this.ca = ca;
this.method = method;
this.env = env;
this.pool = ca.classFile().pool();
}
// ---------------------------------------------------------------------------
/**
* Examine the method to determine what sort of annotations are needed
*/
void checkMethod() {
//@olsen: added printing output
env.message(
"checking method " + ca.userClassName()//NOI18N
+ "." + method.name().asString()//NOI18N
+ Descriptor.userMethodArgs(method.signature().asString()));
//@olsen: cosmetics
annotate = 0;
final CodeAttribute codeAttr = method.codeAttribute();
if (codeAttr == null) {
return;
}
//^olsen: make robust
/*
if (isAnnotated(codeAttr)) {
env.message("Method " + ca.userClassName() +
"." + method.name().asString() +
Descriptor.userMethodArgs(method.signature().asString()) +
" is already annotated.");
return;
}
*/
// look for certain special cases to avoid
//@olsen: cosmetics
if (avoidAnnotation()) {
return;
}
checkCode(codeAttr);
//@olsen: disabled feature
/*
if (!avoidAnnotation()) {
largestLoop = Loop.checkLoops(codeAttr.theCode());
checkCode(codeAttr);
} else if (methodIsPersistentFinalize()) {
annotate = MakeThisTransient;
}
*/
}
/**
* Check to see if the code attribute contains any calls to
* Implementaiton.fetch, or Implementation.dirty
*/
//^olsen: make robust
/*
private boolean isAnnotated(CodeAttribute codeAttr) {
for (Insn insn = codeAttr.theCode();
insn != null;
insn = insn.next()) {
// All non-interface method invocations are InsnConstOp
if (insn instanceof InsnConstOp) {
InsnConstOp coInsn = (InsnConstOp) insn;
ConstBasic operand = coInsn.value();
if (operand instanceof ConstMethodRef) {
// A method invocation of some sort
ConstMethodRef methRef = (ConstMethodRef) operand;
if (methRef.className().asString().equals("com/sun/forte4j/persistence/internal/Implementation")) {
// A method invocation against class Persistent
ConstNameAndType nt = methRef.nameAndType();
String ntName = nt.name().asString();
if (ntName.equals("fetch") || ntName.equals("dirty"))
// A fetch or a dirty call
return true;
}
}
}
}
return false;
}
*/
/**
* Check to see if this method is an initializer.
*/
//@olsen: disabled feature
/*
private boolean methodIsInitializer() {
String methName = method.name().asString();
//^olsen: check for serialization
return (methName.equals("") ||
(methName.equals("readObject") &&
method.signature().asString().equals(
"(Ljava/io/ObjectInputStream;)V")));
}
*/
/**
* Check to see if this method is a finalize method.
*/
//@olsen: disabled feature
/*
private boolean methodIsFinalize() {
return (method.name().asString().equals("finalize") &&
method.signature().asString().equals("()V") &&
!method.isStatic());
}
*/
/**
* Check to see if this method is an persistent finalize.
*/
//@olsen: disabled feature
/*
private boolean methodIsPersistentFinalize() {
return (methodIsFinalize() &&
ca.persistCapable());
}
*/
/**
* Check to see if this is a special case that should not be
* annotated.
*/
private boolean avoidAnnotation() {
//@olsen: cosmetics
//@olsen: allow for annotating initializers+finalizers
/*
final String methodName = method.name().asString();
final String methodSig = method.signature().asString();
if (methodName.equals("") || methodIsFinalize())
// Never annotate class initializers or finalizers
return true;
*/
//^olsen: enable feature, rather use HashMap for lookup
//@olsen: disabled feature
/*
if (ca.persistCapable()) {
if ((methodName.equals("initializeContents") &&
methodSig.equals("(Lcom/sun/forte4j/persistence/internal/ObjectContents;)V")) ||
(methodName.equals("flushContents") &&
methodSig.equals("(Lcom/sun/forte4j/persistence/internal/ObjectContents;)V")) ||
(methodName.equals("clearContents") &&
methodSig.equals("()V")) ||
(methodName.equals("postInitializeContents") &&
methodSig.equals("()V")) ||
(methodName.equals("preFlushContents") &&
methodSig.equals("()V")) ||
(methodName.equals("preClearContents") &&
methodSig.equals("()V")) ||
(methodName.equals("jdoGetStateManager") &&
methodSig.equals("()Lcom/sun/forte4j/persistence/internal/StateManager;")) ||
(methodName.equals("jdoSetStateManager") &&
methodSig.equals("(Lcom/sun/forte4j/persistence/internal/StateManager;)V")) ||
(methodName.equals("jdoGetFlags") &&
methodSig.equals("()B")) ||
(methodName.equals("jdoSetFlags") &&
methodSig.equals("(B)V")))
// This is one of the special persistence actions.
// Don't annotate it
return true;
}
*/
return false;
}
// ---------------------------------------------------------------------------
/**
* Check the code attribute for possible annotations
*/
//^olsen: move code to inner class ?!
void checkCode(CodeAttribute codeAttr) {
//@olsen: cosmetics
Insn firstInsn = codeAttr.theCode();
// mark branch targets so we can distinguish them from
// targets which exist for the benefit of line numbers,
// local variables, etc.
for (Insn markInsn = firstInsn;
markInsn != null;
markInsn = markInsn.next()) {
markInsn.markTargets();
}
int allFlags = 0;
//@olsen: disabled feature
/*
boolean branchesSeen = false;
*/
for (Insn insn = firstInsn; insn != null; insn = insn.next() ) {
InsnNote note = null;
switch(insn.opcode()) {
//@olsen: disabled feature
/*
case opc_invokestatic:
case opc_invokespecial:
case opc_invokevirtual:
case opc_invokeinterface:
note = noteInvokeAnnotation(insn);
break;
*/
case opc_getfield:
note = noteGetFieldAnnotation(insn);
break;
case opc_putfield:
note = notePutFieldAnnotation(insn);
break;
//@olsen: disabled feature
/*
case opc_aaload:
case opc_baload:
case opc_caload:
case opc_saload:
case opc_iaload:
case opc_laload:
case opc_faload:
case opc_daload:
note = noteArrayLoadAnnotation(insn);
break;
case opc_aastore:
case opc_bastore:
case opc_castore:
case opc_sastore:
case opc_iastore:
case opc_lastore:
case opc_fastore:
case opc_dastore:
note = noteArrayStoreAnnotation(insn);
break;
*/
default:
break;
}
if (note != null) {
addNoteList(note);
//@olsen: ensured to use single note only (as instantiated)
affirm((note.next() == null),
"Number of annotation notes for instruction > 1.");//NOI18N
allFlags |= note.insnFlags;
//@olsen: ensured to use single note only (as instantiated)
/*
for (InsnNote aNote = note;
aNote != null;
aNote = aNote.next()) {
//@olsen: disabled feature
///
if (branchesSeen == false)
aNote.insnFlags |= Unconditional;
///
//@olsen: disabled feature
///
if (largestLoop != null && largestLoop.contains(insn))
aNote.insnFlags |= InLoop;
///
//@olsen: disabled feature
///
// annotating based on thisOptimization will be done later
if (aNote.dirtyThis() && aNote.unconditional())
dirtyThis = true;
else if (aNote.dirtyThis() || aNote.fetchThis())
fetchThis = true;
///
allFlags |= aNote.insnFlags;
}
*/
}
//@olsen: disabled feature
/*
if (insn.branches())
branchesSeen = true;
*/
}
//@olsen: disabled feature
/*
if (methodIsInitializer()) {
// An inititalizer - either force the fetchThis, dirtyThis flags
// on or off.
if (env.doInitializerOptimization()) {
// turn on the fetchThis, dirtyThis flags to inhibit fetches
// and stores of this if enabled. We won't really insert the
// fetch/dirty, since it isn't needed.
fetchThis = true;
dirtyThis = true;
} else {
// Make sure that the fetchThis, dirtyThis flags are turned off
fetchThis = false;
dirtyThis = false;
}
}
*/
//^olsen: prepare for inheritance on PC classes
//@olsen: check for annotating of clone()
final String methodName = method.name().asString();
final String methodSig = method.signature().asString();
//^olsen: annotate persistence-capable root classes only
// until the JDO spec precisely defines how to treat
// user-defined clone methods in transient classes
final boolean implementsPersistence = ca.getImplementsPersistence();
if (false) {
System.out.println(" check for annotating clone()");//NOI18N
System.out.println(" methodName = " + methodName);//NOI18N
System.out.println(" methodSig = " + methodSig);//NOI18N
System.out.println(" implementsPersistence = "//NOI18N
+ implementsPersistence);
}
if (methodName.equals("clone")//NOI18N
&& methodSig.equals("()Ljava/lang/Object;")//NOI18N
&& implementsPersistence) {
//^olsen: rather scan for 'invokespecial clone()Ljava/lang/Object;'
// in instruction loop above
allFlags |= SuperClone;
}
//@olsen: disabled feature
/*
if (methodName.equals("clone") &&
methodSig.equals("()Ljava/lang/Object;") &&
ca.persistCapable()) {
allFlags |= FetchThis;
fetchThis = true;
}
*/
annotate = allFlags;
}
/**
* Make note of annotations if needed for a method invocation instruction.
*/
//@olsen: disabled feature
/*
private InsnNote noteInvokeAnnotation(Insn insn) {
int flags = 0;
ConstBasicMemberRef methRef = (ConstBasicMemberRef)
((InsnConstOp)insn).value();
InsnArgNote note = null;
for (InvokeAnnotation invAnn
= InvokeAnnotation.checkInvoke(methRef, env);
invAnn != null;
invAnn = invAnn.next()) {
int thisFlags = 0;
Insn dep = findArgDepositer(insn, invAnn.whichArg());
if (dep != null && dep.opcode() == opc_aload_0 && !method.isStatic()) {
if ((invAnn.annotateHow() & DirtyAny) != 0)
thisFlags = DirtyThis;
else
thisFlags = FetchThis;
} else
thisFlags = invAnn.annotateHow();
InsnArgNote newNote =
new InsnArgNote(insn, thisFlags, invAnn.whichArg(),
Descriptor.extractArgSig(
methRef.nameAndType().signature().asString()));
// sort in order of decreasing stack depth
if (note == null || note.arg() < newNote.arg()) {
newNote.nextNote = note;
note = newNote;
} else {
InsnArgNote aNote = note;
while (aNote.nextNote != null && aNote.nextNote.arg() > newNote.arg())
aNote = aNote.nextNote;
newNote.nextNote = aNote.nextNote;
aNote.nextNote = newNote;
}
}
return note;
}
*/
/**
* make note of annotations if needed for the getField instruction.
*/
//^olsen: merge code with notePutFieldAnnotation() ?!
private InsnNote noteGetFieldAnnotation(Insn insn) {
//@olsen: cosmetics
final InsnConstOp getFieldInsn = (InsnConstOp)insn;
final ConstFieldRef fieldRef = (ConstFieldRef)getFieldInsn.value();
final String fieldOf = fieldRef.className().asString();
//@olsen: changed to use JDOMetaData
final String fieldName
= fieldRef.nameAndType().name().asString();
final JDOMetaData meta = env.getJDOMetaData();
if (!meta.isPersistentField(fieldOf, fieldName))
return null;
//@olsen: disabled feature
/*
final ClassControl cc = env.findClass(fieldOf);
if (cc == null || !cc.persistCapable())
return null;
*/
//@olsen: added checks
final boolean dfgField
= meta.isDefaultFetchGroupField(fieldOf, fieldName);
final boolean pkField
= meta.isPrimaryKeyField(fieldOf, fieldName);
final int fieldIndex
= meta.getFieldNo(fieldOf, fieldName);
final String targetPCRootClass
= meta.getPersistenceCapableRootClass(fieldOf);
int flags = 0;
//@olsen: added variables
final String fieldSig = fieldRef.nameAndType().signature().asString();
// there's no field value on the stack yet
final int stackArgSize = 0;
//@olsen: added println() for debugging
if (false) {
System.out.println(" get field "//NOI18N
+ fieldOf + "." + fieldName//NOI18N
+ "[" + fieldIndex + "]"//NOI18N
+ "<" + fieldSig + ">"//NOI18N
+ " : p"//NOI18N
+ (dfgField ? ",dfg" : ",!dfg")//NOI18N
+ (pkField ? ",pk" : ",!pk")//NOI18N
+ ";");//NOI18N
}
Insn dep = findArgDepositer(insn, stackArgSize);
if (dep != null
&& dep.opcode() == opc_aload_0
&& !method.isStatic())
// This represents a fetch of "this"
flags |= FetchThis;
else
flags |= FetchPersistent;
//@olsen: added test
if (dfgField)
flags |= DFGField;
//@olsen: added test
if (pkField)
flags |= PKField;
//@olsen: changed to use JDOMetaData
return new InsnNote(insn, flags,
stackArgSize,
fieldSig, fieldOf, fieldName, fieldIndex,
targetPCRootClass);
//@olsen: disabled feature
/*
return new InsnNote(insn, flags, 0, "", cc.action());
*/
}
/**
* Generate annotations if needed for the putField instruction.
*/
//^olsen: merge code with noteGetFieldAnnotation() ?!
private InsnNote notePutFieldAnnotation(Insn insn) {
//@olsen: cosmetics
final InsnConstOp putFieldInsn = (InsnConstOp)insn;
final ConstFieldRef fieldRef = (ConstFieldRef)putFieldInsn.value();
final String fieldOf = fieldRef.className().asString();
//@olsen: changed to use JDOMetaData
final String fieldName
= fieldRef.nameAndType().name().asString();
final JDOMetaData meta = env.getJDOMetaData();
if (!meta.isPersistentField(fieldOf, fieldName))
return null;
//@olsen: disabled feature
/*
final ClassControl cc = env.findClass(fieldOf);
if (cc == null || !cc.persistCapable())
return null;
*/
//@olsen: added checks
final boolean dfgField
= meta.isDefaultFetchGroupField(fieldOf, fieldName);
final boolean pkField
= meta.isPrimaryKeyField(fieldOf, fieldName);
final int fieldIndex
= meta.getFieldNo(fieldOf, fieldName);
final String targetPCRootClass
= meta.getPersistenceCapableRootClass(fieldOf);
int flags = 0;
//@olsen: added variables
final String fieldSig = fieldRef.nameAndType().signature().asString();
// size of field value on the stack
final int stackArgSize
= (fieldSig.equals("J") || fieldSig.equals("D")) ? 2 : 1;//NOI18N
//@olsen: added println() for debugging
if (false) {
System.out.println(" put field "//NOI18N
+ fieldOf + "." + fieldName//NOI18N
+ "[" + fieldIndex + "]"//NOI18N
+ "<" + fieldSig + ">"//NOI18N
+ " : p"//NOI18N
+ (dfgField ? ",dfg" : ",!dfg")//NOI18N
+ (pkField ? ",pk" : ",!pk")//NOI18N
+ ";");//NOI18N
}
Insn dep = findArgDepositer(insn, stackArgSize);
if (dep != null
&& dep.opcode() == opc_aload_0
&& !method.isStatic())
// This represents a dirtyfication of "this"
flags |= DirtyThis;
else
flags |= DirtyPersistent;
//@olsen: added test
if (dfgField)
flags |= DFGField;
//@olsen: added test
if (pkField)
flags |= PKField;
//@olsen: changed to use JDOMetaData
return new InsnNote(insn, flags,
stackArgSize,
fieldSig, fieldOf, fieldName, fieldIndex,
targetPCRootClass);
//@olsen: disabled feature
/*
return new InsnNote(insn, flags, stackArgSize, fieldSig, cc.action());
*/
}
/**
* Generate annotations if needed for the arrayLoad instruction.
*/
//@olsen: disabled feature
/*
private InsnNote noteArrayLoadAnnotation(Insn insn) {
int arrayFetchType = 0;
switch(insn.opcode()) {
case opc_aaload:
arrayFetchType = ArrayTypeObject;
break;
case opc_caload:
arrayFetchType = ArrayTypeChar;
break;
case opc_saload:
arrayFetchType = ArrayTypeShort;
break;
case opc_iaload:
arrayFetchType = ArrayTypeInt;
break;
case opc_laload:
arrayFetchType = ArrayTypeLong;
break;
case opc_faload:
arrayFetchType = ArrayTypeFloat;
break;
case opc_daload:
arrayFetchType = ArrayTypeDouble;
break;
case opc_baload:
// Unfortunately, both byte arrays and boolean arrays are accessed
// using the same instruction so don't attempt to infer the array
// element type for these.
break;
}
return new InsnNote(insn, FetchArray | arrayFetchType, 1, "I", null);
}
*/
//@olsen: disabled feature
/*
private InsnNote noteArrayStoreAnnotation(Insn insn) {
int valueType = Insn.loadStoreDataType(insn.opcode());
int valueSize = Descriptor.elementSize(valueType);
String stackSig = "I" + Descriptor.elementSig(valueType);
// Compute the array store type for completeness. The generated
// annotation currently doesn't use this information because there
// are no array element type-specific overloads of dirty() but
// perhaps we'll add them at some point.
int arrayStoreType = 0;
switch(insn.opcode()) {
case opc_aastore:
arrayStoreType = ArrayTypeObject;
break;
case opc_castore:
arrayStoreType = ArrayTypeChar;
break;
case opc_sastore:
arrayStoreType = ArrayTypeShort;
break;
case opc_iastore:
arrayStoreType = ArrayTypeInt;
break;
case opc_lastore:
arrayStoreType = ArrayTypeLong;
break;
case opc_fastore:
arrayStoreType = ArrayTypeFloat;
break;
case opc_dastore:
arrayStoreType = ArrayTypeDouble;
break;
case opc_bastore:
// Unfortunately, both byte arrays and boolean arrays are accessed
// using the same instruction so don't attempt to infer the array
// element type for these.
break;
}
return new InsnNote(insn, DirtyArray | arrayStoreType,
valueSize+1, stackSig, null);
}
*/
// ---------------------------------------------------------------------------
/**
* Annotate the class method. For now, brute force rules.
*/
void annotateMethod() {
//@olsen: cosmetics
final CodeAttribute codeAttr = method.codeAttribute();
if (codeAttr == null || !needsAnnotation())
return;
//@olsen: disabled feature
/*
if ((annotate & MakeThisTransient) != 0) {
makeThisTransient(codeAttr);
if (annotate == MakeThisTransient)
return;
}
*/
//@olsen: added printing output
env.message(
"annotating method " + ca.userClassName()//NOI18N
+ "." + method.name().asString()//NOI18N
+ Descriptor.userMethodArgs(method.signature().asString()));
//@olsen: disabled feature
/*
clearThisAnnotation();
removeRedundantThisAnnotation();
*/
Insn firstInsn = codeAttr.theCode();
// First instruction is a target
Insn insn = firstInsn.next();
while (insn != null) {
switch(insn.opcode()) {
//@olsen: disabled feature
/*
case opc_invokestatic:
case opc_invokespecial:
case opc_invokevirtual:
case opc_invokeinterface:
*/
case opc_getfield:
case opc_putfield:
//@olsen: disabled feature
/*
case opc_aaload:
case opc_baload:
case opc_caload:
case opc_saload:
case opc_iaload:
case opc_laload:
case opc_faload:
case opc_daload:
case opc_aastore:
case opc_bastore:
case opc_castore:
case opc_sastore:
case opc_iastore:
case opc_lastore:
case opc_fastore:
case opc_dastore:
*/
insn = insnAnnotation(insn);
break;
default:
break;
}
insn = insn.next();
}
//@olsen: do special annotation if detected super.clone()
if ((annotate & SuperClone) != 0) {
final String superName = ca.classFile().superName().asString();
annotateClone(codeAttr, superName);
}
//@olsen: disabled feature
/*
if (methodIsInitializer()) {
} else {
// Pre- fetch/dirty this if needed
if (fetchThis || dirtyThis) {
// Optimize a fetch(this) or dirty(this) to the start of
// the method.
// For fetch calls this is:
// if (jdoFlags < 0)
// Implementation.fetch(this);
//
// For dirty calls this is:
// if ((jdoFlags&PersistenceCapable.writeBarrierSet) != 0)
// Implementation.dirty(this);
Insn newInsn = Insn.create(opc_aload_0);
Insn annotationStart = newInsn;
InsnTarget afterCondition = null;
//@olsen: disabled feature
///
if (ca.getFlagsMemberValid() &&
ca.getFlagsMember() != null) {
///
//@olsen: changed to use JDOMetaData
final String className = ca.className();
final String pcRootClass
= env.getJDOMetaData().getPersistenceCapableRootClass(className);
newInsn = newInsn.append(
Insn.create(opc_getfield,
pool.addFieldRef(
pcRootClass,
JDOMetaData.JDOFlagsFieldName,
JDOMetaData.JDOFlagsFieldSig)));
//@olsen: disabled feature
///
ClassControl flagsCC
= ca.getFlagsMemberClassControl();
newInsn = newInsn.append(
Insn.create(opc_getfield,
pool.addFieldRef(
flagsCC.className(),
ca.getFlagsMember(),
"B")));
///
afterCondition = new InsnTarget();
if (dirtyThis) {
newInsn = newInsn.append(Insn.create(opc_iconst_2));
newInsn = newInsn.append(Insn.create(opc_iand));
newInsn = newInsn.append(Insn.create(opc_ifeq, afterCondition));
newInsn = newInsn.append(Insn.create(opc_aload_0));
} else {
newInsn = newInsn.append(Insn.create(opc_ifge, afterCondition));
newInsn = newInsn.append(Insn.create(opc_aload_0));
}
//@olsen: disabled feature
///
}
///
newInsn = newInsn.append(
Insn.create(
opc_invokestatic,
pool.addMethodRef("com/sun/forte4j/persistence/internal/Implementation",
(dirtyThis ? "dirty" : "fetch"),
"(" + JDOMetaData.JDOPersistenceCapableSig + ")V")));
if (afterCondition != null)
newInsn = newInsn.append(afterCondition);
firstInsn.insert(annotationStart);
noteStack(2);
}
//@olsen: disabled feature
///
if (methodName.equals("clone") &&
methodSig.equals("()Ljava/lang/Object;") &&
!ca.getNeedsClone()) {
annotateClone(codeAttr, superName);
}
///
//@olsen: disabled feature
}
*/
//@olsen: disabled feature
/*
//^olsen: caches -> int[] ?
if (caches != null && caches.size() > 0) {
// Generate fetch/dirty cache initializers
Insn initInsn = null;
//^olsen: optimize traversal ?
for (int i = 0; i < caches.size(); i++) {
int slot = ((Integer) caches.elementAt(i)).intValue();
Insn nullInsn = Insn.create(opc_aconst_null);
if (initInsn == null)
initInsn = nullInsn;
else
initInsn.append(nullInsn);
initInsn.append(InsnUtils.aStore(slot, pool));
}
// These initializations must not occur in an
// exception handler or the code may fail to verify. If an
// exception handler starts at offset 0, our initializations
// will fall into the exception handler block. For
// simplicity, just add a new target as the initial
// instruction - it doesn't cost anything in the
// generated code.
InsnTarget newFirstInsn = new InsnTarget();
initInsn.append(firstInsn);
newFirstInsn.append(initInsn);
firstInsn = newFirstInsn;
codeAttr.setTheCode(firstInsn);
}
*/
if (annotationStack > 0)
codeAttr.setStackUsed(codeAttr.stackUsed() + annotationStack);
}
// ---------------------------------------------------------------------------
/**
* If dirtyThis or fetchThis is set, remove flags indicating the need to
* fetch or dirth "this" on individual instructions.
*/
//@olsen: disabled feature
/*
private void clearThisAnnotation() {
// If the user has disabled "this" optimization, simply turn the
// dirtyThis and fetchThis flags off unless this is an initializer
// method, in which case we defer reseting the flags until the end
// of this method.
if (!env.doThisOptimization() && !methodIsInitializer()) {
dirtyThis = false;
fetchThis = false;
}
if (!dirtyThis && !fetchThis)
return;
final CodeAttribute codeAttr = method.codeAttribute();
if (codeAttr != null) {
for (Insn insn = codeAttr.theCode();
insn != null;
insn = insn.next()) {
for (InsnNote note = getNoteList(insn);
note != null;
note = note.next()) {
if (dirtyThis && note.dirtyThis())
note.dontDirtyThis();
if ((dirtyThis || fetchThis) && note.fetchThis())
note.dontFetchThis();
}
}
}
if (methodIsInitializer()) {
dirtyThis = false;
fetchThis = false;
}
}
*/
/**
* Optimize out obviously redundant fetch(this) and dirty(this)
* annotations. These are repeated fetches and dirties which occur
* in straight-line code with no intervening branch targets or
* method calls.
*/
//@olsen: disabled feature
/*
private void removeRedundantThisAnnotation() {
// This optimization doesn't apply to static methods or initializers.
// Static methods are ignored because they don't have a "this" and
// initializers may be excluded if we expect that there are no
// fetch/dirty of "this".
if (method.isStatic() ||
(methodIsInitializer() && env.doInitializerOptimization()))
return;
CodeAttribute codeAttr = method.codeAttribute();
if (codeAttr != null && needsAnnotation()) {
Insn firstInsn = codeAttr.theCode();
// First instruction is a target
Insn insn = firstInsn.next();
boolean thisFetched = false;
boolean thisDirtied = false;
while (insn != null) {
for (InsnNote note = getNoteList(insn);
note != null;
note = note.next()) {
if (note.fetchThis()) {
if (thisFetched)
note.dontFetchThis();
else
thisFetched = true;
}
if (note.dirtyThis()) {
if (thisDirtied)
note.dontDirtyThis();
else {
thisDirtied = true;
thisFetched = true;
}
}
}
boolean invalidate = false;
switch(insn.opcode()) {
case opc_jsr:
case opc_invokestatic:
case opc_invokespecial:
case opc_invokevirtual:
case opc_invokeinterface:
invalidate = true;
break;
case opc_monitorenter:
// If the code is explicitly synchronizing then the user
// might have some reason to expect instructions to
// interleave against another thread execution in a
// particular order, so invalidate any assumption about
// the fetch/dirty flags
invalidate = true;
break;
case Insn.opc_target:
// targets which result from line-number info, etc. do not
// invalidate the optimization
if (((InsnTarget)insn).isBranchTarget())
invalidate = true;
break;
default:
break;
}
if (invalidate) {
thisFetched = false;
thisDirtied = false;
}
insn = insn.next();
}
}
}
*/
// ---------------------------------------------------------------------------
//^olsen: extend for full support of inheritance on PC classes
//@olsen: reimplemented this method
private void annotateClone(CodeAttribute codeAttr,
String superName) {
if (false) {
final String methodName = method.name().asString();
final String methodSig = method.signature().asString();
System.out.println("annotateClone()");//NOI18N
System.out.println(" methodName = " + methodName);//NOI18N
System.out.println(" methodSig = " + methodSig);//NOI18N
System.out.println(" superName = " + superName);//NOI18N
}
Insn insn;
for (insn = codeAttr.theCode();
insn != null;
insn = insn.next()) {
// Found the clone method. See if it is the flavor of clone()
// which does a super.clone() call, and if it is, add
// field initializations for the jdoStateManager and jdoFlags
// fields.
if (insn.opcode() != opc_invokespecial)
continue;
final InsnConstOp invoke = (InsnConstOp)insn;
final ConstMethodRef methodRef = (ConstMethodRef)invoke.value();
final ConstNameAndType methodNT = methodRef.nameAndType();
final String methodName = methodNT.name().asString();
final String methodSig = methodNT.signature().asString();
if (!(methodName.equals("clone")//NOI18N
&& methodSig.equals("()Ljava/lang/Object;")))//NOI18N
continue;
if (false) {
final ConstClass methodClass = methodRef.className();
final String methodClassName = methodClass.asString();
System.out.println(" found invocation of: "//NOI18N
+ methodClassName
+ "." + methodName + methodSig);//NOI18N
}
// check whether next instruction already is a downcast to a
// class implementing PersistenceCapable
final String thisClass = ca.className();
final Insn checkCastInsn = insn.next();
final boolean needCheckcast;
if (checkCastInsn.opcode() != opc_checkcast) {
needCheckcast = true;
} else {
ConstClass target =
(ConstClass) ((InsnConstOp) checkCastInsn).value();
if (target.asString().equals(thisClass)) {
insn = checkCastInsn;
needCheckcast = false;
} else {
needCheckcast = true;
}
}
// clear jdo fields of clone
{
// duplicate downcastet reference
final Insn newInsn = Insn.create(opc_dup);
if (needCheckcast) {
newInsn.append(Insn.create(opc_checkcast,
pool.addClass(thisClass)));
}
newInsn.append(Insn.create(opc_dup));
// clear jdo fields
newInsn.append(Insn.create(opc_aconst_null));
newInsn.append(Insn.create(
opc_putfield,
pool.addFieldRef(thisClass,
JDOMetaData.JDOStateManagerFieldName,
JDOMetaData.JDOStateManagerFieldSig)));
newInsn.append(Insn.create(opc_iconst_0));
newInsn.append(Insn.create(
opc_putfield,
pool.addFieldRef(thisClass,
JDOMetaData.JDOFlagsFieldName,
JDOMetaData.JDOFlagsFieldSig)));
// insert code
insn.insert(newInsn);
noteStack(3);
}
}
}
//@olsen: disabled feature
/*
private void annotateClone(CodeAttribute codeAttr,
String superName) {
Insn insn;
for (insn = codeAttr.theCode();
insn != null;
insn = insn.next()) {
// Found the clone method. See if it is the flavor of clone()
// which does a super.clone() call, and if it is, add
// field initializations for the jdoStateManager and jdoFlags
// fields.
if (insn.opcode() == opc_invokespecial) {
InsnConstOp invoke = (InsnConstOp) insn;
ConstMethodRef methRef = (ConstMethodRef) invoke.value();
String methName = methRef.nameAndType().name().asString();
if (methName.equals("clone")) {
String thisClass = ca.className();
//@olsen: disabled feature
///
// The following change to the method ref is a
// workaround for the Sun JIT. If there is a
// derived class whose clone() method calls
// super.clone() where the super class's clone()
// was constructed by osjcfp,
// the compiler will generate code which
// calls java.lang.Object.clone() instead of the
// base class's clone (since that's all it can
// see at compile time). It also sets
// (correctly) the ACC_SUPER bit. Unfortunately,
// the JDK JIT will not call the inserted clone
// method, but instead calls the
// java.lang.Object.clone() method. The hackery
// below modifies the invokespecial super.clone()
// call to instead use the osjcfp supplied clone().
// It should be removed if/when the JIT
// is fixed. -cwl 6/27/97
ClassControl cc =
env.findClass(superName).findMethodClass(
"clone", "()Ljava/lang/Object;");
if (cc != null &&
!cc.className().equals(methRef.className().asString())) {
env.message("Changing " + thisClass + ".clone() to call " +
cc.className() + ".clone() instead of " +
methRef.className().asString() + ".clone()");
ConstMethodRef newMethRef =
pool.addMethodRef(cc.className(),
"clone",
"()Ljava/lang/Object;");
invoke.setValue(newMethRef);
}
///
//@olsen: disabled feature
///
boolean needCheckcast = false;
Insn checkCastInsn = insn.next();
if (checkCastInsn.opcode() != opc_checkcast)
needCheckcast = true;
else {
ConstClass target =
(ConstClass) ((InsnConstOp) checkCastInsn).value();
ClassControl targetCC = env.findClass(target.asString());
if (targetCC != null && !targetCC.inherits(thisClass))
needCheckcast = true;
else
insn = checkCastInsn;
}
boolean checkStack = false;
if (ca.getNeedsJDOStateManagerMethods()) {
Insn newInsn = Insn.create(opc_dup);
if (needCheckcast)
newInsn.append(Insn.create(opc_checkcast,
pool.addClass(thisClass)));
newInsn.append(Insn.create(opc_aconst_null));
newInsn.append(Insn.create(
opc_putfield,
pool.addFieldRef(thisClass,
ca.getRefMember(),
JDOStateManagerSig)));
insn.insert(newInsn);
checkStack = true;
}
if (ca.getNeedsJDOFlagsMethods()) {
Insn newInsn = Insn.create(opc_dup);
if (needCheckcast)
newInsn.append(Insn.create(opc_checkcast,
pool.addClass(thisClass)));
newInsn.append(Insn.create(opc_iconst_0));
newInsn.append(Insn.create(opc_putfield,
pool.addFieldRef(thisClass,
ca.getFlagsMember(),
"B")));
insn.insert(newInsn);
checkStack = true;
}
if (checkStack)
noteStack(2);
///
}
}
}
}
*/
// ---------------------------------------------------------------------------
/**
* For a non-static method of a class which implements PersistenceCapable,
* convert the object to a transient object by setting the stateManager
* to null and the object flags to 0. It is assumed that
* the ObjectTable will have already been cleaned up by the
* garbage collector.
*/
//@olsen: disabled feature
/*
private void makeThisTransient(CodeAttribute codeAttr) {
Insn insn = codeAttr.theCode();
while (insn.opcode() == Insn.opc_target)
insn = insn.next();
// Set the statemanager to null
Insn annotation = Insn.create(opc_aload_0);
annotation.append(Insn.create(opc_aconst_null));
ConstInterfaceMethodRef methRef =
pool.addInterfaceMethodRef(JDOPersistenceCapablePath,
"jdoSetStateManager",
"(Lcom/sun/forte4j/persistence/internal/StateManager;)V");
annotation.append(new InsnInterfaceInvoke(methRef, 2));
// Set the object flags to null
annotation.append(Insn.create(opc_aload_0));
annotation.append(Insn.create(opc_iconst_0));
methRef = pool.addInterfaceMethodRef(
JDOPersistenceCapablePath,
"jdoSetFlags",
"(B)V");
annotation.append(new InsnInterfaceInvoke(methRef, 2));
insn.prev().insert(annotation);
if (codeAttr.stackUsed() < 2)
codeAttr.setStackUsed(2);
}
*/
// ---------------------------------------------------------------------------
/**
* Generate annotations if needed for the instruction.
*/
private Insn insnAnnotation(final Insn insn) {
// The note list should be sorted in order of decreasing arg depth
int initialSingleRegs = 0;
//@olsen: ensured to use single note only (as instantiated)
/*
for (InsnNote note = getNoteList(insn);
note != null;
note = note.next()) { ... }
*/
InsnNote note = getNoteList(insn);
if (note == null)
return insn;
//@olsen: ensured to use single note only (as instantiated)
affirm(insn == note.insn);
affirm((note.next() == null),
"Number of annotation notes for instruction > 1.");//NOI18N
//@olsen: not needed to ensure: note.dirtyThis() && !method.isStatic()
final boolean fetch = (note.fetchPersistent() || note.fetchThis());
final boolean dirty = (note.dirtyPersistent() || note.dirtyThis());
//@olsen: added consistency check
affirm((fetch ^ dirty),
"Inconsistent fetch/dirty flags.");//NOI18N
//@olsen: added checks
final boolean dfgField = note.dfgFieldAccess();
final boolean pkField = note.pkFieldAccess();
//@olsen: added println() for debugging
if (false) {
final String targetClassName = note.targetClassName;
final String targetFieldName = note.targetFieldName;
//final String targetPCRootClass = note.targetPCRootClass;
System.out.println(" build annotation: "//NOI18N
+ targetClassName
+ "." + targetFieldName + " : "//NOI18N
+ (pkField ? "pk," : "!pk,")//NOI18N
+ (dfgField ? "dfg," : "!dfg,")//NOI18N
+ (fetch ? "fetch " : "dirty ")//NOI18N
+ (note.fetchPersistent()
? "persistent" : "this")//NOI18N
+ ";");//NOI18N
}
//@olsen: improved control flow
//@olsen: 4385427: do not enhance PK read access at all
if (pkField && fetch) {
return insn;
}
//@olsen: enhance for mediated access
//@olsen: enhance PK write as mediated access
//@olsen: added: mediated getfield/putfield insn annotation
if (pkField || !dfgField) {
//insn.prev().insert(Insn.create(opc_nop));
//@olsen: 4429769: drop putfield instruction on mediated write
// access; isolate the get/putfield instruction to allow
// to now be inserted by buildAccessAnnotation() itself
final Insn prev = insn.prev();
insn.remove();
//@olsen: changed not to return null
final AnnotationFragment frag1 = buildAccessAnnotation(note);
affirm(frag1, "Illegal annotation of PK or non-dfg field.");//NOI18N
//@olsen: 4429769, replace current instruction with fragment
//insn.prev().insert(frag1.annotation);
//noteStack(frag1.stackRequired - note.arg());
//return insn;
final Insn last = prev.insert(frag1.annotation);
noteStack(frag1.stackRequired - note.arg());
return last;
}
// do basic annotation
//@olsen: enhance for non-mediated access
final AnnotationFragment frag0 = buildBasicAnnotation(note);
//@olsen: changed not to return null
affirm(frag0, "Illegal annotation of dfg field.");//NOI18N
//if (frag0 != null) {
{
// Attempt to find an instruction where the argument is known
// to be on the top of stack
StackState state
= new StackState(note.arg(), note.sig(), insn.prev());
minimizeStack(state);
if (false) {
System.out.println(" state.argDepth = "//NOI18N
+ state.argDepth);
System.out.print(" state.insn = ");//NOI18N
state.insn.printInsn(System.out);
System.out.print(" insn = ");//NOI18N
insn.printInsn(System.out);
}
// generate the necessary instructions
Insn annotation = null;
if (state.argDepth == 0) {
// The value is on top of the stack - the dup in the basic
// annotation fragment will suffice
annotation = frag0.annotation;
noteStack(frag0.stackRequired);
} else if (state.argDepth == 1) {
// The value on top of the stack is one deep. Because the
// operand of interest is also a single word value we can
// simply execute a swap operation to get access to the
// operand on top of the stack
annotation = Insn.create(opc_swap);
annotation.append(frag0.annotation);
annotation.append(Insn.create(opc_swap));
// reduce the code fragment's stack requirements by
// the amount that minimizeStack reduced the stack depth,
// since that is the context in which the code fragment
// will run.
noteStack(frag0.stackRequired - (note.arg()-1));
} else {
// The value is hidden by 2 or more stack operands. Move
// the obscuring values into temporaries to get access to
// the value - put them back when done
Stack stackTypes = state.stackTypes;
int depth = state.argDepth;
int elem = stackTypes.size()-1;
int singleRegs = initialSingleRegs;
int doubleRegs = 0;
int regnums[] = new int[depth];
int regtotal = 0;
// Now, move values into temp registers
while (depth > 0) {
int elemType =
((Integer)stackTypes.elementAt(elem--)).intValue();
int elemSize = Descriptor.elementSize(elemType);
depth -= elemSize;
int reg = ((elemSize == 1)
? tmpReg(singleRegs++)
: tmpReg2(doubleRegs++));
regnums[regtotal++] = reg;
Insn store = InsnUtils.store(elemType, reg, pool);
if (annotation == null)
annotation = store;
else
annotation.append(store);
}
affirm((depth >= 0),
"Stack underflow while computing save registers");//NOI18N
annotation.append(frag0.annotation);
while (regtotal > 0)
annotation.append(InsnUtils.load(
((Integer)stackTypes.elementAt(++elem)).intValue(),
regnums[--regtotal], pool));
noteStack(frag0.stackRequired - note.arg());
}
state.insn.insert(annotation);
}
return insn;
}
//@olsen: added method for direct annotation of put/getfield
//@olsen: must not return null
private AnnotationFragment buildAccessAnnotation(final InsnNote note) {
final int requiredStack;
final Insn annotation;
final String targetClassName = note.targetClassName;
final String targetFieldName = note.targetFieldName;
final String targetPCRootClass = note.targetPCRootClass;
//@olsen: not needed to ensure: note.dirtyThis() && !method.isStatic()
final boolean fetch = (note.fetchPersistent() || note.fetchThis());
final boolean dirty = (note.dirtyPersistent() || note.dirtyThis());
//@olsen: added consistency check
affirm((fetch ^ dirty),
"Inconsistent fetch/dirty flags.");//NOI18N
//@olsen: added println() for debugging
if (false) {
final boolean dfgField = note.dfgFieldAccess();
final boolean pkField = note.pkFieldAccess();
System.out.println(" build access annotation: "//NOI18N
+ targetClassName
+ "." + targetFieldName + " : "//NOI18N
+ (pkField ? "pk," : "!pk,")//NOI18N
+ (dfgField ? "dfg," : "!dfg,")//NOI18N
+ (fetch ? "fetch " : "dirty ")//NOI18N
+ (note.fetchPersistent()
? "persistent" : "this")//NOI18N
+ ";");//NOI18N
}
final int argSize = note.arg();
final String fieldSig = note.sig();
final int fieldType = Descriptor.elementType(fieldSig);
final int fieldIndex = note.targetFieldIndex;
if (false) {
System.out.println(" argSize = " + argSize);//NOI18N
System.out.println(" fieldSig = " + fieldSig);//NOI18N
System.out.println(" fieldType = " + fieldType);//NOI18N
System.out.println(" fieldIndex = " + fieldIndex);//NOI18N
}
if (fetch) {
// get jdoStateManager
Insn insn = annotation = Insn.create(opc_dup);
insn = insn.append(
Insn.create(opc_getfield,
pool.addFieldRef(
targetPCRootClass,
JDOMetaData.JDOStateManagerFieldName,
JDOMetaData.JDOStateManagerFieldSig)));
// test jdoStateManager
// load/dirty field if nonnull
InsnTarget fetchDirty = new InsnTarget();
InsnTarget afterFetchDirty = new InsnTarget();
insn = insn.append(Insn.create(opc_dup));
insn = insn.append(
Insn.create(opc_ifnonnull, fetchDirty));
// pop jdoStateManager and skip loading/dirtying
insn = insn.append(Insn.create(opc_pop));
insn = insn.append(
Insn.create(opc_goto, afterFetchDirty));
// invoke StateManager's fetch method
insn = insn.append(fetchDirty);
// push field's unique index onto stack (1st arg)
insn = insn.append(InsnUtils.integerConstant(fieldIndex, pool));
// call stateManager's void prepareGetField(int fieldID) method
requiredStack = 2;
insn = insn.append(
new InsnInterfaceInvoke(
pool.addInterfaceMethodRef(
JDOMetaData.JDOStateManagerPath,
"prepareGetField",//NOI18N
"(I)V"),//NOI18N
requiredStack));
insn = insn.append(afterFetchDirty);
insn = insn.append(note.insn);
} else {
//affirm(dirty);
int singleRegs = 0;
int doubleRegs = 0;
// move current value into temp registers
affirm(argSize > 0);
final int reg = ((argSize == 1)
? tmpReg(singleRegs++)
: tmpReg2(doubleRegs++));
Insn insn = annotation = InsnUtils.store(fieldType, reg, pool);
// get jdoStateManager
insn = insn.append(Insn.create(opc_dup));
insn = insn.append(
Insn.create(opc_getfield,
pool.addFieldRef(
targetPCRootClass,
JDOMetaData.JDOStateManagerFieldName,
JDOMetaData.JDOStateManagerFieldSig)));
// test jdoStateManager
// load/dirty field if nonnull
InsnTarget fetchDirty = new InsnTarget();
InsnTarget afterFetchDirty = new InsnTarget();
insn = insn.append(Insn.create(opc_dup));
insn = insn.append(
Insn.create(opc_ifnonnull, fetchDirty));
// pop jdoStateManager and skip loading/dirtying
insn = insn.append(Insn.create(opc_pop));
// restore value from registers
affirm(argSize > 0);
insn = insn.append(InsnUtils.load(fieldType, reg, pool));
//@olsen: 4429769, insert the original putfield instruction here
insn = insn.append(note.insn);
insn = insn.append(
Insn.create(opc_goto, afterFetchDirty));
// invoke StateManager's load method
insn = insn.append(fetchDirty);
// push field's unique index onto stack (1st arg)
insn = insn.append(InsnUtils.integerConstant(fieldIndex, pool));
// restore value from registers (2nd arg)
affirm(argSize > 0);
insn = insn.append(InsnUtils.load(fieldType, reg, pool));
// call stateManager's setField(index, value) method
switch(fieldType) {
case T_BOOLEAN:
//boolean setBooleanField(int fieldNumber, boolean value);
requiredStack = 3;
insn = insn.append(
new InsnInterfaceInvoke(
pool.addInterfaceMethodRef(
JDOMetaData.JDOStateManagerPath,
"setBooleanField",//NOI18N
"(IB)B"),//NOI18N
requiredStack));
//@olsen: 4429769, disregard object and setField's return value
insn = insn.append(Insn.create(opc_pop2));
break;
case T_CHAR:
//char setCharField(int fieldNumber, char 3);
requiredStack = 3;
insn = insn.append(
new InsnInterfaceInvoke(
pool.addInterfaceMethodRef(
JDOMetaData.JDOStateManagerPath,
"setCharField",//NOI18N
"(IC)C"),//NOI18N
requiredStack));
//@olsen: 4429769, disregard object and setField's return value
insn = insn.append(Insn.create(opc_pop2));
break;
case T_BYTE:
//byte setByteField(int fieldNumber, byte value);
requiredStack = 3;
insn = insn.append(
new InsnInterfaceInvoke(
pool.addInterfaceMethodRef(
JDOMetaData.JDOStateManagerPath,
"setByteField",//NOI18N
"(IZ)Z"),//NOI18N
requiredStack));
//@olsen: 4429769, disregard object and setField's return value
insn = insn.append(Insn.create(opc_pop2));
break;
case T_SHORT:
//short setShortField(int fieldNumber, short value);
requiredStack = 3;
insn = insn.append(
new InsnInterfaceInvoke(
pool.addInterfaceMethodRef(
JDOMetaData.JDOStateManagerPath,
"setShortField",//NOI18N
"(IS)S"),//NOI18N
requiredStack));
//@olsen: 4429769, disregard object and setField's return value
insn = insn.append(Insn.create(opc_pop2));
break;
case T_INT:
//int setIntField(int fieldNumber, int value);
requiredStack = 3;
insn = insn.append(
new InsnInterfaceInvoke(
pool.addInterfaceMethodRef(
JDOMetaData.JDOStateManagerPath,
"setIntField",//NOI18N
"(II)I"),//NOI18N
requiredStack));
//@olsen: 4429769, disregard object and setField's return value
insn = insn.append(Insn.create(opc_pop2));
break;
case T_LONG:
//long setLongField(int fieldNumber, long value);
requiredStack = 4;
insn = insn.append(
new InsnInterfaceInvoke(
pool.addInterfaceMethodRef(
JDOMetaData.JDOStateManagerPath,
"setLongField",//NOI18N
"(IJ)J"),//NOI18N
requiredStack));
//@olsen: 4429769, disregard object and setField's return value
insn = insn.append(Insn.create(opc_pop2));
insn = insn.append(Insn.create(opc_pop));
break;
case T_FLOAT:
//float setFloatField(int fieldNumber, float value);
requiredStack = 3;
insn = insn.append(
new InsnInterfaceInvoke(
pool.addInterfaceMethodRef(
JDOMetaData.JDOStateManagerPath,
"setFloatField",//NOI18N
"(IF)F"),//NOI18N
requiredStack));
//@olsen: 4429769, disregard object and setField's return value
insn = insn.append(Insn.create(opc_pop2));
break;
case T_DOUBLE:
//double setDoubleField(int fieldNumber, double value);
requiredStack = 4;
insn = insn.append(
new InsnInterfaceInvoke(
pool.addInterfaceMethodRef(
JDOMetaData.JDOStateManagerPath,
"setDoubleField",//NOI18N
"(ID)D"),//NOI18N
requiredStack));
//@olsen: 4429769, disregard object and setField's return value
insn = insn.append(Insn.create(opc_pop2));
insn = insn.append(Insn.create(opc_pop));
break;
case TC_OBJECT:
case TC_INTERFACE:
//Object setObjectField(int fieldNumber, Object value);
requiredStack = 3;
insn = insn.append(
new InsnInterfaceInvoke(
pool.addInterfaceMethodRef(
JDOMetaData.JDOStateManagerPath,
"setObjectField",//NOI18N
"(ILjava/lang/Object;)Ljava/lang/Object;"),//NOI18N
requiredStack));
//@olsen: 4429769, no need to downcast anymore
/*
// add a down-cast to the field's type
affirm((fieldSig.charAt(0) == 'L'
&& fieldSig.charAt(fieldSig.length() - 1) == ';'),
"Inconsistent field signature");//NOI18N
final String fieldTypeClassName
= fieldSig.substring(1, fieldSig.length() - 1);
final ConstClass fieldTypeConstClass
= pool.addClass(fieldTypeClassName);
insn = insn.append(
Insn.create(opc_checkcast, fieldTypeConstClass));
*/
//@olsen: 4429769, disregard object and setField's return value
insn = insn.append(Insn.create(opc_pop2));
break;
default:
throw new InternalError("Unexpected field type");//NOI18N
}
insn = insn.append(afterFetchDirty);
}
//@olsen: added println() for debugging
if (false) {
System.out.println(" built annotation, "//NOI18N
+ "required stack = "//NOI18N
+ requiredStack);
}
return new AnnotationFragment(annotation, requiredStack);
}
/**
* Assuming that an object reference is on the top of stack,
* generate an instruction sequence to perform the annotation
* indicated by the note.
*/
//@olsen: must not return null
private AnnotationFragment buildBasicAnnotation(InsnNote note) {
int requiredStack = 2;
Insn basicAnnotation = null;
//@olsen: changed to use JDOMetaData
final String targetClassName = note.targetClassName;
final String targetFieldName = note.targetFieldName;
final String targetPCRootClass = note.targetPCRootClass;
//@olsen: not needed to ensure: note.dirtyThis() && !method.isStatic()
final boolean fetch = (note.fetchPersistent() || note.fetchThis());
final boolean dirty = (note.dirtyPersistent() || note.dirtyThis());
//@olsen: added consistency check
affirm((fetch ^ dirty),
"Inconsistent fetch/dirty flags.");//NOI18N
//@olsen: added println() for debugging
if (false) {
final boolean dfgField = note.dfgFieldAccess();
final boolean pkField = note.pkFieldAccess();
System.out.println(" build basic annotation: "//NOI18N
+ targetClassName
+ "." + targetFieldName + " : "//NOI18N
+ (pkField ? "pk," : "!pk,")//NOI18N
+ (dfgField ? "dfg," : "!dfg,")//NOI18N
+ (fetch ? "fetch " : "dirty ")//NOI18N
+ (note.fetchPersistent()
? "persistent" : "this")//NOI18N
+ ";");//NOI18N
}
//@olsen: changed code for annotation
{
Insn insn = null;
//requiredStack = 2;
// get jdoFlags
basicAnnotation = insn = Insn.create(opc_dup);
insn = insn.append(
Insn.create(opc_getfield,
pool.addFieldRef(
targetPCRootClass,
JDOMetaData.JDOFlagsFieldName,
JDOMetaData.JDOFlagsFieldSig)));
// test jdoFlags
// skip loading for read if <= 0 / for update if == 0
InsnTarget afterFetchDirty = new InsnTarget();
insn = insn.append(
Insn.create((fetch ? opc_ifle : opc_ifeq),
afterFetchDirty));
// get jdoStateManager
insn = insn.append(Insn.create(opc_dup));
insn = insn.append(
Insn.create(opc_getfield,
pool.addFieldRef(
targetPCRootClass,
JDOMetaData.JDOStateManagerFieldName,
JDOMetaData.JDOStateManagerFieldSig)));
// invoke StateManager's load method
insn = insn.append(
new InsnInterfaceInvoke(
pool.addInterfaceMethodRef(
JDOMetaData.JDOStateManagerPath,
(fetch ? "loadForRead" : "loadForUpdate"),//NOI18N
"()V"),//NOI18N
1));
insn = insn.append(afterFetchDirty);
}
//@olsen: added println() for debugging
if (false) {
System.out.println(" built annotation, "//NOI18N
+ "required stack = "//NOI18N
+ requiredStack);
}
return new AnnotationFragment(basicAnnotation, requiredStack);
}
/**
* Assuming that an object reference is on the top of stack,
* generate an instruction sequence to perform the annotation
* indicated by the note.
*/
//@olsen: disabled feature
/*
private AnnotationFragment buildBasicAnnotation(InsnNote note) {
Insn annotation = null; // used?
int requiredStack = 2;
Insn basicAnnotation = null;
//@olsen: disabled feature
///
ConstMethodRef methRef = null;
InsnTarget afterFetchDirty = null;
Insn flagsCheckAnnotation = null;
///
//@olsen: disabled feature
///
ClassAction targetCA = note.targetClassAction();
///
//@olsen: disabled feature
///
// we may need to save the argument in a register for later use
Insn regStore = null;
if (note.getArgReg() >= 0) {
regStore = Insn.create(opc_dup);
regStore.append(InsnUtils.aStore(note.getArgReg(), pool));
}
///
///
if (methRef != null) {
if (flagsCheckAnnotation == null) {
basicAnnotation = Insn.create(opc_dup);
basicAnnotation.append(Insn.create(opc_invokestatic, methRef));
} else {
basicAnnotation = flagsCheckAnnotation;
basicAnnotation.append(Insn.create(opc_dup));
basicAnnotation.append(Insn.create(opc_invokestatic, methRef));
basicAnnotation.append(afterFetchDirty);
}
}
///
//@olsen: disabled feature
///
if (note.fetchPersistent() ||
(note.fetchThis() && thisIsPersistent())) {
methRef
= pool.addMethodRef("com/sun/forte4j/persistence/internal/Implementation", "fetch",
"(" + JDOMetaData.JDOPersistenceCapableSig + ")V");
if (targetCA != null) {
targetCA.ensureFlagsMemberValid();
if (targetCA.getFlagsMember() != null) {
ClassControl flagsCC = targetCA.getFlagsMemberClassControl();
flagsCheckAnnotation = Insn.create(opc_dup);
//@olsen: changed to use JDOMetaData
flagsCheckAnnotation.append(
Insn.create(opc_getfield,
pool.addFieldRef(
targetPCRootClass,
JDOMetaData.JDOFlagsFieldName,
JDOMetaData.JDOFlagsFieldSig)));
flagsCheckAnnotation.append(
Insn.create(opc_getfield,
pool.addFieldRef(flagsCC.className(),
targetCA.getFlagsMember(),
"B")));
afterFetchDirty = new InsnTarget();
//@olsen: skip loading for read if <= 0
flagsCheckAnnotation.append(
Insn.create(opc_ifle,
afterFetchDirty));
}
}
} else if (note.dirtyPersistent() ||
(note.dirtyThis() && thisIsPersistent())) {
methRef
= pool.addMethodRef("com/sun/forte4j/persistence/internal/Implementation", "dirty",
"(" + JDOMetaData.JDOPersistenceCapableSig + ")V");
if (targetCA != null) {
targetCA.ensureFlagsMemberValid();
if (targetCA.getFlagsMember() != null) {
ClassControl flagsCC = targetCA.getFlagsMemberClassControl();
flagsCheckAnnotation = Insn.create(opc_dup);
//@olsen: changed to use JDOMetaData
flagsCheckAnnotation.append(
Insn.create(opc_getfield,
pool.addFieldRef(
targetPCRootClass,
JDOMetaData.JDOFlagsFieldName,
JDOMetaData.JDOFlagsFieldSig)));
flagsCheckAnnotation.append(
Insn.create(opc_getfield,
pool.addFieldRef(flagsCC.className(),
targetCA.getFlagsMember(),
"B")));
afterFetchDirty = new InsnTarget();
flagsCheckAnnotation.append(Insn.create(opc_iconst_2));
flagsCheckAnnotation.append(Insn.create(opc_iand));
flagsCheckAnnotation.append(
Insn.create(opc_ifeq,
afterFetchDirty));
// One more word is needed here for the constant
requiredStack = 2;
}
}
} else if (note.fetchArray()) {
String fetchSig =
arrayFetchSignature(env.doArrayElementFetch()
? note.arrayElementType() : 0);
methRef = pool.addMethodRef("com/sun/forte4j/persistence/internal/Implementation", "fetch", fetchSig);
} else if (note.fetchObject()) {
methRef = pool.addMethodRef("com/sun/forte4j/persistence/internal/Implementation", "fetch",
"(Ljava/lang/Object;)V");
} else if (note.dirtyArray()) {
methRef = pool.addMethodRef("com/sun/forte4j/persistence/internal/Implementation", "dirty",
"(Ljava/lang/Object;)V");
} else if (note.dirtyObject()) {
methRef = pool.addMethodRef("com/sun/forte4j/persistence/internal/Implementation", "dirty",
"(Ljava/lang/Object;)V");
}
if (methRef != null) {
if (flagsCheckAnnotation == null) {
basicAnnotation = Insn.create(opc_dup);
basicAnnotation.append(Insn.create(opc_invokestatic, methRef));
} else {
basicAnnotation = flagsCheckAnnotation;
basicAnnotation.append(Insn.create(opc_dup));
basicAnnotation.append(Insn.create(opc_invokestatic, methRef));
basicAnnotation.append(afterFetchDirty);
}
boolean cacheResult = false;
if (env.doArrayOptimization() &&
(note.fetchArray() || note.dirtyArray()) &&
note.inLoop())
cacheResult = true;
if (cacheResult || note.checkNull()) {
// Since this method appears to create a loop of some sort,
// add a cache to remember what array has been fetched
int cacheSlot = 0;
InsnTarget skipTo = new InsnTarget();
// This generally requires at least two words of stack
if (cacheResult)
cacheSlot = newCacheSlot();
Insn skipAnnotation = Insn.create(opc_dup);
if (note.checkNull()) {
// skip cache-check/fetch if null
skipAnnotation.append(Insn.create(opc_ifnull, skipTo));
if (cacheResult)
// we used the dup'd result so dup again
skipAnnotation.append(Insn.create(opc_dup));
}
if (cacheResult) {
skipAnnotation.append(InsnUtils.aLoad(cacheSlot, pool));
skipAnnotation.append(Insn.create(opc_if_acmpeq, skipTo));
}
skipAnnotation.append(basicAnnotation);
if (cacheResult) {
skipAnnotation.append(Insn.create(opc_dup));
skipAnnotation.append(InsnUtils.aStore(cacheSlot, pool));
}
if (requiredStack < 2)
requiredStack = 2;
skipAnnotation.append(skipTo);
basicAnnotation = skipAnnotation;
}
}
///
//@olsen: disabled feature
///
// Put the unconditional store-arg-to-register annotation at the
// front if non-null
if (regStore != null) {
regStore.append(basicAnnotation);
basicAnnotation = regStore;
}
///
if (basicAnnotation != null)
return new AnnotationFragment(basicAnnotation, requiredStack);
return null;
}
*/
/**
* Compute the method signature for a array fetch() method call based
* on the type of array element (as defined in AnnotationConstants
*/
//@olsen: disabled feature
/*
String arrayFetchSignature(int arrayElementType) {
switch (arrayElementType) {
case ArrayTypeBoolean:
return "([Z)V";
case ArrayTypeByte:
return "([B)V";
case ArrayTypeChar:
return "([C)V";
case ArrayTypeShort:
return "([S)V";
case ArrayTypeInt:
return "([I)V";
case ArrayTypeLong:
return "([J)V";
case ArrayTypeFloat:
return "([F)V";
case ArrayTypeDouble:
return "([D)V";
case ArrayTypeObject:
return "([Ljava/lang/Object;)V";
}
// No special matching type - just use the default signature.
return "(Ljava/lang/Object;)V";
}
*/
/**
* Allocate a two word temporary register
* @param idx the index of the temporary register to return. If the
* specified temporary hasn't been allocated, allocated it now.
*/
private int tmpReg2(int idx) {
if (tmpDoubleRegisters == null)
tmpDoubleRegisters = new Vector(3);
// allocated as many 2 register pairs as necessary in order to
// make idx be a valid index
while (tmpDoubleRegisters.size() <= idx) {
final CodeAttribute codeAttr = method.codeAttribute();
final int reg = codeAttr.localsUsed();
tmpDoubleRegisters.addElement(Integer.valueOf(reg));
codeAttr.setLocalsUsed(reg+2);
}
return ((Integer)tmpDoubleRegisters.elementAt(idx)).intValue();
}
/**
* Allocate a one word temporary register
* @param idx the index of the temporary register to return. If the
* specified temporary hasn't been allocated, allocated it now.
*/
private int tmpReg(int idx) {
if (tmpRegisters == null)
tmpRegisters = new Vector(3);
// allocate as many registers as necessary in order to
// make idx be a valid index
while (tmpRegisters.size() <= idx) {
final CodeAttribute codeAttr = method.codeAttribute();
final int reg = codeAttr.localsUsed();
tmpRegisters.addElement(Integer.valueOf(reg));
codeAttr.setLocalsUsed(reg+1);
}
return ((Integer)tmpRegisters.elementAt(idx)).intValue();
}
/**
* Allocate an object fetch/store cache slot
*/
//@olsen: disabled feature
/*
private int newCacheSlot() {
CodeAttribute codeAttr = method.codeAttribute();
int slot = codeAttr.localsUsed();
codeAttr.setLocalsUsed(slot+1);
if (caches == null)
caches = new Vector(3);
caches.addElement(new Integer(slot));
return slot;
}
*/
/**
* Note the following amount of stack used by a single annotation.
*/
private void noteStack(int stk) {
if (stk > annotationStack)
annotationStack = (short)stk;
}
/**
* Is this a non-static method of a persistence-capable class?
*/
//@olsen: disabled feature
/*
private boolean thisIsPersistent() {
return (ca.persistCapable() &&
!method.isStatic());
}
*/
// ---------------------------------------------------------------------------
/**
* Attempt to locate the instruction which deposits to the top of stack
* the 1 word stack argument to currInsn which is argDepth deep on the
* stack (top of stack == 0).
* If unable to determine this with confidence, return null.
*
* Note that this method will not look back past a target.
* Also, the operations performed by the dup2, dup_x1, dup_x2, dup2_x1,
* dup2_x2 instructions are currently not understood by this method so
* we don't attempt to chain back through these instructions.
*/
private Insn findArgDepositer(Insn currInsn, int argDepth) {
Insn depositer = null;
for (Insn i = currInsn.prev(); argDepth >= 0; i = i.prev()) {
// At control flow branch/merge points, abort the search for the
// target operand.
if (i.branches() ||
((i instanceof InsnTarget) && ((InsnTarget)i).isBranchTarget()))
break;
int nArgs = i.nStackArgs();
int nResults = i.nStackResults();
if (argDepth - nResults < 0) {
// This instruction does deposit the value
// For now, don't return depositers other than opc_dup which
// deposit more than one value. These are the
// long/doubleinstructions (which can't be depositing a one
// word value) and the dupX variants
if (nResults > 1 && i.opcode() != opc_dup)
break;
depositer = i;
// consider special cases which may cause us to look further
switch (i.opcode()) {
case opc_dup:
if (argDepth == 0)
// keep going to find the real depositer at a greater depth
argDepth++;
break;
case opc_checkcast:
// keep going to find the real depositer
break;
default:
return i;
}
}
argDepth += (nArgs - nResults);
}
return depositer;
}
/**
* Assume that after the execution of state.insn there is a word on
* the stack which is state.argDepth words deep.
* Scan backwards through the instruction sequence, attempting to
* locate an instruction after which the argument is at a minimal
* depth w.r.t. the top of stack. Update the state to indicate
* progress.
* Note that this method will not look back past a target.
*/
private void minimizeStack(StackState state) {
Insn i = state.insn;
int argDepth = state.argDepth;
Stack argTypesStack = new Stack();
Stack resultTypesStack = new Stack();
Stack stackTypes = new Stack();
copyStack(state.stackTypes, stackTypes);
for (; argDepth > 0; i = i.prev()) {
// At control flow branch/merge points, abort the search for the
// target operand. The caller will have to make do with the best
// stack state computed thus far.
if (i.branches() ||
((i instanceof InsnTarget)
&& ((InsnTarget)i).isBranchTarget()))
break;
int nArgs = i.nStackArgs();
int nResults = i.nStackResults();
String argTypes = i.argTypes();
String resultTypes = i.resultTypes();
argDepth -= nResults;
// If the target argument was placed there by an instruction which
// deposited multiple results (one of the dup type instructions)
// then we don't have the smarts to figure out where it came from
// so just quit looking
if (argDepth < 0)
break;
argDepth += nArgs;
if (i.opcode() == opc_swap) {
Object x = stackTypes.pop();
Object y = stackTypes.pop();
stackTypes.push(x);
stackTypes.push(y);
} else {
// Make sure the arg types and result types stacks are empty
while (!argTypesStack.empty()) argTypesStack.pop();
while (!resultTypesStack.empty()) resultTypesStack.pop();
Descriptor.computeStackTypes(argTypes, argTypesStack);
Descriptor.computeStackTypes(resultTypes, resultTypesStack);
int expectWords = 0;
while (!resultTypesStack.empty())
expectWords += Descriptor.elementSize(
((Integer) resultTypesStack.pop()).intValue());
while (expectWords > 0)
expectWords -= Descriptor.elementSize(
((Integer) stackTypes.pop()).intValue());
if (expectWords < 0) {
// perhaps we ought to signal an exception, but returning
// will keep things going just fine.
return;
}
transferStackArgs(argTypesStack, stackTypes);
}
if (argDepth >= 0 && argDepth < state.argDepth &&
knownTypes(stackTypes, argDepth)) {
state.argDepth = argDepth;
state.insn = i.prev();
copyStack(stackTypes, state.stackTypes);
}
}
}
/* Take all stack elements in fromStack and push them onto toStack
* such that they are in the same relative stack positions */
private final void transferStackArgs(Stack fromStack, Stack toStack) {
if (!fromStack.empty()) {
Object o = fromStack.pop();
transferStackArgs(fromStack, toStack);
toStack.push(o);
}
}
/* Make toStack look just like fromStack */
private final void copyStack(Stack fromStack, Stack toStack) {
while (!toStack.empty())
toStack.pop();
// take advantage of Stack's inheritance from Vector
for (int i=0; i= 0 && nWords > 0; i--) {
int words = 0;
switch (((Integer)stack.elementAt(i)).intValue()) {
case T_UNKNOWN:
case T_WORD:
case T_TWOWORD:
return false;
case T_BOOLEAN:
case T_CHAR:
case T_FLOAT:
case T_BYTE:
case T_SHORT:
case T_INT:
case TC_OBJECT:
case TC_INTERFACE:
case TC_STRING:
words = 1;
break;
case T_DOUBLE:
case T_LONG:
words = 2;
break;
default:
break;
}
nWords -= words;
}
return true;
}
// ---------------------------------------------------------------------------
/**
* Add a list of notes to the note list.
*/
//@olsen: made final
private final void addNoteList(InsnNote note) {
insnNotes.put(note.insn, note);
}
/**
* Find the note list for the specified instruction.
*/
//@olsen: made final
private final InsnNote getNoteList(Insn insn) {
return (InsnNote)insnNotes.get(insn);
}
}
// ---------------------------------------------------------------------------
/**
* Class loop is a simple class to represent a possible looping construct
* within a method.
*/
//@olsen: disabled feature
/*
class Loop {
int loopStart; // instruction offset - inclusive
int loopEnd; // instruction offset - inclusive
Loop(int lStart, int lEnd) {
loopStart = lStart;
loopEnd = lEnd;
}
*/
/**
* Scan the instructions looking for backward branches which suggests a
* loop structure. If any are found, return a Loop object which
* represents the largest possible loop.
*/
//@olsen: disabled feature
/*
static Loop checkLoops(Insn code) {
// Use 999999 to represent an impossibly large instruction offset
// The current VM design limits methods to 64k of instructions
int loopStart = 999999;
int loopEnd = 0;
for (Insn i = code; i != null; i = i.next()) {
if (i instanceof InsnTargetOp) {
InsnTarget targ = ((InsnTargetOp) i).target();
if (targ.offset() < i.offset()) {
// a backward branch
if (targ.offset() < loopStart)
loopStart = targ.offset();
if (i.offset() > loopEnd)
loopEnd = i.offset();
}
}
}
if (loopStart < loopEnd)
return new Loop(loopStart, loopEnd);
return null;
}
*/
/**
* Is the instruction contained within the loop?
* Note that the instruction must have a valid offset for this
* to answer correctly.
*/
//@olsen: disabled feature
/*
boolean contains(Insn i) {
return i.offset() >= loopStart && i.offset() <= loopEnd;
}
}
*/
// ---------------------------------------------------------------------------
/**
* A structure to record what annotation requirements are implied
* by a particular VM instruction.
*/
class InsnNote
extends Support
implements AnnotationConstants {
//@olsen: made final
final Insn insn;
int insnFlags;
final int argWord;
//@olsen: disabled feature
/*
int argReg = -1;
*/
final String stackSig;
//@olsen: added fields
final String targetClassName;
final String targetFieldName;
final int targetFieldIndex;
final String targetPCRootClass;
//@olsen: disabled feature
/*
final ClassAction targetClassAction;
*/
/**
* Return the next instruction note in this instruction sequence.
* Most instructions need only a single note, but subtypes may need
* to be chained, and should re-implement next().
*/
InsnNote next() {
return null;
}
/**
* Return a descriptor for the current stack state. This descriptor
* is a sequence of VM element type descriptors in decreasing stack
* depth order. That is, the element on the top of stack is the last
* element in the descriptor signature. This descriptor is only
* guaranteed to represent the objects between the instruction stack
* operand (which is offset arg()) deep on the stack and the top of
* stack at the time insn is to be executed. It may however contain
* additional descriptor elements.
*/
final String sig() {
return stackSig;
}
//@olsen: disabled feature
/*
final ClassAction targetClassAction() {
return targetClassAction;
}
*/
/**
* Return the offset from the top of the stack of the argument
*/
final int arg() {
return argWord;
}
final boolean fetchThis() {
return (insnFlags & FetchThis) != 0;
}
//@olsen: disabled feature
/*
final void dontFetchThis() {
insnFlags &= ~FetchThis;
}
*/
final boolean dirtyThis() {
return (insnFlags & DirtyThis) != 0;
}
//@olsen: disabled feature
/*
final void dontDirtyThis() {
insnFlags &= ~DirtyThis;
}
*/
//@olsen: disabled feature
/*
final boolean unconditional() {
return (insnFlags & Unconditional) != 0;
}
*/
//@olsen: disabled feature / not used anymore
/*
final boolean fetchObject() {
return (insnFlags & FetchObject) != 0;
}
final boolean dirtyObject() {
return (insnFlags & DirtyObject) != 0;
}
*/
final boolean fetchPersistent() {
return (insnFlags & FetchPersistent) != 0;
}
final boolean dirtyPersistent() {
return (insnFlags & DirtyPersistent) != 0;
}
//@olsen: added method
final boolean dfgFieldAccess() {
return (insnFlags & DFGField) != 0;
}
//@olsen: added method
final boolean pkFieldAccess() {
return (insnFlags & PKField) != 0;
}
//@olsen: disabled feature
/*
final boolean fetchArray() {
return (insnFlags & FetchArray) != 0;
}
final boolean dirtyArray() {
return (insnFlags & DirtyArray) != 0;
}
final int arrayElementType() {
return insnFlags & ArrayTypeMask;
}
final boolean inLoop() {
return (insnFlags & InLoop) != 0;
}
final boolean checkNull() {
return (insnFlags & CheckNull) != 0;
}
*/
/* If getArgReg returns < 0, the argReg is not set */
//@olsen: disabled feature
/*
final int getArgReg() {
return argReg;
}
final void setArgReg(int reg) {
argReg = reg;
}
*/
/**
* Construct an instruction note.
* @param argWord must be the depth of the word on the stack in
* word units
* @param stackSig a stack descriptor for the stack - see
* the doc for sig().
*/
InsnNote(Insn i, int flags, int argWord,
String stackSig,
String targetClassName,
String targetFieldName,
int targetFieldIndex,
String targetPCRootClass) {
//@olsen: disabled feature
/*
InsnNote(Insn i, int flags, int argWord,
String stackSig, ClassAction targetClassAction) {
*/
insn = i;
insnFlags = flags;
this.stackSig = stackSig;
this.argWord = argWord;
//@olsen: disabled feature
/*
this.targetClassAction = targetClassAction;
*/
this.targetClassName = targetClassName;
this.targetFieldName = targetFieldName;
this.targetFieldIndex = targetFieldIndex;
this.targetPCRootClass = targetPCRootClass;
//@olsen: added consistency check
affirm(!(insn == null
|| argWord < 0
|| targetClassName == null
|| targetFieldName == null
|| targetFieldIndex < 0
|| targetPCRootClass == null),
"Inconsistent instruction annotation note.");//NOI18N
}
}
/**
* A specialized form of instruction note for method invocation arguments.
* The only thing that this adds is a link element to allow multiple notes
* to apply to an instruction.
*/
//@olsen: disabled feature
/*
class InsnArgNote extends InsnNote {
InsnArgNote nextNote;
InsnNote next() {
return nextNote;
}
InsnArgNote(Insn i, int flags, int argWord, String stackSig) {
super(i, flags, argWord, stackSig, null, null);
}
}
*/
// ---------------------------------------------------------------------------
/**
* StackState is really just a simple association of instruction
* and the depth of some stack operand on the operand stack.
*/
class StackState implements VMConstants {
/* number of words deep that the target word is */
int argDepth;
/* Stack of types */
Stack stackTypes;
/* the instruction after which, the word is argDepth deep */
Insn insn;
StackState(int depth, String stackSig, Insn i) {
stackTypes = new Stack();
Descriptor.computeStackTypes(stackSig, stackTypes);
argDepth = depth;
insn = i;
}
}
/**
* AnnotationFragment is really just a simple association of instruction
* and the number of words of stack used during the execution of the
* fragment.
*/
class AnnotationFragment {
Insn annotation;
int stackRequired;
AnnotationFragment(Insn i, int stack) {
annotation = i;
stackRequired = stack;
}
}
// ---------------------------------------------------------------------------
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