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A bundle project producing JAX-RS RI bundles. The primary artifact is an "all-in-one" OSGi-fied JAX-RS RI bundle (jaxrs-ri.jar). Attached to that are two compressed JAX-RS RI archives. The first archive (jaxrs-ri.zip) consists of binary RI bits and contains the API jar (under "api" directory), RI libraries (under "lib" directory) as well as all external RI dependencies (under "ext" directory). The secondary archive (jaxrs-ri-src.zip) contains buildable JAX-RS RI source bundle and contains the API jar (under "api" directory), RI sources (under "src" directory) as well as all external RI dependencies (under "ext" directory). The second archive also contains "build.xml" ANT script that builds the RI sources. To build the JAX-RS RI simply unzip the archive, cd to the created jaxrs-ri directory and invoke "ant" from the command line.

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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
// LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
// CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
// SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
// INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
// CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
// ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF
// THE POSSIBILITY OF SUCH DAMAGE.
package jersey.repackaged.org.objectweb.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; /** * The flags passed to the constructor. Must be zero or more of {@link #COMPUTE_MAXS} and {@link * #COMPUTE_FRAMES}. */ private final int flags; // 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} or {@link Opcodes#ACC_RECORD}, 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 number_of_classes field of the PermittedSubclasses attribute, or 0. */ private int numberOfPermittedSubclasses; /** The 'classes' array of the PermittedSubclasses attribute, or {@literal null}. */ private ByteVector permittedSubclasses; /** * The record components of this class, stored in a linked list of {@link RecordComponentWriter} * linked via their {@link RecordComponentWriter#delegate} field. This field stores the first * element of this list. */ private RecordComponentWriter firstRecordComponent; /** * The record components of this class, stored in a linked list of {@link RecordComponentWriter} * linked via their {@link RecordComponentWriter#delegate} field. This field stores the last * element of this list. */ private RecordComponentWriter lastRecordComponent; /** * 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(/* latest api = */ Opcodes.ASM9); this.flags = flags; symbolTable = classReader == null ? new SymbolTable(this) : new SymbolTable(this, classReader); if ((flags & COMPUTE_FRAMES) != 0) { compute = MethodWriter.COMPUTE_ALL_FRAMES; } else if ((flags & COMPUTE_MAXS) != 0) { compute = MethodWriter.COMPUTE_MAX_STACK_AND_LOCAL; } else { compute = MethodWriter.COMPUTE_NOTHING; } } // ----------------------------------------------------------------------------------------------- // Accessors // ----------------------------------------------------------------------------------------------- /** * Returns true if all the given flags were passed to the constructor. * * @param flags some option flags. Must be zero or more of {@link #COMPUTE_MAXS} and {@link * #COMPUTE_FRAMES}. * @return true if all the given flags, or more, were passed to the constructor. */ public boolean hasFlags(final int flags) { return (this.flags & flags) == flags; } // ----------------------------------------------------------------------------------------------- // 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 final 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) { if (visible) { return lastRuntimeVisibleAnnotation = AnnotationWriter.create(symbolTable, descriptor, lastRuntimeVisibleAnnotation); } else { return lastRuntimeInvisibleAnnotation = AnnotationWriter.create(symbolTable, descriptor, lastRuntimeInvisibleAnnotation); } } @Override public final AnnotationVisitor visitTypeAnnotation( final int typeRef, final TypePath typePath, final String descriptor, final boolean visible) { if (visible) { return lastRuntimeVisibleTypeAnnotation = AnnotationWriter.create( symbolTable, typeRef, typePath, descriptor, lastRuntimeVisibleTypeAnnotation); } else { return lastRuntimeInvisibleTypeAnnotation = AnnotationWriter.create( symbolTable, typeRef, typePath, descriptor, 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 final void visitNestMember(final String nestMember) { if (nestMemberClasses == null) { nestMemberClasses = new ByteVector(); } ++numberOfNestMemberClasses; nestMemberClasses.putShort(symbolTable.addConstantClass(nestMember).index); } @Override public final void visitPermittedSubclass(final String permittedSubclass) { if (permittedSubclasses == null) { permittedSubclasses = new ByteVector(); } ++numberOfPermittedSubclasses; permittedSubclasses.putShort(symbolTable.addConstantClass(permittedSubclass).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 RecordComponentVisitor visitRecordComponent( final String name, final String descriptor, final String signature) { RecordComponentWriter recordComponentWriter = new RecordComponentWriter(symbolTable, name, descriptor, signature); if (firstRecordComponent == null) { firstRecordComponent = recordComponentWriter; } else { lastRecordComponent.delegate = recordComponentWriter; } return lastRecordComponent = recordComponentWriter; } @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() { // 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 (permittedSubclasses != null) { ++attributesCount; size += 8 + permittedSubclasses.length; symbolTable.addConstantUtf8(Constants.PERMITTED_SUBCLASSES); } int recordComponentCount = 0; int recordSize = 0; if ((accessFlags & Opcodes.ACC_RECORD) != 0 || firstRecordComponent != null) { RecordComponentWriter recordComponentWriter = firstRecordComponent; while (recordComponentWriter != null) { ++recordComponentCount; recordSize += recordComponentWriter.computeRecordComponentInfoSize(); recordComponentWriter = (RecordComponentWriter) recordComponentWriter.delegate; } ++attributesCount; size += 8 + recordSize; symbolTable.addConstantUtf8(Constants.RECORD); } 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); } AnnotationWriter.putAnnotations( symbolTable, lastRuntimeVisibleAnnotation, lastRuntimeInvisibleAnnotation, lastRuntimeVisibleTypeAnnotation, lastRuntimeInvisibleTypeAnnotation, 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 (permittedSubclasses != null) { result .putShort(symbolTable.addConstantUtf8(Constants.PERMITTED_SUBCLASSES)) .putInt(permittedSubclasses.length + 2) .putShort(numberOfPermittedSubclasses) .putByteArray(permittedSubclasses.data, 0, permittedSubclasses.length); } if ((accessFlags & Opcodes.ACC_RECORD) != 0 || firstRecordComponent != null) { result .putShort(symbolTable.addConstantUtf8(Constants.RECORD)) .putInt(recordSize + 2) .putShort(recordComponentCount); RecordComponentWriter recordComponentWriter = firstRecordComponent; while (recordComponentWriter != null) { recordComponentWriter.putRecordComponentInfo(result); recordComponentWriter = (RecordComponentWriter) recordComponentWriter.delegate; } } 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; numberOfPermittedSubclasses = 0; permittedSubclasses = null; firstRecordComponent = null; lastRecordComponent = 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; } RecordComponentWriter recordComponentWriter = firstRecordComponent; while (recordComponentWriter != null) { recordComponentWriter.collectAttributePrototypes(attributePrototypes); recordComponentWriter = (RecordComponentWriter) recordComponentWriter.delegate; } 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 (see {@link Type#getInternalName()}). * @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 (see {@link * Type#getInternalName()}). * @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 (see {@link * Type#getInternalName()}). * @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 (see {@link Type#getInternalName()}). * @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 (see {@link * Type#getInternalName()}). * @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 (see {@link Type#getInternalName()}). * @param type2 the internal name of another class (see {@link Type#getInternalName()}). * @return the internal name of the common super class of the two given classes (see {@link * Type#getInternalName()}). */ 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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