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/*
* ProGuard -- shrinking, optimization, obfuscation, and preverification
* of Java bytecode.
*
* Copyright (c) 2002-2019 Guardsquare NV
*
* This program is free software; you can redistribute it and/or modify it
* under the terms of the GNU General Public License as published by the Free
* Software Foundation; either version 2 of the License, or (at your option)
* any later version.
*
* This program is distributed in the hope that it will be useful, but WITHOUT
* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for
* more details.
*
* You should have received a copy of the GNU General Public License along
* with this program; if not, write to the Free Software Foundation, Inc.,
* 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
*/
package proguard.optimize.peephole;
import proguard.classfile.*;
import proguard.classfile.attribute.visitor.*;
import proguard.classfile.constant.visitor.*;
import proguard.classfile.editor.*;
import proguard.classfile.util.*;
import proguard.classfile.visitor.*;
import proguard.optimize.KeepMarker;
import proguard.optimize.info.*;
import proguard.util.*;
import java.util.*;
/**
* This ClassVisitor inlines the classes that it visits in a given target class,
* whenever possible.
*
* @see RetargetedInnerClassAttributeRemover
* @see TargetClassChanger
* @see ClassReferenceFixer
* @see MemberReferenceFixer
* @see AccessFixer
* @author Eric Lafortune
*/
public class ClassMerger
extends SimplifiedVisitor
implements ClassVisitor,
ConstantVisitor
{
//*
private static final boolean DEBUG = false;
private static final boolean DETAILS = false;
/*/
private static boolean DEBUG = System.getProperty("cm") != null;
private static boolean DETAILS = System.getProperty("cmd") != null;
//*/
private final ProgramClass targetClass;
private final boolean allowAccessModification;
private final boolean mergeInterfacesAggressively;
private final boolean mergeWrapperClasses;
private final ClassVisitor extraClassVisitor;
private final MemberVisitor fieldOptimizationInfoCopier = new FieldOptimizationInfoCopier();
/**
* Creates a new ClassMerger that will merge classes into the given target
* class.
* @param targetClass the class into which all visited
* classes will be merged.
* @param allowAccessModification specifies whether the access modifiers
* of classes can be changed in order to
* merge them.
* @param mergeInterfacesAggressively specifies whether interfaces may
* be merged aggressively.
*/
public ClassMerger(ProgramClass targetClass,
boolean allowAccessModification,
boolean mergeInterfacesAggressively,
boolean mergeWrapperClasses)
{
this(targetClass,
allowAccessModification,
mergeInterfacesAggressively,
mergeWrapperClasses,
null);
}
/**
* Creates a new ClassMerger that will merge classes into the given target
* class.
* @param targetClass the class into which all visited
* classes will be merged.
* @param allowAccessModification specifies whether the access modifiers
* of classes can be changed in order to
* merge them.
* @param mergeInterfacesAggressively specifies whether interfaces may
* be merged aggressively.
* @param extraClassVisitor an optional extra visitor for all
* merged classes.
*/
public ClassMerger(ProgramClass targetClass,
boolean allowAccessModification,
boolean mergeInterfacesAggressively,
boolean mergeWrapperClasses,
ClassVisitor extraClassVisitor)
{
this.targetClass = targetClass;
this.allowAccessModification = allowAccessModification;
this.mergeInterfacesAggressively = mergeInterfacesAggressively;
this.mergeWrapperClasses = mergeWrapperClasses;
this.extraClassVisitor = extraClassVisitor;
}
// Implementations for ClassVisitor.
public void visitProgramClass(ProgramClass programClass)
{
//final String CLASS_NAME = "abc/Def";
//DEBUG = programClass.getName().equals(CLASS_NAME) ||
// targetClass.getName().equals(CLASS_NAME);
// TODO: Remove this when the class merger has stabilized.
// Catch any unexpected exceptions from the actual visiting method.
try
{
visitProgramClass0(programClass);
}
catch (RuntimeException ex)
{
System.err.println("Unexpected error while merging classes:");
System.err.println(" Class = ["+programClass.getName()+"]");
System.err.println(" Target class = ["+targetClass.getName()+"]");
System.err.println(" Exception = ["+ex.getClass().getName()+"] ("+ex.getMessage()+")");
if (DEBUG)
{
programClass.accept(new ClassPrinter());
targetClass.accept(new ClassPrinter());
}
throw ex;
}
}
public void visitProgramClass0(ProgramClass programClass)
{
if (!programClass.equals(targetClass) &&
// Don't merge classes that must be preserved.
!KeepMarker.isKept(programClass) &&
!KeepMarker.isKept(targetClass) &&
// Only merge classes that haven't been retargeted yet.
getTargetClass(programClass) == null &&
getTargetClass(targetClass) == null &&
// Don't merge annotation classes, with all their reflection and
// infinite recursion.
(programClass.getAccessFlags() & ClassConstants.ACC_ANNOTATION) == 0 &&
(!DETAILS || print(programClass, "Version?")) &&
// Only merge classes with equal class versions.
programClass.u4version == targetClass.u4version &&
(!DETAILS || print(programClass, "Package visibility?")) &&
// Only merge classes if we can change the access permissions, or
// if they are in the same package, or
// if they are public and don't contain or invoke package visible
// class members.
(allowAccessModification ||
((programClass.getAccessFlags() &
targetClass.getAccessFlags() &
ClassConstants.ACC_PUBLIC) != 0 &&
!PackageVisibleMemberContainingClassMarker.containsPackageVisibleMembers(programClass) &&
!PackageVisibleMemberInvokingClassMarker.invokesPackageVisibleMembers(programClass)) ||
ClassUtil.internalPackageName(programClass.getName()).equals(
ClassUtil.internalPackageName(targetClass.getName()))) &&
(!DETAILS || print(programClass, "Interface/abstract/single?")) &&
// Only merge two classes or two interfaces or two abstract classes,
// or a single implementation into its interface.
((programClass.getAccessFlags() &
(ClassConstants.ACC_INTERFACE |
ClassConstants.ACC_ABSTRACT)) ==
(targetClass.getAccessFlags() &
(ClassConstants.ACC_INTERFACE |
ClassConstants.ACC_ABSTRACT)) ||
(isOnlySubClass(programClass, targetClass) &&
programClass.getSuperClass() != null &&
(programClass.getSuperClass().equals(targetClass) ||
programClass.getSuperClass().equals(targetClass.getSuperClass())))) &&
(!DETAILS || print(programClass, "Indirect implementation?")) &&
// One class must not implement the other class indirectly.
!indirectlyImplementedInterfaces(programClass).contains(targetClass) &&
!targetClass.extendsOrImplements(programClass) &&
(!DETAILS || print(programClass, "Interfaces same subinterfaces?")) &&
// Interfaces must have exactly the same subinterfaces, not
// counting themselves, to avoid any loops in the interface
// hierarchy.
((programClass.getAccessFlags() & ClassConstants.ACC_INTERFACE) == 0 ||
(targetClass.getAccessFlags() & ClassConstants.ACC_INTERFACE) == 0 ||
subInterfaces(programClass, targetClass).equals(subInterfaces(targetClass, programClass))) &&
(!DETAILS || print(programClass, "Same initialized superclasses?")) &&
// The two classes must have the same superclasses and interfaces
// with static initializers.
sideEffectSuperClasses(programClass).equals(sideEffectSuperClasses(targetClass)) &&
(!DETAILS || print(programClass, "Same instanceofed superclasses?")) &&
// The two classes must have the same superclasses and interfaces
// that are tested with 'instanceof'.
instanceofedSuperClasses(programClass).equals(instanceofedSuperClasses(targetClass)) &&
(!DETAILS || print(programClass, "Same caught superclasses?")) &&
// The two classes must have the same superclasses that are caught
// as exceptions.
caughtSuperClasses(programClass).equals(caughtSuperClasses(targetClass)) &&
(!DETAILS || print(programClass, "Not .classed?")) &&
// The two classes must not both be part of a .class construct.
!(DotClassMarker.isDotClassed(programClass) &&
DotClassMarker.isDotClassed(targetClass)) &&
(!DETAILS || print(programClass, "No clashing fields?")) &&
// The classes must not have clashing fields.
(mergeWrapperClasses ||
!haveAnyIdenticalFields(programClass, targetClass)) &&
(!DETAILS || print(programClass, "No unwanted fields?")) &&
// The two classes must not introduce any unwanted fields.
(mergeWrapperClasses ||
!introducesUnwantedFields(programClass, targetClass) &&
!introducesUnwantedFields(targetClass, programClass)) &&
(!DETAILS || print(programClass, "No shadowed fields?")) &&
// The two classes must not shadow each others fields.
(mergeWrapperClasses ||
!shadowsAnyFields(programClass, targetClass) &&
!shadowsAnyFields(targetClass, programClass)) &&
(!DETAILS || print(programClass, "No clashing methods?")) &&
// The classes must not have clashing methods.
!haveAnyIdenticalMethods(programClass, targetClass) &&
(!DETAILS || print(programClass, "No abstract methods?")) &&
// The classes must not introduce abstract methods, unless
// explicitly allowed.
(mergeInterfacesAggressively ||
(!introducesUnwantedAbstractMethods(programClass, targetClass) &&
!introducesUnwantedAbstractMethods(targetClass, programClass))) &&
(!DETAILS || print(programClass, "No overridden methods?")) &&
// The classes must not override each others concrete methods.
!overridesAnyMethods(programClass, targetClass) &&
!overridesAnyMethods(targetClass, programClass) &&
(!DETAILS || print(programClass, "No shadowed methods?")) &&
// The classes must not shadow each others non-private methods.
!shadowsAnyMethods(programClass, targetClass) &&
!shadowsAnyMethods(targetClass, programClass) &&
(!DETAILS || print(programClass, "No type variables/parameterized types?")) &&
// The two classes must not have a signature attribute as type variables
// and/or parameterized types can not always be merged.
!hasSignatureAttribute(programClass) &&
!hasSignatureAttribute(targetClass) &&
(!DETAILS || print(programClass, "No non-copiable attributes?")) &&
// The class to be merged into the target class must not have
// non-copiable attributes (InnerClass, EnclosingMethod),
// unless it is a synthetic class.
(mergeWrapperClasses ||
(programClass.getAccessFlags() & ClassConstants.ACC_SYNTHETIC) != 0 ||
!hasNonCopiableAttributes(programClass)))
{
// We're not actually merging the classes, but only copying the
// contents from the source class to the target class. We'll
// then let all other classes point to it. The shrinking step
// will finally remove the source class.
if (DEBUG)
{
System.out.println("ClassMerger ["+programClass.getName()+"] -> ["+targetClass.getName()+"]");
System.out.println(" Source interface? ["+((programClass.getAccessFlags() & ClassConstants.ACC_INTERFACE)!=0)+"]");
System.out.println(" Target interface? ["+((targetClass.getAccessFlags() & ClassConstants.ACC_INTERFACE)!=0)+"]");
System.out.println(" Source subclasses ["+programClass.subClasses+"]");
System.out.println(" Target subclasses ["+targetClass.subClasses+"]");
System.out.println(" Source superclass ["+programClass.getSuperClass().getName()+"]");
System.out.println(" Target superclass ["+targetClass.getSuperClass().getName()+"]");
//System.out.println("=== Before ===");
//programClass.accept(new ClassPrinter());
//targetClass.accept(new ClassPrinter());
}
// Combine the access flags.
int targetAccessFlags = targetClass.getAccessFlags();
int sourceAccessFlags = programClass.getAccessFlags();
targetClass.u2accessFlags =
((targetAccessFlags &
sourceAccessFlags) &
(ClassConstants.ACC_INTERFACE |
ClassConstants.ACC_ABSTRACT)) |
((targetAccessFlags |
sourceAccessFlags) &
(ClassConstants.ACC_PUBLIC |
ClassConstants.ACC_SUPER |
ClassConstants.ACC_ANNOTATION |
ClassConstants.ACC_ENUM));
// Copy over the superclass, if it's a non-interface class being
// merged into an interface class.
// However, we're currently never merging in a way that changes the
// superclass.
//if ((programClass.getAccessFlags() & ClassConstants.ACC_INTERFACE) == 0 &&
// (targetClass.getAccessFlags() & ClassConstants.ACC_INTERFACE) != 0)
//{
// targetClass.u2superClass =
// new ConstantAdder(targetClass).addConstant(programClass, programClass.u2superClass);
//}
// Copy over the interfaces that aren't present yet and that
// wouldn't cause loops in the class hierarchy.
// Note that the code shouldn't be iterating over the original
// list at this point. This is why we only add subclasses in
// a separate step.
programClass.interfaceConstantsAccept(
new ExceptClassConstantFilter(targetClass.getName(),
new ImplementedClassConstantFilter(targetClass,
new ImplementingClassConstantFilter(targetClass,
new InterfaceAdder(targetClass)))));
// Copy over the class members.
MemberAdder memberAdder =
new MemberAdder(targetClass, fieldOptimizationInfoCopier);
programClass.fieldsAccept(mergeWrapperClasses ?
new MemberAccessFilter(ClassConstants.ACC_STATIC, 0, memberAdder) :
memberAdder);
programClass.methodsAccept(mergeWrapperClasses ?
new MemberNameFilter(new NotMatcher(new FixedStringMatcher(ClassConstants.METHOD_NAME_INIT)), memberAdder) :
memberAdder);
// Copy over the other attributes.
programClass.attributesAccept(
new AttributeNameFilter(new NotMatcher(
new OrMatcher(new FixedStringMatcher(ClassConstants.ATTR_BootstrapMethods),
new OrMatcher(new FixedStringMatcher(ClassConstants.ATTR_SourceFile),
new OrMatcher(new FixedStringMatcher(ClassConstants.ATTR_InnerClasses),
new FixedStringMatcher(ClassConstants.ATTR_EnclosingMethod))))),
new AttributeAdder(targetClass, true)));
// Update the optimization information of the target class.
ProgramClassOptimizationInfo.getProgramClassOptimizationInfo(targetClass)
.merge(ClassOptimizationInfo.getClassOptimizationInfo(programClass));
// Remember to replace the inlined class by the target class.
setTargetClass(programClass, targetClass);
//if (DEBUG)
//{
// System.out.println("=== After ====");
// targetClass.accept(new ClassPrinter());
//}
// Visit the merged class, if required.
if (extraClassVisitor != null)
{
extraClassVisitor.visitProgramClass(programClass);
}
}
}
public void visitLibraryClass(LibraryClass libraryClass)
{
// Ignore attempts to merge with a library class.
}
private boolean print(ProgramClass programClass, String message)
{
System.out.println("Merge ["+targetClass.getName()+"] <- ["+programClass.getName()+"] "+message);
return true;
}
// Small utility methods.
/**
* Returns whether a given class is the only subclass of another given class.
*/
private boolean isOnlySubClass(Clazz subClass,
ProgramClass clazz)
{
// TODO: The list of subclasses is not up to date.
return clazz.subClasses != null &&
clazz.subClasses.length == 1 &&
clazz.subClasses[0].equals(subClass);
}
/**
* Returns the set of indirectly implemented interfaces.
*/
private Set indirectlyImplementedInterfaces(Clazz clazz)
{
Set set = new HashSet();
ReferencedClassVisitor referencedInterfaceCollector =
new ReferencedClassVisitor(
new ClassHierarchyTraveler(false, false, true, false,
new ClassCollector(set)));
// Visit all superclasses and collect their interfaces.
clazz.superClassConstantAccept(referencedInterfaceCollector);
// Visit all interfaces and collect their interfaces.
clazz.interfaceConstantsAccept(referencedInterfaceCollector);
return set;
}
/**
* Returns the set of interface subclasses, not including the given class.
*/
private Set subInterfaces(Clazz clazz, Clazz exceptClass)
{
Set set = new HashSet();
// Visit all subclasses, collecting the interface classes.
clazz.hierarchyAccept(false, false, false, true,
new ClassAccessFilter(ClassConstants.ACC_INTERFACE, 0,
new ExceptClassesFilter(new Clazz[] { exceptClass },
new ClassCollector(set))));
return set;
}
/**
* Returns the set of superclasses and interfaces that are initialized.
*/
private Set sideEffectSuperClasses(Clazz clazz)
{
Set set = new HashSet();
// Visit all superclasses and interfaces, collecting the ones that have
// static initializers.
clazz.hierarchyAccept(true, true, true, false,
new SideEffectClassFilter(
new ClassCollector(set)));
return set;
}
/**
* Returns the set of superclasses and interfaces that are used in
* 'instanceof' tests.
*/
private Set instanceofedSuperClasses(Clazz clazz)
{
Set set = new HashSet();
// Visit all superclasses and interfaces, collecting the ones that are
// used in an 'instanceof' test.
clazz.hierarchyAccept(true, true, true, false,
new InstanceofClassFilter(
new ClassCollector(set)));
return set;
}
/**
* Returns the set of superclasses that are caught as exceptions.
*/
private Set caughtSuperClasses(Clazz clazz)
{
// Don't bother if this isn't an exception at all.
if (!clazz.extends_(ClassConstants.NAME_JAVA_LANG_THROWABLE))
{
return Collections.EMPTY_SET;
}
// Visit all superclasses, collecting the ones that are caught
// (plus java.lang.Object, in the current implementation).
Set set = new HashSet();
clazz.hierarchyAccept(true, true, false, false,
new CaughtClassFilter(
new ClassCollector(set)));
return set;
}
/**
* Returns whether the given class has a Signature attributes containing
* type variables or parameterized types.
*/
private boolean hasSignatureAttribute(Clazz clazz)
{
AttributeCounter counter = new AttributeCounter();
clazz.attributesAccept(
new AttributeNameFilter(
new FixedStringMatcher(ClassConstants.ATTR_Signature),
counter));
return counter.getCount() > 0;
}
/**
* Returns whether the two given classes have fields with the same
* names and descriptors.
*/
private boolean haveAnyIdenticalFields(Clazz clazz,
Clazz targetClass)
{
MemberCounter counter = new MemberCounter();
// Visit all fields, counting the with the same name and descriptor in
// the target class.
clazz.fieldsAccept(new SimilarMemberVisitor(targetClass, true, false, false, false,
counter));
return counter.getCount() > 0;
}
/**
* Returns whether the given class would introduce any unwanted fields
* in the target class.
*/
private boolean introducesUnwantedFields(Clazz programClass,
ProgramClass targetClass)
{
// It's ok if the target class is never instantiated and does not
// have any subclasses except for maybe the source class.
if (!InstantiationClassMarker.isInstantiated(targetClass) &&
(targetClass.subClasses == null ||
isOnlySubClass(programClass, targetClass)))
{
return false;
}
MemberCounter counter = new MemberCounter();
// Count all non-static fields in the the source class.
programClass.fieldsAccept(new MemberAccessFilter(0, ClassConstants.ACC_STATIC,
counter));
return counter.getCount() > 0;
}
/**
* Returns whether the given class or its subclasses shadow any fields in
* the given target class.
*/
private boolean shadowsAnyFields(Clazz clazz,
Clazz targetClass)
{
MemberCounter counter = new MemberCounter();
// Visit all fields, counting the ones that are shadowing non-private
// fields in the class hierarchy of the target class.
clazz.hierarchyAccept(true, false, false, true,
new AllFieldVisitor(
new SimilarMemberVisitor(targetClass, true, true, true, false,
new MemberAccessFilter(0, ClassConstants.ACC_PRIVATE,
counter))));
return counter.getCount() > 0;
}
/**
* Returns whether the two given classes have class members with the same
* name and descriptor.
*/
private boolean haveAnyIdenticalMethods(Clazz clazz,
Clazz targetClass)
{
MemberCounter counter = new MemberCounter();
// Visit all non-abstract methods, counting the ones that are also
// present in the target class.
clazz.methodsAccept(new MemberAccessFilter(0, ClassConstants.ACC_ABSTRACT,
new SimilarMemberVisitor(targetClass, true, false, false, false,
new MemberAccessFilter(0, ClassConstants.ACC_ABSTRACT,
counter))));
return counter.getCount() > 0;
}
/**
* Returns whether the given class would introduce any abstract methods
* in the target class.
*/
private boolean introducesUnwantedAbstractMethods(Clazz clazz,
ProgramClass targetClass)
{
// It's ok if the target class is already abstract and does not
// have any subclasses except for maybe the source class.
if ((targetClass.getAccessFlags() &
(ClassConstants.ACC_ABSTRACT |
ClassConstants.ACC_INTERFACE)) != 0 &&
(targetClass.subClasses == null ||
isOnlySubClass(clazz, targetClass)))
{
return false;
}
MemberCounter counter = new MemberCounter();
Set targetSet = new HashSet();
// Collect all abstract methods, and similar abstract methods in the
// class hierarchy of the target class.
clazz.methodsAccept(new MemberAccessFilter(ClassConstants.ACC_ABSTRACT, 0,
new MultiMemberVisitor(
counter,
new SimilarMemberVisitor(targetClass, true, true, true, false,
new MemberAccessFilter(ClassConstants.ACC_ABSTRACT, 0,
new MemberCollector(false, true, true, targetSet)))
)));
return targetSet.size() < counter.getCount();
}
/**
* Returns whether the given class overrides any methods in the given
* target class.
*/
private boolean overridesAnyMethods(Clazz clazz,
ProgramClass targetClass)
{
// It's ok if the target class is never instantiated and does
// not have any subclasses except for maybe the source class.
if (!InstantiationClassMarker.isInstantiated(targetClass) &&
(targetClass.subClasses == null ||
isOnlySubClass(clazz, targetClass)))
{
return false;
}
MemberCounter counter = new MemberCounter();
// Visit all non-abstract methods, counting the ones that are
// overriding methods in the class hierarchy of the target class.
clazz.methodsAccept(new MemberAccessFilter(0, ClassConstants.ACC_ABSTRACT,
new InitializerMethodFilter(null,
new SimilarMemberVisitor(targetClass, true, true, false, false,
new MemberAccessFilter(0, ClassConstants.ACC_PRIVATE | ClassConstants.ACC_STATIC | ClassConstants.ACC_ABSTRACT,
counter)))));
return counter.getCount() > 0;
}
/**
* Returns whether the given class or its subclasses have private or
* static methods that shadow any methods in the given target class.
*/
private boolean shadowsAnyMethods(Clazz clazz,
Clazz targetClass)
{
// It's ok if the source class already extends the target class
// or (in practice) vice versa.
if (clazz.extends_(targetClass) ||
targetClass.extends_(clazz))
{
return false;
}
MemberCounter counter = new MemberCounter();
// Visit all methods, counting the ones that are shadowing
// final methods in the class hierarchy of the target class.
clazz.hierarchyAccept(true, false, false, true,
new AllMethodVisitor(
new InitializerMethodFilter(null,
new SimilarMemberVisitor(targetClass, true, true, false, false,
new MemberAccessFilter(ClassConstants.ACC_FINAL, 0,
counter)))));
if (counter.getCount() > 0)
{
return true;
}
// Visit all private methods, counting the ones that are shadowing
// non-private methods in the class hierarchy of the target class.
clazz.hierarchyAccept(true, false, false, true,
new AllMethodVisitor(
new MemberAccessFilter(ClassConstants.ACC_PRIVATE, 0,
new InitializerMethodFilter(null,
new SimilarMemberVisitor(targetClass, true, true, true, false,
new MemberAccessFilter(0, ClassConstants.ACC_PRIVATE,
counter))))));
if (counter.getCount() > 0)
{
return true;
}
// Visit all static methods, counting the ones that are shadowing
// non-private methods in the class hierarchy of the target class.
clazz.hierarchyAccept(true, false, false, true,
new AllMethodVisitor(
new MemberAccessFilter(ClassConstants.ACC_STATIC, 0,
new InitializerMethodFilter(null,
new SimilarMemberVisitor(targetClass, true, true, true, false,
new MemberAccessFilter(0, ClassConstants.ACC_PRIVATE,
counter))))));
return counter.getCount() > 0;
}
/**
* Returns whether the given class has any attributes that can not be copied when
* merging it into another class.
*/
private boolean hasNonCopiableAttributes(Clazz clazz)
{
AttributeCounter counter = new AttributeCounter();
// Copy over the other attributes.
clazz.attributesAccept(
new AttributeNameFilter(
new OrMatcher(new FixedStringMatcher(ClassConstants.ATTR_InnerClasses),
new FixedStringMatcher(ClassConstants.ATTR_EnclosingMethod)),
counter));
return counter.getCount() > 0;
}
public static void setTargetClass(Clazz clazz, Clazz targetClass)
{
ProgramClassOptimizationInfo.getProgramClassOptimizationInfo(clazz).setTargetClass(targetClass);
}
public static Clazz getTargetClass(Clazz clazz)
{
Clazz targetClass = null;
// Return the last target class, if any.
while (true)
{
clazz = ClassOptimizationInfo.getClassOptimizationInfo(clazz).getTargetClass();
if (clazz == null)
{
return targetClass;
}
targetClass = clazz;
}
}
/**
* This MemberVisitor copies field optimization info from copied fields.
*/
private static class FieldOptimizationInfoCopier
extends SimplifiedVisitor
implements MemberVisitor
{
public void visitProgramField(ProgramClass programClass, ProgramField programField)
{
// Copy the optimization info from the field that was just copied.
ProgramField copiedField = (ProgramField)programField.getVisitorInfo();
Object info = copiedField.getVisitorInfo();
programField.setVisitorInfo(info instanceof ProgramFieldOptimizationInfo ?
new ProgramFieldOptimizationInfo((ProgramFieldOptimizationInfo)info) :
info);
}
public void visitProgramMethod(ProgramClass programClass, ProgramMethod programMethod)
{
// Linked methods share their optimization info.
}
}
}