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/*
 * Javassist, a Java-bytecode translator toolkit.
 * Copyright (C) 1999- Shigeru Chiba. All Rights Reserved.
 *
 * The contents of this file are subject to the Mozilla Public License Version
 * 1.1 (the "License"); you may not use this file except in compliance with
 * the License.  Alternatively, the contents of this file may be used under
 * the terms of the GNU Lesser General Public License Version 2.1 or later,
 * or the Apache License Version 2.0.
 *
 * Software distributed under the License is distributed on an "AS IS" basis,
 * WITHOUT WARRANTY OF ANY KIND, either express or implied. See the License
 * for the specific language governing rights and limitations under the
 * License.
 */

package javassist;

import javassist.bytecode.*;
import javassist.convert.*;

/**
 * Simple translator of method bodies
 * (also see the javassist.expr package).
 *
 * 

Instances of this class specifies how to instrument of the * bytecodes representing a method body. They are passed to * CtClass.instrument() or * CtMethod.instrument() as a parameter. * *

Example: *

 * ClassPool cp = ClassPool.getDefault();
 * CtClass point = cp.get("Point");
 * CtClass singleton = cp.get("Singleton");
 * CtClass client = cp.get("Client");
 * CodeConverter conv = new CodeConverter();
 * conv.replaceNew(point, singleton, "makePoint");
 * client.instrument(conv);
 * 
* *

This program substitutes "Singleton.makePoint()" * for all occurrences of "new Point()" * appearing in methods declared in a Client class. * * @see javassist.CtClass#instrument(CodeConverter) * @see javassist.CtMethod#instrument(CodeConverter) * @see javassist.expr.ExprEditor */ public class CodeConverter { protected Transformer transformers = null; /** * Modify a method body so that instantiation of the specified class * is replaced with a call to the specified static method. For example, * replaceNew(ctPoint, ctSingleton, "createPoint") * (where ctPoint and ctSingleton are * compile-time classes for class Point and class * Singleton, respectively) * replaces all occurrences of: * *

new Point(x, y)
* * in the method body with: * *
Singleton.createPoint(x, y)
* *

This enables to intercept instantiation of Point * and change the samentics. For example, the following * createPoint() implements the singleton pattern: * *

public static Point createPoint(int x, int y) {
     *     if (aPoint == null)
     *         aPoint = new Point(x, y);
     *     return aPoint;
     * }
     * 
* *

The static method call substituted for the original new * expression must be * able to receive the same set of parameters as the original * constructor. If there are multiple constructors with different * parameter types, then there must be multiple static methods * with the same name but different parameter types. * *

The return type of the substituted static method must be * the exactly same as the type of the instantiated class specified by * newClass. * * @param newClass the instantiated class. * @param calledClass the class in which the static method is * declared. * @param calledMethod the name of the static method. */ public void replaceNew(CtClass newClass, CtClass calledClass, String calledMethod) { transformers = new TransformNew(transformers, newClass.getName(), calledClass.getName(), calledMethod); } /** * Modify a method body so that instantiation of the class * specified by oldClass * is replaced with instantiation of another class newClass. * For example, * replaceNew(ctPoint, ctPoint2) * (where ctPoint and ctPoint2 are * compile-time classes for class Point and class * Point2, respectively) * replaces all occurrences of: * *

new Point(x, y)
* * in the method body with: * *
new Point2(x, y)
* *

Note that Point2 must be type-compatible with Point. * It must have the same set of methods, fields, and constructors as the * replaced class. */ public void replaceNew(CtClass oldClass, CtClass newClass) { transformers = new TransformNewClass(transformers, oldClass.getName(), newClass.getName()); } /** * Modify a method body so that field read/write expressions access * a different field from the original one. * *

Note that this method changes only the filed name and the class * declaring the field; the type of the target object does not change. * Therefore, the substituted field must be declared in the same class * or a superclass of the original class. * *

Also, clazz and newClass must specify * the class directly declaring the field. They must not specify * a subclass of that class. * * @param field the originally accessed field. * @param newClass the class declaring the substituted field. * @param newFieldname the name of the substituted field. */ public void redirectFieldAccess(CtField field, CtClass newClass, String newFieldname) { transformers = new TransformFieldAccess(transformers, field, newClass.getName(), newFieldname); } /** * Modify a method body so that an expression reading the specified * field is replaced with a call to the specified static method. * This static method receives the target object of the original * read expression as a parameter. It must return a value of * the same type as the field. * *

For example, the program below * *

Point p = new Point();
     * int newX = p.x + 3;
* *

can be translated into: * *

Point p = new Point();
     * int newX = Accessor.readX(p) + 3;
* *

where * *

public class Accessor {
     *     public static int readX(Object target) { ... }
     * }
* *

The type of the parameter of readX() must * be java.lang.Object independently of the actual * type of target. The return type must be the same * as the field type. * * @param field the field. * @param calledClass the class in which the static method is * declared. * @param calledMethod the name of the static method. */ public void replaceFieldRead(CtField field, CtClass calledClass, String calledMethod) { transformers = new TransformReadField(transformers, field, calledClass.getName(), calledMethod); } /** * Modify a method body so that an expression writing the specified * field is replaced with a call to the specified static method. * This static method receives two parameters: the target object of * the original * write expression and the assigned value. The return type of the * static method is void. * *

For example, the program below * *

Point p = new Point();
     * p.x = 3;
* *

can be translated into: * *

Point p = new Point();
     * Accessor.writeX(3);
* *

where * *

public class Accessor {
     *     public static void writeX(Object target, int value) { ... }
     * }
* *

The type of the first parameter of writeX() must * be java.lang.Object independently of the actual * type of target. The type of the second parameter * is the same as the field type. * * @param field the field. * @param calledClass the class in which the static method is * declared. * @param calledMethod the name of the static method. */ public void replaceFieldWrite(CtField field, CtClass calledClass, String calledMethod) { transformers = new TransformWriteField(transformers, field, calledClass.getName(), calledMethod); } /** * Modify a method body, so that ALL accesses to an array are replaced with * calls to static methods within another class. In the case of reading an * element from the array, this is replaced with a call to a static method with * the array and the index as arguments, the return value is the value read from * the array. If writing to an array, this is replaced with a call to a static * method with the array, index and new value as parameters, the return value of * the static method is void. * *

The calledClass parameter is the class containing the static methods to be used * for array replacement. The names parameter points to an implementation of * ArrayAccessReplacementMethodNames which specifies the names of the method to be * used for access for each type of array. For example reading from an int[] will * require a different method than if writing to an int[], and writing to a long[] * will require a different method than if writing to a byte[]. If the implementation * of ArrayAccessReplacementMethodNames does not contain the name for access for a * type of array, that access is not replaced. * *

A default implementation of ArrayAccessReplacementMethodNames called * DefaultArrayAccessReplacementMethodNames has been provided and is what is used in the * following example. This also assumes that 'foo.ArrayAdvisor' is the name of the * CtClass passed in. * *

If we have the following class: *

class POJO{
     *    int[] ints = new int[]{1, 2, 3, 4, 5};
     *    long[] longs = new int[]{10, 20, 30};
     *    Object objects = new Object[]{true, false};
     *    Integer[] integers = new Integer[]{new Integer(10)};
     * }
     * 
* and this is accessed as: *
POJO p = new POJO();
     * 
     * //Write to int array
     * p.ints[2] = 7;
     * 
     * //Read from int array
     * int i = p.ints[2];
     * 
     * //Write to long array
     * p.longs[2] = 1000L;
     * 
     * //Read from long array
     * long l = p.longs[2];
     * 
     * //Write to Object array
     * p.objects[2] = "Hello";
     * 
     * //Read from Object array
     * Object o = p.objects[2];
     * 
     * //Write to Integer array
     * Integer integer = new Integer(5);
     * p.integers[0] = integer;
     * 
     * //Read from Object array
     * integer = p.integers[0];
     * 
* * Following instrumentation we will have *
POJO p = new POJO();
     * 
     * //Write to int array
     * ArrayAdvisor.arrayWriteInt(p.ints, 2, 7);
     * 
     * //Read from int array
     * int i = ArrayAdvisor.arrayReadInt(p.ints, 2);
     * 
     * //Write to long array
     * ArrayAdvisor.arrayWriteLong(p.longs, 2, 1000L);
     * 
     * //Read from long array
     * long l = ArrayAdvisor.arrayReadLong(p.longs, 2);
     * 
     * //Write to Object array
     * ArrayAdvisor.arrayWriteObject(p.objects, 2, "Hello");
     * 
     * //Read from Object array
     * Object o = ArrayAdvisor.arrayReadObject(p.objects, 2);
     * 
     * //Write to Integer array
     * Integer integer = new Integer(5);
     * ArrayAdvisor.arrayWriteObject(p.integers, 0, integer);
     * 
     * //Read from Object array
     * integer = ArrayAdvisor.arrayWriteObject(p.integers, 0);
     * 
* * @see DefaultArrayAccessReplacementMethodNames * * @param calledClass the class containing the static methods. * @param names contains the names of the methods to replace * the different kinds of array access with. */ public void replaceArrayAccess(CtClass calledClass, ArrayAccessReplacementMethodNames names) throws NotFoundException { transformers = new TransformAccessArrayField(transformers, calledClass.getName(), names); } /** * Modify method invocations in a method body so that a different * method will be invoked. * *

Note that the target object, the parameters, or * the type of invocation * (static method call, interface call, or private method call) * are not modified. Only the method name is changed. The substituted * method must have the same signature that the original one has. * If the original method is a static method, the substituted method * must be static. * * @param origMethod original method * @param substMethod substituted method */ public void redirectMethodCall(CtMethod origMethod, CtMethod substMethod) throws CannotCompileException { String d1 = origMethod.getMethodInfo2().getDescriptor(); String d2 = substMethod.getMethodInfo2().getDescriptor(); if (!d1.equals(d2)) throw new CannotCompileException("signature mismatch: " + substMethod.getLongName()); int mod1 = origMethod.getModifiers(); int mod2 = substMethod.getModifiers(); if (Modifier.isStatic(mod1) != Modifier.isStatic(mod2) || (Modifier.isPrivate(mod1) && !Modifier.isPrivate(mod2)) || origMethod.getDeclaringClass().isInterface() != substMethod.getDeclaringClass().isInterface()) throw new CannotCompileException("invoke-type mismatch " + substMethod.getLongName()); transformers = new TransformCall(transformers, origMethod, substMethod); } /** * Correct invocations to a method that has been renamed. * If a method is renamed, calls to that method must be also * modified so that the method with the new name will be called. * *

The method must be declared in the same class before and * after it is renamed. * *

Note that the target object, the parameters, or * the type of invocation * (static method call, interface call, or private method call) * are not modified. Only the method name is changed. * * @param oldMethodName the old name of the method. * @param newMethod the method with the new name. * @see javassist.CtMethod#setName(String) */ public void redirectMethodCall(String oldMethodName, CtMethod newMethod) throws CannotCompileException { transformers = new TransformCall(transformers, oldMethodName, newMethod); } /** * Insert a call to another method before an existing method call. * That "before" method must be static. The return type must be * void. As parameters, the before method receives * the target object and all the parameters to the originally invoked * method. For example, if the originally invoked method is * move(): * *

class Point {
     *     Point move(int x, int y) { ... }
     * }
* *

Then the before method must be something like this: * *

class Verbose {
     *     static void print(Point target, int x, int y) { ... }
     * }
* *

The CodeConverter would translate bytecode * equivalent to: * *

Point p2 = p.move(x + y, 0);
* *

into the bytecode equivalent to: * *

int tmp1 = x + y;
     * int tmp2 = 0;
     * Verbose.print(p, tmp1, tmp2);
     * Point p2 = p.move(tmp1, tmp2);
* * @param origMethod the method originally invoked. * @param beforeMethod the method invoked before * origMethod. */ public void insertBeforeMethod(CtMethod origMethod, CtMethod beforeMethod) throws CannotCompileException { try { transformers = new TransformBefore(transformers, origMethod, beforeMethod); } catch (NotFoundException e) { throw new CannotCompileException(e); } } /** * Inserts a call to another method after an existing method call. * That "after" method must be static. The return type must be * void. As parameters, the after method receives * the target object and all the parameters to the originally invoked * method. For example, if the originally invoked method is * move(): * *
class Point {
     *     Point move(int x, int y) { ... }
     * }
* *

Then the after method must be something like this: * *

class Verbose {
     *     static void print(Point target, int x, int y) { ... }
     * }
* *

The CodeConverter would translate bytecode * equivalent to: * *

Point p2 = p.move(x + y, 0);
* *

into the bytecode equivalent to: * *

     * int tmp1 = x + y;
     * int tmp2 = 0;
     * Point p2 = p.move(tmp1, tmp2);
     * Verbose.print(p, tmp1, tmp2);
* * @param origMethod the method originally invoked. * @param afterMethod the method invoked after * origMethod. */ public void insertAfterMethod(CtMethod origMethod, CtMethod afterMethod) throws CannotCompileException { try { transformers = new TransformAfter(transformers, origMethod, afterMethod); } catch (NotFoundException e) { throw new CannotCompileException(e); } } /** * Performs code conversion. */ protected void doit(CtClass clazz, MethodInfo minfo, ConstPool cp) throws CannotCompileException { Transformer t; CodeAttribute codeAttr = minfo.getCodeAttribute(); if (codeAttr == null || transformers == null) return; for (t = transformers; t != null; t = t.getNext()) t.initialize(cp, clazz, minfo); CodeIterator iterator = codeAttr.iterator(); while (iterator.hasNext()) { try { int pos = iterator.next(); for (t = transformers; t != null; t = t.getNext()) pos = t.transform(clazz, pos, iterator, cp); } catch (BadBytecode e) { throw new CannotCompileException(e); } } int locals = 0; int stack = 0; for (t = transformers; t != null; t = t.getNext()) { int s = t.extraLocals(); if (s > locals) locals = s; s = t.extraStack(); if (s > stack) stack = s; } for (t = transformers; t != null; t = t.getNext()) t.clean(); if (locals > 0) codeAttr.setMaxLocals(codeAttr.getMaxLocals() + locals); if (stack > 0) codeAttr.setMaxStack(codeAttr.getMaxStack() + stack); try { minfo.rebuildStackMapIf6(clazz.getClassPool(), clazz.getClassFile2()); } catch (BadBytecode b) { throw new CannotCompileException(b.getMessage(), b); } } /** * Interface containing the method names to be used * as array access replacements. * * @author Kabir Khan * @version $Revision: 1.16 $ */ public interface ArrayAccessReplacementMethodNames { /** * Returns the name of a static method with the signature * (Ljava/lang/Object;I)B to replace reading from a byte[]. */ String byteOrBooleanRead(); /** * Returns the name of a static method with the signature * (Ljava/lang/Object;IB)V to replace writing to a byte[]. */ String byteOrBooleanWrite(); /** * @return the name of a static method with the signature * (Ljava/lang/Object;I)C to replace reading from a char[]. */ String charRead(); /** * Returns the name of a static method with the signature * (Ljava/lang/Object;IC)V to replace writing to a byte[]. */ String charWrite(); /** * Returns the name of a static method with the signature * (Ljava/lang/Object;I)D to replace reading from a double[]. */ String doubleRead(); /** * Returns the name of a static method with the signature * (Ljava/lang/Object;ID)V to replace writing to a double[]. */ String doubleWrite(); /** * Returns the name of a static method with the signature * (Ljava/lang/Object;I)F to replace reading from a float[]. */ String floatRead(); /** * Returns the name of a static method with the signature * (Ljava/lang/Object;IF)V to replace writing to a float[]. */ String floatWrite(); /** * Returns the name of a static method with the signature * (Ljava/lang/Object;I)I to replace reading from a int[]. */ String intRead(); /** * Returns the name of a static method with the signature * (Ljava/lang/Object;II)V to replace writing to a int[]. */ String intWrite(); /** * Returns the name of a static method with the signature * (Ljava/lang/Object;I)J to replace reading from a long[]. */ String longRead(); /** * Returns the name of a static method with the signature * (Ljava/lang/Object;IJ)V to replace writing to a long[]. */ String longWrite(); /** * Returns the name of a static method with the signature * (Ljava/lang/Object;I)Ljava/lang/Object; * to replace reading from a Object[] (or any subclass of object). */ String objectRead(); /** * Returns the name of a static method with the signature * (Ljava/lang/Object;ILjava/lang/Object;)V * to replace writing to a Object[] (or any subclass of object). */ String objectWrite(); /** * Returns the name of a static method with the signature * (Ljava/lang/Object;I)S to replace reading from a short[]. */ String shortRead(); /** * Returns the name of a static method with the signature * (Ljava/lang/Object;IS)V to replace writing to a short[]. */ String shortWrite(); } /** * Default implementation of the ArrayAccessReplacementMethodNames * interface giving default values for method names to be used for replacing * accesses to array elements. * * @author Kabir Khan * @version $Revision: 1.16 $ */ public static class DefaultArrayAccessReplacementMethodNames implements ArrayAccessReplacementMethodNames { /** * Returns "arrayReadByteOrBoolean" as the name of the static method with the signature * (Ljava/lang/Object;I)B to replace reading from a byte[]. */ public String byteOrBooleanRead() { return "arrayReadByteOrBoolean"; } /** * Returns "arrayWriteByteOrBoolean" as the name of the static method with the signature * (Ljava/lang/Object;IB)V to replace writing to a byte[]. */ public String byteOrBooleanWrite() { return "arrayWriteByteOrBoolean"; } /** * Returns "arrayReadChar" as the name of the static method with the signature * (Ljava/lang/Object;I)C to replace reading from a char[]. */ public String charRead() { return "arrayReadChar"; } /** * Returns "arrayWriteChar" as the name of the static method with the signature * (Ljava/lang/Object;IC)V to replace writing to a byte[]. */ public String charWrite() { return "arrayWriteChar"; } /** * Returns "arrayReadDouble" as the name of the static method with the signature * (Ljava/lang/Object;I)D to replace reading from a double[]. */ public String doubleRead() { return "arrayReadDouble"; } /** * Returns "arrayWriteDouble" as the name of the static method with the signature * (Ljava/lang/Object;ID)V to replace writing to a double[]. */ public String doubleWrite() { return "arrayWriteDouble"; } /** * Returns "arrayReadFloat" as the name of the static method with the signature * (Ljava/lang/Object;I)F to replace reading from a float[]. */ public String floatRead() { return "arrayReadFloat"; } /** * Returns "arrayWriteFloat" as the name of the static method with the signature * (Ljava/lang/Object;IF)V to replace writing to a float[]. */ public String floatWrite() { return "arrayWriteFloat"; } /** * Returns "arrayReadInt" as the name of the static method with the signature * (Ljava/lang/Object;I)I to replace reading from a int[]. */ public String intRead() { return "arrayReadInt"; } /** * Returns "arrayWriteInt" as the name of the static method with the signature * (Ljava/lang/Object;II)V to replace writing to a int[]. */ public String intWrite() { return "arrayWriteInt"; } /** * Returns "arrayReadLong" as the name of the static method with the signature * (Ljava/lang/Object;I)J to replace reading from a long[]. */ public String longRead() { return "arrayReadLong"; } /** * Returns "arrayWriteLong" as the name of the static method with the signature * (Ljava/lang/Object;IJ)V to replace writing to a long[]. */ public String longWrite() { return "arrayWriteLong"; } /** * Returns "arrayReadObject" as the name of the static method with the signature * (Ljava/lang/Object;I)Ljava/lang/Object; to replace reading from a Object[] (or any subclass of object). */ public String objectRead() { return "arrayReadObject"; } /** * Returns "arrayWriteObject" as the name of the static method with the signature * (Ljava/lang/Object;ILjava/lang/Object;)V to replace writing to a Object[] (or any subclass of object). */ public String objectWrite() { return "arrayWriteObject"; } /** * Returns "arrayReadShort" as the name of the static method with the signature * (Ljava/lang/Object;I)S to replace reading from a short[]. */ public String shortRead() { return "arrayReadShort"; } /** * Returns "arrayWriteShort" as the name of the static method with the signature * (Ljava/lang/Object;IS)V to replace writing to a short[]. */ public String shortWrite() { return "arrayWriteShort"; } } }




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