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// ASM: a very small and fast Java bytecode manipulation framework
// Copyright (c) 2000-2011 INRIA, France Telecom
// All rights reserved.
//
// Redistribution and use in source and binary forms, with or without
// modification, are permitted provided that the following conditions
// are met:
// 1. Redistributions of source code must retain the above copyright
//    notice, this list of conditions and the following disclaimer.
// 2. Redistributions in binary form must reproduce the above copyright
//    notice, this list of conditions and the following disclaimer in the
//    documentation and/or other materials provided with the distribution.
// 3. Neither the name of the copyright holders nor the names of its
//    contributors may be used to endorse or promote products derived from
//    this software without specific prior written permission.
//
// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
// AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
// IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
// ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE
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// THE POSSIBILITY OF SUCH DAMAGE.
package org.mvel2.asm;

/**
 * A {@link ClassVisitor} that generates a corresponding ClassFile structure, as defined in the Java
 * Virtual Machine Specification (JVMS). It can be used alone, to generate a Java class "from
 * scratch", or with one or more {@link ClassReader} and adapter {@link ClassVisitor} to generate a
 * modified class from one or more existing Java classes.
 *
 * @see JVMS 4
 * @author Eric Bruneton
 */
public class ClassWriter extends ClassVisitor {

  /**
   * A flag to automatically compute the maximum stack size and the maximum number of local
   * variables of methods. If this flag is set, then the arguments of the {@link
   * MethodVisitor#visitMaxs} method of the {@link MethodVisitor} returned by the {@link
   * #visitMethod} method will be ignored, and computed automatically from the signature and the
   * bytecode of each method.
   *
   * 

Note: for classes whose version is {@link Opcodes#V1_7} of more, this option requires * valid stack map frames. The maximum stack size is then computed from these frames, and from the * bytecode instructions in between. If stack map frames are not present or must be recomputed, * used {@link #COMPUTE_FRAMES} instead. * * @see #ClassWriter(int) */ public static final int COMPUTE_MAXS = 1; /** * A flag to automatically compute the stack map frames of methods from scratch. If this flag is * set, then the calls to the {@link MethodVisitor#visitFrame} method are ignored, and the stack * map frames are recomputed from the methods bytecode. The arguments of the {@link * MethodVisitor#visitMaxs} method are also ignored and recomputed from the bytecode. In other * words, {@link #COMPUTE_FRAMES} implies {@link #COMPUTE_MAXS}. * * @see #ClassWriter(int) */ public static final int COMPUTE_FRAMES = 2; // Note: fields are ordered as in the ClassFile structure, and those related to attributes are // ordered as in Section 4.7 of the JVMS. /** * The minor_version and major_version fields of the JVMS ClassFile structure. minor_version is * stored in the 16 most significant bits, and major_version in the 16 least significant bits. */ private int version; /** The symbol table for this class (contains the constant_pool and the BootstrapMethods). */ private final SymbolTable symbolTable; /** * The access_flags field of the JVMS ClassFile structure. This field can contain ASM specific * access flags, such as {@link Opcodes#ACC_DEPRECATED}, which are removed when generating the * ClassFile structure. */ private int accessFlags; /** The this_class field of the JVMS ClassFile structure. */ private int thisClass; /** The super_class field of the JVMS ClassFile structure. */ private int superClass; /** The interface_count field of the JVMS ClassFile structure. */ private int interfaceCount; /** The 'interfaces' array of the JVMS ClassFile structure. */ private int[] interfaces; /** * The fields of this class, stored in a linked list of {@link FieldWriter} linked via their * {@link FieldWriter#fv} field. This field stores the first element of this list. */ private FieldWriter firstField; /** * The fields of this class, stored in a linked list of {@link FieldWriter} linked via their * {@link FieldWriter#fv} field. This field stores the last element of this list. */ private FieldWriter lastField; /** * The methods of this class, stored in a linked list of {@link MethodWriter} linked via their * {@link MethodWriter#mv} field. This field stores the first element of this list. */ private MethodWriter firstMethod; /** * The methods of this class, stored in a linked list of {@link MethodWriter} linked via their * {@link MethodWriter#mv} field. This field stores the last element of this list. */ private MethodWriter lastMethod; /** The number_of_classes field of the InnerClasses attribute, or 0. */ private int numberOfInnerClasses; /** The 'classes' array of the InnerClasses attribute, or {@literal null}. */ private ByteVector innerClasses; /** The class_index field of the EnclosingMethod attribute, or 0. */ private int enclosingClassIndex; /** The method_index field of the EnclosingMethod attribute. */ private int enclosingMethodIndex; /** The signature_index field of the Signature attribute, or 0. */ private int signatureIndex; /** The source_file_index field of the SourceFile attribute, or 0. */ private int sourceFileIndex; /** The debug_extension field of the SourceDebugExtension attribute, or {@literal null}. */ private ByteVector debugExtension; /** * The last runtime visible annotation of this class. The previous ones can be accessed with the * {@link AnnotationWriter#previousAnnotation} field. May be {@literal null}. */ private AnnotationWriter lastRuntimeVisibleAnnotation; /** * The last runtime invisible annotation of this class. The previous ones can be accessed with the * {@link AnnotationWriter#previousAnnotation} field. May be {@literal null}. */ private AnnotationWriter lastRuntimeInvisibleAnnotation; /** * The last runtime visible type annotation of this class. The previous ones can be accessed with * the {@link AnnotationWriter#previousAnnotation} field. May be {@literal null}. */ private AnnotationWriter lastRuntimeVisibleTypeAnnotation; /** * The last runtime invisible type annotation of this class. The previous ones can be accessed * with the {@link AnnotationWriter#previousAnnotation} field. May be {@literal null}. */ private AnnotationWriter lastRuntimeInvisibleTypeAnnotation; /** The Module attribute of this class, or {@literal null}. */ private ModuleWriter moduleWriter; /** The host_class_index field of the NestHost attribute, or 0. */ private int nestHostClassIndex; /** The number_of_classes field of the NestMembers attribute, or 0. */ private int numberOfNestMemberClasses; /** The 'classes' array of the NestMembers attribute, or {@literal null}. */ private ByteVector nestMemberClasses; /** * The first non standard attribute of this class. The next ones can be accessed with the {@link * Attribute#nextAttribute} field. May be {@literal null}. * *

WARNING: this list stores the attributes in the reverse order of their visit. * firstAttribute is actually the last attribute visited in {@link #visitAttribute}. The {@link * #toByteArray} method writes the attributes in the order defined by this list, i.e. in the * reverse order specified by the user. */ private Attribute firstAttribute; /** * Indicates what must be automatically computed in {@link MethodWriter}. Must be one of {@link * MethodWriter#COMPUTE_NOTHING}, {@link MethodWriter#COMPUTE_MAX_STACK_AND_LOCAL}, {@link * MethodWriter#COMPUTE_INSERTED_FRAMES}, or {@link MethodWriter#COMPUTE_ALL_FRAMES}. */ private int compute; // ----------------------------------------------------------------------------------------------- // Constructor // ----------------------------------------------------------------------------------------------- /** * Constructs a new {@link ClassWriter} object. * * @param flags option flags that can be used to modify the default behavior of this class. Must * be zero or more of {@link #COMPUTE_MAXS} and {@link #COMPUTE_FRAMES}. */ public ClassWriter(final int flags) { this(null, flags); } /** * Constructs a new {@link ClassWriter} object and enables optimizations for "mostly add" bytecode * transformations. These optimizations are the following: * *

    *
  • The constant pool and bootstrap methods from the original class are copied as is in the * new class, which saves time. New constant pool entries and new bootstrap methods will be * added at the end if necessary, but unused constant pool entries or bootstrap methods * won't be removed. *
  • Methods that are not transformed are copied as is in the new class, directly from the * original class bytecode (i.e. without emitting visit events for all the method * instructions), which saves a lot of time. Untransformed methods are detected by * the fact that the {@link ClassReader} receives {@link MethodVisitor} objects that come * from a {@link ClassWriter} (and not from any other {@link ClassVisitor} instance). *
* * @param classReader the {@link ClassReader} used to read the original class. It will be used to * copy the entire constant pool and bootstrap methods from the original class and also to * copy other fragments of original bytecode where applicable. * @param flags option flags that can be used to modify the default behavior of this class.Must be * zero or more of {@link #COMPUTE_MAXS} and {@link #COMPUTE_FRAMES}. These option flags do * not affect methods that are copied as is in the new class. This means that neither the * maximum stack size nor the stack frames will be computed for these methods. */ public ClassWriter(final ClassReader classReader, final int flags) { super(Opcodes.ASM7); symbolTable = classReader == null ? new SymbolTable(this) : new SymbolTable(this, classReader); if ((flags & COMPUTE_FRAMES) != 0) { this.compute = MethodWriter.COMPUTE_ALL_FRAMES; } else if ((flags & COMPUTE_MAXS) != 0) { this.compute = MethodWriter.COMPUTE_MAX_STACK_AND_LOCAL; } else { this.compute = MethodWriter.COMPUTE_NOTHING; } } // ----------------------------------------------------------------------------------------------- // Implementation of the ClassVisitor abstract class // ----------------------------------------------------------------------------------------------- @Override public final void visit( final int version, final int access, final String name, final String signature, final String superName, final String[] interfaces) { this.version = version; this.accessFlags = access; this.thisClass = symbolTable.setMajorVersionAndClassName(version & 0xFFFF, name); if (signature != null) { this.signatureIndex = symbolTable.addConstantUtf8(signature); } this.superClass = superName == null ? 0 : symbolTable.addConstantClass(superName).index; if (interfaces != null && interfaces.length > 0) { interfaceCount = interfaces.length; this.interfaces = new int[interfaceCount]; for (int i = 0; i < interfaceCount; ++i) { this.interfaces[i] = symbolTable.addConstantClass(interfaces[i]).index; } } if (compute == MethodWriter.COMPUTE_MAX_STACK_AND_LOCAL && (version & 0xFFFF) >= Opcodes.V1_7) { compute = MethodWriter.COMPUTE_MAX_STACK_AND_LOCAL_FROM_FRAMES; } } @Override public final void visitSource(final String file, final String debug) { if (file != null) { sourceFileIndex = symbolTable.addConstantUtf8(file); } if (debug != null) { debugExtension = new ByteVector().encodeUtf8(debug, 0, Integer.MAX_VALUE); } } @Override public final ModuleVisitor visitModule( final String name, final int access, final String version) { return moduleWriter = new ModuleWriter( symbolTable, symbolTable.addConstantModule(name).index, access, version == null ? 0 : symbolTable.addConstantUtf8(version)); } @Override public void visitNestHost(final String nestHost) { nestHostClassIndex = symbolTable.addConstantClass(nestHost).index; } @Override public final void visitOuterClass( final String owner, final String name, final String descriptor) { enclosingClassIndex = symbolTable.addConstantClass(owner).index; if (name != null && descriptor != null) { enclosingMethodIndex = symbolTable.addConstantNameAndType(name, descriptor); } } @Override public final AnnotationVisitor visitAnnotation(final String descriptor, final boolean visible) { // Create a ByteVector to hold an 'annotation' JVMS structure. // See https://docs.oracle.com/javase/specs/jvms/se9/html/jvms-4.html#jvms-4.7.16. ByteVector annotation = new ByteVector(); // Write type_index and reserve space for num_element_value_pairs. annotation.putShort(symbolTable.addConstantUtf8(descriptor)).putShort(0); if (visible) { return lastRuntimeVisibleAnnotation = new AnnotationWriter(symbolTable, annotation, lastRuntimeVisibleAnnotation); } else { return lastRuntimeInvisibleAnnotation = new AnnotationWriter(symbolTable, annotation, lastRuntimeInvisibleAnnotation); } } @Override public final AnnotationVisitor visitTypeAnnotation( final int typeRef, final TypePath typePath, final String descriptor, final boolean visible) { // Create a ByteVector to hold a 'type_annotation' JVMS structure. // See https://docs.oracle.com/javase/specs/jvms/se9/html/jvms-4.html#jvms-4.7.20. ByteVector typeAnnotation = new ByteVector(); // Write target_type, target_info, and target_path. TypeReference.putTarget(typeRef, typeAnnotation); TypePath.put(typePath, typeAnnotation); // Write type_index and reserve space for num_element_value_pairs. typeAnnotation.putShort(symbolTable.addConstantUtf8(descriptor)).putShort(0); if (visible) { return lastRuntimeVisibleTypeAnnotation = new AnnotationWriter(symbolTable, typeAnnotation, lastRuntimeVisibleTypeAnnotation); } else { return lastRuntimeInvisibleTypeAnnotation = new AnnotationWriter(symbolTable, typeAnnotation, lastRuntimeInvisibleTypeAnnotation); } } @Override public final void visitAttribute(final Attribute attribute) { // Store the attributes in the reverse order of their visit by this method. attribute.nextAttribute = firstAttribute; firstAttribute = attribute; } @Override public void visitNestMember(final String nestMember) { if (nestMemberClasses == null) { nestMemberClasses = new ByteVector(); } ++numberOfNestMemberClasses; nestMemberClasses.putShort(symbolTable.addConstantClass(nestMember).index); } @Override public final void visitInnerClass( final String name, final String outerName, final String innerName, final int access) { if (innerClasses == null) { innerClasses = new ByteVector(); } // Section 4.7.6 of the JVMS states "Every CONSTANT_Class_info entry in the constant_pool table // which represents a class or interface C that is not a package member must have exactly one // corresponding entry in the classes array". To avoid duplicates we keep track in the info // field of the Symbol of each CONSTANT_Class_info entry C whether an inner class entry has // already been added for C. If so, we store the index of this inner class entry (plus one) in // the info field. This trick allows duplicate detection in O(1) time. Symbol nameSymbol = symbolTable.addConstantClass(name); if (nameSymbol.info == 0) { ++numberOfInnerClasses; innerClasses.putShort(nameSymbol.index); innerClasses.putShort(outerName == null ? 0 : symbolTable.addConstantClass(outerName).index); innerClasses.putShort(innerName == null ? 0 : symbolTable.addConstantUtf8(innerName)); innerClasses.putShort(access); nameSymbol.info = numberOfInnerClasses; } // Else, compare the inner classes entry nameSymbol.info - 1 with the arguments of this method // and throw an exception if there is a difference? } @Override public final FieldVisitor visitField( final int access, final String name, final String descriptor, final String signature, final Object value) { FieldWriter fieldWriter = new FieldWriter(symbolTable, access, name, descriptor, signature, value); if (firstField == null) { firstField = fieldWriter; } else { lastField.fv = fieldWriter; } return lastField = fieldWriter; } @Override public final MethodVisitor visitMethod( final int access, final String name, final String descriptor, final String signature, final String[] exceptions) { MethodWriter methodWriter = new MethodWriter(symbolTable, access, name, descriptor, signature, exceptions, compute); if (firstMethod == null) { firstMethod = methodWriter; } else { lastMethod.mv = methodWriter; } return lastMethod = methodWriter; } @Override public final void visitEnd() { // Nothing to do. } // ----------------------------------------------------------------------------------------------- // Other public methods // ----------------------------------------------------------------------------------------------- /** * Returns the content of the class file that was built by this ClassWriter. * * @return the binary content of the JVMS ClassFile structure that was built by this ClassWriter. * @throws ClassTooLargeException if the constant pool of the class is too large. * @throws MethodTooLargeException if the Code attribute of a method is too large. */ public byte[] toByteArray() throws ClassTooLargeException, MethodTooLargeException { // First step: compute the size in bytes of the ClassFile structure. // The magic field uses 4 bytes, 10 mandatory fields (minor_version, major_version, // constant_pool_count, access_flags, this_class, super_class, interfaces_count, fields_count, // methods_count and attributes_count) use 2 bytes each, and each interface uses 2 bytes too. int size = 24 + 2 * interfaceCount; int fieldsCount = 0; FieldWriter fieldWriter = firstField; while (fieldWriter != null) { ++fieldsCount; size += fieldWriter.computeFieldInfoSize(); fieldWriter = (FieldWriter) fieldWriter.fv; } int methodsCount = 0; MethodWriter methodWriter = firstMethod; while (methodWriter != null) { ++methodsCount; size += methodWriter.computeMethodInfoSize(); methodWriter = (MethodWriter) methodWriter.mv; } // For ease of reference, we use here the same attribute order as in Section 4.7 of the JVMS. int attributesCount = 0; if (innerClasses != null) { ++attributesCount; size += 8 + innerClasses.length; symbolTable.addConstantUtf8(Constants.INNER_CLASSES); } if (enclosingClassIndex != 0) { ++attributesCount; size += 10; symbolTable.addConstantUtf8(Constants.ENCLOSING_METHOD); } if ((accessFlags & Opcodes.ACC_SYNTHETIC) != 0 && (version & 0xFFFF) < Opcodes.V1_5) { ++attributesCount; size += 6; symbolTable.addConstantUtf8(Constants.SYNTHETIC); } if (signatureIndex != 0) { ++attributesCount; size += 8; symbolTable.addConstantUtf8(Constants.SIGNATURE); } if (sourceFileIndex != 0) { ++attributesCount; size += 8; symbolTable.addConstantUtf8(Constants.SOURCE_FILE); } if (debugExtension != null) { ++attributesCount; size += 6 + debugExtension.length; symbolTable.addConstantUtf8(Constants.SOURCE_DEBUG_EXTENSION); } if ((accessFlags & Opcodes.ACC_DEPRECATED) != 0) { ++attributesCount; size += 6; symbolTable.addConstantUtf8(Constants.DEPRECATED); } if (lastRuntimeVisibleAnnotation != null) { ++attributesCount; size += lastRuntimeVisibleAnnotation.computeAnnotationsSize( Constants.RUNTIME_VISIBLE_ANNOTATIONS); } if (lastRuntimeInvisibleAnnotation != null) { ++attributesCount; size += lastRuntimeInvisibleAnnotation.computeAnnotationsSize( Constants.RUNTIME_INVISIBLE_ANNOTATIONS); } if (lastRuntimeVisibleTypeAnnotation != null) { ++attributesCount; size += lastRuntimeVisibleTypeAnnotation.computeAnnotationsSize( Constants.RUNTIME_VISIBLE_TYPE_ANNOTATIONS); } if (lastRuntimeInvisibleTypeAnnotation != null) { ++attributesCount; size += lastRuntimeInvisibleTypeAnnotation.computeAnnotationsSize( Constants.RUNTIME_INVISIBLE_TYPE_ANNOTATIONS); } if (symbolTable.computeBootstrapMethodsSize() > 0) { ++attributesCount; size += symbolTable.computeBootstrapMethodsSize(); } if (moduleWriter != null) { attributesCount += moduleWriter.getAttributeCount(); size += moduleWriter.computeAttributesSize(); } if (nestHostClassIndex != 0) { ++attributesCount; size += 8; symbolTable.addConstantUtf8(Constants.NEST_HOST); } if (nestMemberClasses != null) { ++attributesCount; size += 8 + nestMemberClasses.length; symbolTable.addConstantUtf8(Constants.NEST_MEMBERS); } if (firstAttribute != null) { attributesCount += firstAttribute.getAttributeCount(); size += firstAttribute.computeAttributesSize(symbolTable); } // IMPORTANT: this must be the last part of the ClassFile size computation, because the previous // statements can add attribute names to the constant pool, thereby changing its size! size += symbolTable.getConstantPoolLength(); int constantPoolCount = symbolTable.getConstantPoolCount(); if (constantPoolCount > 0xFFFF) { throw new ClassTooLargeException(symbolTable.getClassName(), constantPoolCount); } // Second step: allocate a ByteVector of the correct size (in order to avoid any array copy in // dynamic resizes) and fill it with the ClassFile content. ByteVector result = new ByteVector(size); result.putInt(0xCAFEBABE).putInt(version); symbolTable.putConstantPool(result); int mask = (version & 0xFFFF) < Opcodes.V1_5 ? Opcodes.ACC_SYNTHETIC : 0; result.putShort(accessFlags & ~mask).putShort(thisClass).putShort(superClass); result.putShort(interfaceCount); for (int i = 0; i < interfaceCount; ++i) { result.putShort(interfaces[i]); } result.putShort(fieldsCount); fieldWriter = firstField; while (fieldWriter != null) { fieldWriter.putFieldInfo(result); fieldWriter = (FieldWriter) fieldWriter.fv; } result.putShort(methodsCount); boolean hasFrames = false; boolean hasAsmInstructions = false; methodWriter = firstMethod; while (methodWriter != null) { hasFrames |= methodWriter.hasFrames(); hasAsmInstructions |= methodWriter.hasAsmInstructions(); methodWriter.putMethodInfo(result); methodWriter = (MethodWriter) methodWriter.mv; } // For ease of reference, we use here the same attribute order as in Section 4.7 of the JVMS. result.putShort(attributesCount); if (innerClasses != null) { result .putShort(symbolTable.addConstantUtf8(Constants.INNER_CLASSES)) .putInt(innerClasses.length + 2) .putShort(numberOfInnerClasses) .putByteArray(innerClasses.data, 0, innerClasses.length); } if (enclosingClassIndex != 0) { result .putShort(symbolTable.addConstantUtf8(Constants.ENCLOSING_METHOD)) .putInt(4) .putShort(enclosingClassIndex) .putShort(enclosingMethodIndex); } if ((accessFlags & Opcodes.ACC_SYNTHETIC) != 0 && (version & 0xFFFF) < Opcodes.V1_5) { result.putShort(symbolTable.addConstantUtf8(Constants.SYNTHETIC)).putInt(0); } if (signatureIndex != 0) { result .putShort(symbolTable.addConstantUtf8(Constants.SIGNATURE)) .putInt(2) .putShort(signatureIndex); } if (sourceFileIndex != 0) { result .putShort(symbolTable.addConstantUtf8(Constants.SOURCE_FILE)) .putInt(2) .putShort(sourceFileIndex); } if (debugExtension != null) { int length = debugExtension.length; result .putShort(symbolTable.addConstantUtf8(Constants.SOURCE_DEBUG_EXTENSION)) .putInt(length) .putByteArray(debugExtension.data, 0, length); } if ((accessFlags & Opcodes.ACC_DEPRECATED) != 0) { result.putShort(symbolTable.addConstantUtf8(Constants.DEPRECATED)).putInt(0); } if (lastRuntimeVisibleAnnotation != null) { lastRuntimeVisibleAnnotation.putAnnotations( symbolTable.addConstantUtf8(Constants.RUNTIME_VISIBLE_ANNOTATIONS), result); } if (lastRuntimeInvisibleAnnotation != null) { lastRuntimeInvisibleAnnotation.putAnnotations( symbolTable.addConstantUtf8(Constants.RUNTIME_INVISIBLE_ANNOTATIONS), result); } if (lastRuntimeVisibleTypeAnnotation != null) { lastRuntimeVisibleTypeAnnotation.putAnnotations( symbolTable.addConstantUtf8(Constants.RUNTIME_VISIBLE_TYPE_ANNOTATIONS), result); } if (lastRuntimeInvisibleTypeAnnotation != null) { lastRuntimeInvisibleTypeAnnotation.putAnnotations( symbolTable.addConstantUtf8(Constants.RUNTIME_INVISIBLE_TYPE_ANNOTATIONS), result); } symbolTable.putBootstrapMethods(result); if (moduleWriter != null) { moduleWriter.putAttributes(result); } if (nestHostClassIndex != 0) { result .putShort(symbolTable.addConstantUtf8(Constants.NEST_HOST)) .putInt(2) .putShort(nestHostClassIndex); } if (nestMemberClasses != null) { result .putShort(symbolTable.addConstantUtf8(Constants.NEST_MEMBERS)) .putInt(nestMemberClasses.length + 2) .putShort(numberOfNestMemberClasses) .putByteArray(nestMemberClasses.data, 0, nestMemberClasses.length); } if (firstAttribute != null) { firstAttribute.putAttributes(symbolTable, result); } // Third step: replace the ASM specific instructions, if any. if (hasAsmInstructions) { return replaceAsmInstructions(result.data, hasFrames); } else { return result.data; } } /** * Returns the equivalent of the given class file, with the ASM specific instructions replaced * with standard ones. This is done with a ClassReader -> ClassWriter round trip. * * @param classFile a class file containing ASM specific instructions, generated by this * ClassWriter. * @param hasFrames whether there is at least one stack map frames in 'classFile'. * @return an equivalent of 'classFile', with the ASM specific instructions replaced with standard * ones. */ private byte[] replaceAsmInstructions(final byte[] classFile, final boolean hasFrames) { final Attribute[] attributes = getAttributePrototypes(); firstField = null; lastField = null; firstMethod = null; lastMethod = null; lastRuntimeVisibleAnnotation = null; lastRuntimeInvisibleAnnotation = null; lastRuntimeVisibleTypeAnnotation = null; lastRuntimeInvisibleTypeAnnotation = null; moduleWriter = null; nestHostClassIndex = 0; numberOfNestMemberClasses = 0; nestMemberClasses = null; firstAttribute = null; compute = hasFrames ? MethodWriter.COMPUTE_INSERTED_FRAMES : MethodWriter.COMPUTE_NOTHING; new ClassReader(classFile, 0, /* checkClassVersion = */ false) .accept( this, attributes, (hasFrames ? ClassReader.EXPAND_FRAMES : 0) | ClassReader.EXPAND_ASM_INSNS); return toByteArray(); } /** * Returns the prototypes of the attributes used by this class, its fields and its methods. * * @return the prototypes of the attributes used by this class, its fields and its methods. */ private Attribute[] getAttributePrototypes() { Attribute.Set attributePrototypes = new Attribute.Set(); attributePrototypes.addAttributes(firstAttribute); FieldWriter fieldWriter = firstField; while (fieldWriter != null) { fieldWriter.collectAttributePrototypes(attributePrototypes); fieldWriter = (FieldWriter) fieldWriter.fv; } MethodWriter methodWriter = firstMethod; while (methodWriter != null) { methodWriter.collectAttributePrototypes(attributePrototypes); methodWriter = (MethodWriter) methodWriter.mv; } return attributePrototypes.toArray(); } // ----------------------------------------------------------------------------------------------- // Utility methods: constant pool management for Attribute sub classes // ----------------------------------------------------------------------------------------------- /** * Adds a number or string constant to the constant pool of the class being build. Does nothing if * the constant pool already contains a similar item. This method is intended for {@link * Attribute} sub classes, and is normally not needed by class generators or adapters. * * @param value the value of the constant to be added to the constant pool. This parameter must be * an {@link Integer}, a {@link Float}, a {@link Long}, a {@link Double} or a {@link String}. * @return the index of a new or already existing constant item with the given value. */ public int newConst(final Object value) { return symbolTable.addConstant(value).index; } /** * Adds an UTF8 string to the constant pool of the class being build. Does nothing if the constant * pool already contains a similar item. This method is intended for {@link Attribute} sub * classes, and is normally not needed by class generators or adapters. * * @param value the String value. * @return the index of a new or already existing UTF8 item. */ // DontCheck(AbbreviationAsWordInName): can't be renamed (for backward binary compatibility). public int newUTF8(final String value) { return symbolTable.addConstantUtf8(value); } /** * Adds a class reference to the constant pool of the class being build. Does nothing if the * constant pool already contains a similar item. This method is intended for {@link Attribute} * sub classes, and is normally not needed by class generators or adapters. * * @param value the internal name of the class. * @return the index of a new or already existing class reference item. */ public int newClass(final String value) { return symbolTable.addConstantClass(value).index; } /** * Adds a method type reference to the constant pool of the class being build. Does nothing if the * constant pool already contains a similar item. This method is intended for {@link Attribute} * sub classes, and is normally not needed by class generators or adapters. * * @param methodDescriptor method descriptor of the method type. * @return the index of a new or already existing method type reference item. */ public int newMethodType(final String methodDescriptor) { return symbolTable.addConstantMethodType(methodDescriptor).index; } /** * Adds a module reference to the constant pool of the class being build. Does nothing if the * constant pool already contains a similar item. This method is intended for {@link Attribute} * sub classes, and is normally not needed by class generators or adapters. * * @param moduleName name of the module. * @return the index of a new or already existing module reference item. */ public int newModule(final String moduleName) { return symbolTable.addConstantModule(moduleName).index; } /** * Adds a package reference to the constant pool of the class being build. Does nothing if the * constant pool already contains a similar item. This method is intended for {@link Attribute} * sub classes, and is normally not needed by class generators or adapters. * * @param packageName name of the package in its internal form. * @return the index of a new or already existing module reference item. */ public int newPackage(final String packageName) { return symbolTable.addConstantPackage(packageName).index; } /** * Adds a handle to the constant pool of the class being build. Does nothing if the constant pool * already contains a similar item. This method is intended for {@link Attribute} sub classes, * and is normally not needed by class generators or adapters. * * @param tag the kind of this handle. Must be {@link Opcodes#H_GETFIELD}, {@link * Opcodes#H_GETSTATIC}, {@link Opcodes#H_PUTFIELD}, {@link Opcodes#H_PUTSTATIC}, {@link * Opcodes#H_INVOKEVIRTUAL}, {@link Opcodes#H_INVOKESTATIC}, {@link Opcodes#H_INVOKESPECIAL}, * {@link Opcodes#H_NEWINVOKESPECIAL} or {@link Opcodes#H_INVOKEINTERFACE}. * @param owner the internal name of the field or method owner class. * @param name the name of the field or method. * @param descriptor the descriptor of the field or method. * @return the index of a new or already existing method type reference item. * @deprecated this method is superseded by {@link #newHandle(int, String, String, String, * boolean)}. */ @Deprecated public int newHandle( final int tag, final String owner, final String name, final String descriptor) { return newHandle(tag, owner, name, descriptor, tag == Opcodes.H_INVOKEINTERFACE); } /** * Adds a handle to the constant pool of the class being build. Does nothing if the constant pool * already contains a similar item. This method is intended for {@link Attribute} sub classes, * and is normally not needed by class generators or adapters. * * @param tag the kind of this handle. Must be {@link Opcodes#H_GETFIELD}, {@link * Opcodes#H_GETSTATIC}, {@link Opcodes#H_PUTFIELD}, {@link Opcodes#H_PUTSTATIC}, {@link * Opcodes#H_INVOKEVIRTUAL}, {@link Opcodes#H_INVOKESTATIC}, {@link Opcodes#H_INVOKESPECIAL}, * {@link Opcodes#H_NEWINVOKESPECIAL} or {@link Opcodes#H_INVOKEINTERFACE}. * @param owner the internal name of the field or method owner class. * @param name the name of the field or method. * @param descriptor the descriptor of the field or method. * @param isInterface true if the owner is an interface. * @return the index of a new or already existing method type reference item. */ public int newHandle( final int tag, final String owner, final String name, final String descriptor, final boolean isInterface) { return symbolTable.addConstantMethodHandle(tag, owner, name, descriptor, isInterface).index; } /** * Adds a dynamic constant reference to the constant pool of the class being build. Does nothing * if the constant pool already contains a similar item. This method is intended for {@link * Attribute} sub classes, and is normally not needed by class generators or adapters. * * @param name name of the invoked method. * @param descriptor field descriptor of the constant type. * @param bootstrapMethodHandle the bootstrap method. * @param bootstrapMethodArguments the bootstrap method constant arguments. * @return the index of a new or already existing dynamic constant reference item. */ public int newConstantDynamic( final String name, final String descriptor, final Handle bootstrapMethodHandle, final Object... bootstrapMethodArguments) { return symbolTable.addConstantDynamic( name, descriptor, bootstrapMethodHandle, bootstrapMethodArguments) .index; } /** * Adds an invokedynamic reference to the constant pool of the class being build. Does nothing if * the constant pool already contains a similar item. This method is intended for {@link * Attribute} sub classes, and is normally not needed by class generators or adapters. * * @param name name of the invoked method. * @param descriptor descriptor of the invoke method. * @param bootstrapMethodHandle the bootstrap method. * @param bootstrapMethodArguments the bootstrap method constant arguments. * @return the index of a new or already existing invokedynamic reference item. */ public int newInvokeDynamic( final String name, final String descriptor, final Handle bootstrapMethodHandle, final Object... bootstrapMethodArguments) { return symbolTable.addConstantInvokeDynamic( name, descriptor, bootstrapMethodHandle, bootstrapMethodArguments) .index; } /** * Adds a field reference to the constant pool of the class being build. Does nothing if the * constant pool already contains a similar item. This method is intended for {@link Attribute} * sub classes, and is normally not needed by class generators or adapters. * * @param owner the internal name of the field's owner class. * @param name the field's name. * @param descriptor the field's descriptor. * @return the index of a new or already existing field reference item. */ public int newField(final String owner, final String name, final String descriptor) { return symbolTable.addConstantFieldref(owner, name, descriptor).index; } /** * Adds a method reference to the constant pool of the class being build. Does nothing if the * constant pool already contains a similar item. This method is intended for {@link Attribute} * sub classes, and is normally not needed by class generators or adapters. * * @param owner the internal name of the method's owner class. * @param name the method's name. * @param descriptor the method's descriptor. * @param isInterface {@literal true} if {@code owner} is an interface. * @return the index of a new or already existing method reference item. */ public int newMethod( final String owner, final String name, final String descriptor, final boolean isInterface) { return symbolTable.addConstantMethodref(owner, name, descriptor, isInterface).index; } /** * Adds a name and type to the constant pool of the class being build. Does nothing if the * constant pool already contains a similar item. This method is intended for {@link Attribute} * sub classes, and is normally not needed by class generators or adapters. * * @param name a name. * @param descriptor a type descriptor. * @return the index of a new or already existing name and type item. */ public int newNameType(final String name, final String descriptor) { return symbolTable.addConstantNameAndType(name, descriptor); } // ----------------------------------------------------------------------------------------------- // Default method to compute common super classes when computing stack map frames // ----------------------------------------------------------------------------------------------- /** * Returns the common super type of the two given types. The default implementation of this method * loads the two given classes and uses the java.lang.Class methods to find the common * super class. It can be overridden to compute this common super type in other ways, in * particular without actually loading any class, or to take into account the class that is * currently being generated by this ClassWriter, which can of course not be loaded since it is * under construction. * * @param type1 the internal name of a class. * @param type2 the internal name of another class. * @return the internal name of the common super class of the two given classes. */ protected String getCommonSuperClass(final String type1, final String type2) { ClassLoader classLoader = getClassLoader(); Class class1; try { class1 = Class.forName(type1.replace('/', '.'), false, classLoader); } catch (ClassNotFoundException e) { throw new TypeNotPresentException(type1, e); } Class class2; try { class2 = Class.forName(type2.replace('/', '.'), false, classLoader); } catch (ClassNotFoundException e) { throw new TypeNotPresentException(type2, e); } if (class1.isAssignableFrom(class2)) { return type1; } if (class2.isAssignableFrom(class1)) { return type2; } if (class1.isInterface() || class2.isInterface()) { return "java/lang/Object"; } else { do { class1 = class1.getSuperclass(); } while (!class1.isAssignableFrom(class2)); return class1.getName().replace('.', '/'); } } /** * Returns the {@link ClassLoader} to be used by the default implementation of {@link * #getCommonSuperClass(String, String)}, that of this {@link ClassWriter}'s runtime type by * default. * * @return ClassLoader */ protected ClassLoader getClassLoader() { return getClass().getClassLoader(); } }




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