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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 mockit.external.asm4;
import java.io.IOException;
import java.io.InputStream;
import java.util.*;
import java.util.concurrent.*;
import org.jetbrains.annotations.*;
/**
* A Java class parser to make a {@link ClassVisitor} visit an existing class.
* This class parses a byte array conforming to the Java class file format and
* calls the appropriate visit methods of a given class visitor for each field,
* method and bytecode instruction encountered.
*
* @author Eric Bruneton
* @author Eugene Kuleshov
*/
public final class ClassReader {
/**
* True to enable signatures support.
*/
static final boolean SIGNATURES = true;
/**
* True to enable annotations support.
*/
static final boolean ANNOTATIONS = true;
/**
* True to enable stack map frames support.
*/
static final boolean FRAMES = true;
/**
* True to enable JSR_W and GOTO_W support.
*/
static final boolean RESIZE = true;
/**
* Flag to skip method code. If this class is set CODE
* attribute won't be visited. This can be used, for example, to retrieve
* annotations for methods and method parameters.
*/
public static final int SKIP_CODE = 1;
/**
* Flag to skip the debug information in the class. If this flag is set the
* debug information of the class is not visited, i.e. the
* {@link MethodVisitor#visitLocalVariable visitLocalVariable} and
* {@link MethodVisitor#visitLineNumber visitLineNumber} methods will not be
* called.
*/
public static final int SKIP_DEBUG = 2;
/**
* Flag to skip the stack map frames in the class. If this flag is set the
* stack map frames of the class is not visited, i.e. the
* {@link MethodVisitor#visitFrame visitFrame} method will not be called.
* This flag is useful when the {@link ClassWriter#COMPUTE_FRAMES} option is
* used: it avoids visiting frames that will be ignored and recomputed from
* scratch in the class writer.
*/
public static final int SKIP_FRAMES = 4;
/**
* Flag to expand the stack map frames. By default stack map frames are
* visited in their original format (i.e. "expanded" for classes whose
* version is less than V1_6, and "compressed" for the other classes). If
* this flag is set, stack map frames are always visited in expanded format
* (this option adds a decompression/recompression step in ClassReader and
* ClassWriter which degrades performances quite a lot).
*/
public static final int EXPAND_FRAMES = 8;
/**
* The class to be parsed. The content of this array must not be
* modified. This field is intended for {@link Attribute} sub classes, and
* is normally not needed by class generators or adapters.
*/
public final byte[] b;
/**
* The start index of each constant pool item in {@link #b b}, plus one.
* The one byte offset skips the constant pool item tag that indicates its
* type.
*/
private final int[] items;
/**
* The String objects corresponding to the CONSTANT_Utf8 items. This cache
* avoids multiple parsing of a given CONSTANT_Utf8 constant pool item,
* which GREATLY improves performances (by a factor 2 to 3). This caching
* strategy could be extended to all constant pool items, but its benefit
* would not be so great for these items (because they are much less
* expensive to parse than CONSTANT_Utf8 items).
*/
private final String[] strings;
/**
* Maximum length of the strings contained in the constant pool of the
* class.
*/
private final int maxStringLength;
/**
* Start index of the class header information (access, name...) in
* {@link #b b}.
*/
private final int header;
// ------------------------------------------------------------------------
// Constructors
// ------------------------------------------------------------------------
/**
* Constructs a new {@link ClassReader} object.
*
* @param b the bytecode of the class to be read.
*/
public ClassReader(@NotNull final byte[] b) {
this(b, 0, b.length);
}
/**
* Constructs a new {@link ClassReader} object.
*
* @param b the bytecode of the class to be read.
* @param off the start offset of the class data.
* @param len the length of the class data.
*/
public ClassReader(final byte[] b, final int off, final int len) {
this.b = b;
// parses the constant pool
items = new int[readUnsignedShort(off + 8)];
int n = items.length;
strings = new String[n];
int max = 0;
int index = off + 10;
for (int i = 1; i < n; ++i) {
items[i] = index + 1;
int size;
switch (b[index]) {
case ClassWriter.FIELD:
case ClassWriter.METH:
case ClassWriter.IMETH:
case ClassWriter.INT:
case ClassWriter.FLOAT:
case ClassWriter.NAME_TYPE:
case ClassWriter.INDY:
size = 5;
break;
case ClassWriter.LONG:
case ClassWriter.DOUBLE:
size = 9;
++i;
break;
case ClassWriter.UTF8:
size = 3 + readUnsignedShort(index + 1);
if (size > max) {
max = size;
}
break;
case ClassWriter.HANDLE:
size = 4;
break;
// case ClassWriter.CLASS:
// case ClassWriter.STR:
// case ClassWriter.MTYPE
default:
size = 3;
break;
}
index += size;
}
maxStringLength = max;
// the class header information starts just after the constant pool
header = index;
}
/**
* Returns the class's access flags (see {@link Opcodes}). This value may
* not reflect Deprecated and Synthetic flags when bytecode is before 1.5
* and those flags are represented by attributes.
*
* @return the class access flags
*
* @see ClassVisitor#visit(int, int, String, String, String, String[])
*/
public int getAccess() {
return readUnsignedShort(header);
}
/**
* Returns the internal name of the class (see
* {@link Type#getInternalName() getInternalName}).
*
* @return the internal class name
*
* @see ClassVisitor#visit(int, int, String, String, String, String[])
*/
public String getClassName() {
return readClass(header + 2, new char[maxStringLength]);
}
/**
* Returns the internal of name of the super class (see
* {@link Type#getInternalName() getInternalName}). For interfaces, the
* super class is {@link Object}.
*
* @return the internal name of super class, or null for
* {@link Object} class.
*
* @see ClassVisitor#visit(int, int, String, String, String, String[])
*/
public String getSuperName() {
int n = items[readUnsignedShort(header + 4)];
return n == 0 ? null : readUTF8(n, new char[maxStringLength]);
}
/**
* Returns the internal names of the class's interfaces (see
* {@link Type#getInternalName() getInternalName}).
*
* @return the array of internal names for all implemented interfaces or
* null.
*
* @see ClassVisitor#visit(int, int, String, String, String, String[])
*/
public String[] getInterfaces() {
int index = header + 6;
int n = readUnsignedShort(index);
String[] interfaces = new String[n];
if (n > 0) {
char[] buf = new char[maxStringLength];
for (int i = 0; i < n; ++i) {
index += 2;
interfaces[i] = readClass(index, buf);
}
}
return interfaces;
}
/**
* Copies the constant pool data into the given {@link ClassWriter}. Should
* be called before the {@link #accept(ClassVisitor,int)} method.
*
* @param classWriter the {@link ClassWriter} to copy constant pool into.
*/
void copyPool(final ClassWriter classWriter) {
char[] buf = new char[maxStringLength];
int ll = items.length;
Item[] items2 = new Item[ll];
for (int i = 1; i < ll; i++) {
int index = items[i];
int tag = b[index - 1];
Item item = new Item(i);
int nameType;
switch (tag) {
case ClassWriter.FIELD:
case ClassWriter.METH:
case ClassWriter.IMETH:
nameType = items[readUnsignedShort(index + 2)];
item.set(tag,
readClass(index, buf),
readUTF8(nameType, buf),
readUTF8(nameType + 2, buf));
break;
case ClassWriter.INT:
item.set(readInt(index));
break;
case ClassWriter.FLOAT:
item.set(Float.intBitsToFloat(readInt(index)));
break;
case ClassWriter.NAME_TYPE:
item.set(tag,
readUTF8(index, buf),
readUTF8(index + 2, buf),
null);
break;
case ClassWriter.LONG:
item.set(readLong(index));
++i;
break;
case ClassWriter.DOUBLE:
item.set(Double.longBitsToDouble(readLong(index)));
++i;
break;
case ClassWriter.UTF8: {
String s = strings[i];
if (s == null) {
index = items[i];
s = strings[i] = readUTF(index + 2,
readUnsignedShort(index),
buf);
}
item.set(tag, s, null, null);
}
break;
case ClassWriter.HANDLE: {
int fieldOrMethodRef = items[readUnsignedShort(index + 1)];
nameType = items[readUnsignedShort(fieldOrMethodRef + 2)];
item.set(ClassWriter.HANDLE_BASE + readByte(index),
readClass(fieldOrMethodRef, buf),
readUTF8(nameType, buf),
readUTF8(nameType + 2, buf));
}
break;
case ClassWriter.INDY:
if (classWriter.bootstrapMethods == null) {
copyBootstrapMethods(classWriter, items2, buf);
}
nameType = items[readUnsignedShort(index + 2)];
item.set(readUTF8(nameType, buf),
readUTF8(nameType + 2, buf),
readUnsignedShort(index));
break;
// case ClassWriter.STR:
// case ClassWriter.CLASS:
// case ClassWriter.MTYPE
default:
item.set(tag, readUTF8(index, buf), null, null);
break;
}
int index2 = item.hashCode % items2.length;
item.next = items2[index2];
items2[index2] = item;
}
int off = items[1] - 1;
classWriter.pool.putByteArray(b, off, header - off);
classWriter.items = items2;
classWriter.threshold = (int) (0.75d * ll);
classWriter.index = ll;
}
private void copyBootstrapMethods(ClassWriter classWriter, Item[] items2, char[] buf) {
int i, j, k, u, v;
// skip class header
v = header;
v += 8 + (readUnsignedShort(v + 6) << 1);
// skips fields and methods
i = readUnsignedShort(v);
v += 2;
for (; i > 0; --i) {
j = readUnsignedShort(v + 6);
v += 8;
for (; j > 0; --j) {
v += 6 + readInt(v + 2);
}
}
i = readUnsignedShort(v);
v += 2;
for (; i > 0; --i) {
j = readUnsignedShort(v + 6);
v += 8;
for (; j > 0; --j) {
v += 6 + readInt(v + 2);
}
}
// read class attributes
i = readUnsignedShort(v);
v += 2;
for (; i > 0; --i) {
String attrName = readUTF8(v, buf);
int size = readInt(v + 2);
if ("BootstrapMethods".equals(attrName)) {
int boostrapMethodCount = readUnsignedShort(v + 6);
int x = v + 8;
for (j = 0; j < boostrapMethodCount; j++) {
int hashCode = readConst(readUnsignedShort(x), buf).hashCode();
k = readUnsignedShort(x + 2);
u = x + 4;
for(; k > 0; --k) {
hashCode ^= readConst(readUnsignedShort(u), buf).hashCode();
u += 2;
}
Item item = new Item(j);
item.set(x - v - 8, hashCode & 0x7FFFFFFF);
int index2 = item.hashCode % items2.length;
item.next = items2[index2];
items2[index2] = item;
x = u;
}
classWriter.bootstrapMethodsCount = boostrapMethodCount;
ByteVector bootstrapMethods = new ByteVector(size + 62);
bootstrapMethods.putByteArray(b, v + 8, size - 2);
classWriter.bootstrapMethods = bootstrapMethods;
return;
}
v += 6 + size;
}
// we are in trouble !!!
}
/**
* Constructs a new {@link ClassReader} object.
*
* @param is an input stream from which to read the class.
* @throws IOException if a problem occurs during reading.
*/
public ClassReader(final InputStream is) throws IOException {
this(readClass(is));
}
/**
* Constructs a new {@link ClassReader} object.
*
* @param name the binary qualified name of the class to be read.
* @throws IOException if an exception occurs during reading.
*/
public ClassReader(String name) throws IOException {
this(readClass(ClassLoader.getSystemResourceAsStream(name.replace('.', '/') + ".class")));
}
/**
* Reads the bytecode of a class.
*
* @param is an input stream from which to read the class.
* @return the bytecode read from the given input stream.
* @throws IOException if a problem occurs during reading.
*/
private static byte[] readClass(InputStream is)
throws IOException
{
if (is == null) {
throw new IOException("Class not found");
}
try {
byte[] b = new byte[is.available()];
int len = 0;
while (true) {
int n = is.read(b, len, b.length - len);
if (n == -1) {
if (len < b.length) {
byte[] c = new byte[len];
System.arraycopy(b, 0, c, 0, len);
b = c;
}
return b;
}
len += n;
if (len == b.length) {
int last = is.read();
if (last < 0) {
return b;
}
byte[] c = new byte[b.length + 1000];
System.arraycopy(b, 0, c, 0, len);
c[len++] = (byte) last;
b = c;
}
}
} finally {
is.close();
}
}
// ------------------------------------------------------------------------
// Public methods
// ------------------------------------------------------------------------
/**
* Makes the given visitor visit the Java class of this ClassReader.
* This class is the one specified in the constructor (see
* {@link #ClassReader(byte[]) ClassReader}).
*
* @param classVisitor the visitor that must visit this class.
* @param flags option flags that can be used to modify the default behavior
* of this class. See {@link #SKIP_DEBUG}, {@link #EXPAND_FRAMES},
* {@link #SKIP_FRAMES}, {@link #SKIP_CODE}.
*/
public void accept(ClassVisitor classVisitor, int flags) {
accept(classVisitor, new Attribute[0], flags);
}
/**
* Makes the given visitor visit the Java class of this ClassReader.
* This class is the one specified in the constructor (see
* {@link #ClassReader(byte[]) ClassReader}).
*
* @param classVisitor the visitor that must visit this class.
* @param attrs prototypes of the attributes that must be parsed during the
* visit of the class. Any attribute whose type is not equal to the
* type of one the prototypes will not be parsed: its byte array
* value will be passed unchanged to the ClassWriter. This may
* corrupt it if this value contains references to the constant pool,
* or has syntactic or semantic links with a class element that has
* been transformed by a class adapter between the reader and the
* writer.
* @param flags option flags that can be used to modify the default behavior
* of this class. See {@link #SKIP_DEBUG}, {@link #EXPAND_FRAMES},
* {@link #SKIP_FRAMES}, {@link #SKIP_CODE}.
*/
public void accept(
ClassVisitor classVisitor,
Attribute[] attrs,
int flags)
{
byte[] b = this.b; // the bytecode array
char[] c = new char[maxStringLength]; // buffer used to read strings
int i, j, k; // loop variables
int u, v, w; // indexes in b
Attribute attr;
int access;
String name;
String desc;
String attrName;
String signature;
int anns = 0;
int ianns = 0;
Attribute cattrs = null;
// visits the header
u = header;
access = readUnsignedShort(u);
name = readClass(u + 2, c);
v = items[readUnsignedShort(u + 4)];
String superClassName = v == 0 ? null : readUTF8(v, c);
String[] implementedItfs = new String[readUnsignedShort(u + 6)];
w = 0;
u += 8;
for (i = 0; i < implementedItfs.length; ++i) {
implementedItfs[i] = readClass(u, c);
u += 2;
}
boolean skipCode = (flags & SKIP_CODE) != 0;
boolean skipDebug = (flags & SKIP_DEBUG) != 0;
boolean unzip = (flags & EXPAND_FRAMES) != 0;
// skips fields and methods
v = u;
i = readUnsignedShort(v);
v += 2;
for (; i > 0; --i) {
j = readUnsignedShort(v + 6);
v += 8;
for (; j > 0; --j) {
v += 6 + readInt(v + 2);
}
}
i = readUnsignedShort(v);
v += 2;
for (; i > 0; --i) {
j = readUnsignedShort(v + 6);
v += 8;
for (; j > 0; --j) {
v += 6 + readInt(v + 2);
}
}
// reads the class's attributes
signature = null;
String sourceFile = null;
String sourceDebug = null;
String enclosingOwner = null;
String enclosingName = null;
String enclosingDesc = null;
int[] bootstrapMethods = null; // start indexed of the bsms
i = readUnsignedShort(v);
v += 2;
for (; i > 0; --i) {
attrName = readUTF8(v, c);
// tests are sorted in decreasing frequency order
// (based on frequencies observed on typical classes)
if ("SourceFile".equals(attrName)) {
sourceFile = readUTF8(v + 6, c);
} else if ("InnerClasses".equals(attrName)) {
w = v + 6;
} else if ("EnclosingMethod".equals(attrName)) {
enclosingOwner = readClass(v + 6, c);
int item = readUnsignedShort(v + 8);
if (item != 0) {
enclosingName = readUTF8(items[item], c);
enclosingDesc = readUTF8(items[item] + 2, c);
}
} else if ("Signature".equals(attrName)) {
signature = readUTF8(v + 6, c);
} else if ("RuntimeVisibleAnnotations".equals(attrName)) {
anns = v + 6;
} else if ("Deprecated".equals(attrName)) {
access |= Opcodes.ACC_DEPRECATED;
} else if ("Synthetic".equals(attrName)) {
access |= Opcodes.ACC_SYNTHETIC | ClassWriter.ACC_SYNTHETIC_ATTRIBUTE;
} else if ("SourceDebugExtension".equals(attrName)) {
int len = readInt(v + 2);
sourceDebug = readUTF(v + 6, len, new char[len]);
} else if ("RuntimeInvisibleAnnotations".equals(attrName)) {
ianns = v + 6;
} else if ("BootstrapMethods".equals(attrName)) {
int boostrapMethodCount = readUnsignedShort(v + 6);
bootstrapMethods = new int[boostrapMethodCount];
int x = v + 8;
for (j = 0; j < boostrapMethodCount; j++) {
bootstrapMethods[j] = x;
x += 2 + readUnsignedShort(x + 2) << 1;
}
} else {
attr = readAttribute(attrs,
attrName,
v + 6,
readInt(v + 2),
c,
-1,
null);
if (attr != null) {
attr.next = cattrs;
cattrs = attr;
}
}
v += 6 + readInt(v + 2);
}
// calls the visit method
classVisitor.visit(readInt(4),
access,
name,
signature,
superClassName,
implementedItfs);
// calls the visitSource method
if (!skipDebug && (sourceFile != null || sourceDebug != null)) {
classVisitor.visitSource(sourceFile, sourceDebug);
}
// calls the visitOuterClass method
if (enclosingOwner != null) {
classVisitor.visitOuterClass(enclosingOwner,
enclosingName,
enclosingDesc);
}
// visits the class annotations
for (i = 1; i >= 0; --i) {
v = i == 0 ? ianns : anns;
if (v != 0) {
j = readUnsignedShort(v);
v += 2;
for (; j > 0; --j) {
v = readAnnotationValues(v + 2, c, true,
classVisitor.visitAnnotation(readUTF8(v, c), i != 0));
}
}
}
// visits the class attributes
while (cattrs != null) {
attr = cattrs.next;
cattrs.next = null;
classVisitor.visitAttribute(cattrs);
cattrs = attr;
}
// calls the visitInnerClass method
if (w != 0) {
i = readUnsignedShort(w);
w += 2;
for (; i > 0; --i) {
classVisitor.visitInnerClass(readUnsignedShort(w) == 0
? null
: readClass(w, c), readUnsignedShort(w + 2) == 0
? null
: readClass(w + 2, c), readUnsignedShort(w + 4) == 0
? null
: readUTF8(w + 4, c), readUnsignedShort(w + 6));
w += 8;
}
}
// visits the fields
i = readUnsignedShort(u);
u += 2;
for (; i > 0; --i) {
access = readUnsignedShort(u);
name = readUTF8(u + 2, c);
desc = readUTF8(u + 4, c);
// visits the field's attributes and looks for a ConstantValue
// attribute
int fieldValueItem = 0;
signature = null;
anns = 0;
ianns = 0;
cattrs = null;
j = readUnsignedShort(u + 6);
u += 8;
for (; j > 0; --j) {
attrName = readUTF8(u, c);
// tests are sorted in decreasing frequency order
// (based on frequencies observed on typical classes)
if ("ConstantValue".equals(attrName)) {
fieldValueItem = readUnsignedShort(u + 6);
} else if ("Signature".equals(attrName)) {
signature = readUTF8(u + 6, c);
} else if ("Deprecated".equals(attrName)) {
access |= Opcodes.ACC_DEPRECATED;
} else if ("Synthetic".equals(attrName)) {
access |= Opcodes.ACC_SYNTHETIC | ClassWriter.ACC_SYNTHETIC_ATTRIBUTE;
} else if ("RuntimeVisibleAnnotations".equals(attrName)) {
anns = u + 6;
} else if ("RuntimeInvisibleAnnotations".equals(attrName)) {
ianns = u + 6;
} else {
attr = readAttribute(attrs,
attrName,
u + 6,
readInt(u + 2),
c,
-1,
null);
if (attr != null) {
attr.next = cattrs;
cattrs = attr;
}
}
u += 6 + readInt(u + 2);
}
// visits the field
FieldVisitor fv = classVisitor.visitField(access,
name,
desc,
signature,
fieldValueItem == 0 ? null : readConst(fieldValueItem, c));
// visits the field annotations and attributes
if (fv != null) {
for (j = 1; j >= 0; --j) {
v = j == 0 ? ianns : anns;
if (v != 0) {
k = readUnsignedShort(v);
v += 2;
for (; k > 0; --k) {
v = readAnnotationValues(v + 2, c, true,
fv.visitAnnotation(readUTF8(v, c), j != 0));
}
}
}
while (cattrs != null) {
attr = cattrs.next;
cattrs.next = null;
fv.visitAttribute(cattrs);
cattrs = attr;
}
fv.visitEnd();
}
}
// visits the methods
i = readUnsignedShort(u);
u += 2;
for (; i > 0; --i) {
int u0 = u + 6;
access = readUnsignedShort(u);
name = readUTF8(u + 2, c);
desc = readUTF8(u + 4, c);
signature = null;
anns = 0;
ianns = 0;
int dann = 0;
int mpanns = 0;
int impanns = 0;
cattrs = null;
v = 0;
w = 0;
// looks for Code and Exceptions attributes
j = readUnsignedShort(u + 6);
u += 8;
for (; j > 0; --j) {
attrName = readUTF8(u, c);
int attrSize = readInt(u + 2);
u += 6;
// tests are sorted in decreasing frequency order
// (based on frequencies observed on typical classes)
if ("Code".equals(attrName)) {
if (!skipCode) {
v = u;
}
} else if ("Exceptions".equals(attrName)) {
w = u;
} else if ("Signature".equals(attrName)) {
signature = readUTF8(u, c);
} else if ("Deprecated".equals(attrName)) {
access |= Opcodes.ACC_DEPRECATED;
} else if ("RuntimeVisibleAnnotations".equals(attrName)) {
anns = u;
} else if ("AnnotationDefault".equals(attrName)) {
dann = u;
} else if ("Synthetic".equals(attrName)) {
access |= Opcodes.ACC_SYNTHETIC | ClassWriter.ACC_SYNTHETIC_ATTRIBUTE;
} else if ("RuntimeInvisibleAnnotations".equals(attrName)) {
ianns = u;
} else if ("RuntimeVisibleParameterAnnotations".equals(attrName))
{
mpanns = u;
} else if ("RuntimeInvisibleParameterAnnotations".equals(attrName))
{
impanns = u;
} else {
attr = readAttribute(attrs,
attrName,
u,
attrSize,
c,
-1,
null);
if (attr != null) {
attr.next = cattrs;
cattrs = attr;
}
}
u += attrSize;
}
// reads declared exceptions
String[] exceptions;
if (w == 0) {
exceptions = null;
} else {
exceptions = new String[readUnsignedShort(w)];
w += 2;
for (j = 0; j < exceptions.length; ++j) {
exceptions[j] = readClass(w, c);
w += 2;
}
}
// visits the method's code, if any
MethodVisitor mv = classVisitor.visitMethod(access,
name,
desc,
signature,
exceptions);
if (mv != null) {
/*
* if the returned MethodVisitor is in fact a MethodWriter, it
* means there is no method adapter between the reader and the
* writer. If, in addition, the writer's constant pool was
* copied from this reader (mw.cw.cr == this), and the signature
* and exceptions of the method have not been changed, then it
* is possible to skip all visit events and just copy the
* original code of the method to the writer (the access, name
* and descriptor can have been changed, this is not important
* since they are not copied as is from the reader).
*/
if (mv instanceof MethodWriter) {
MethodWriter mw = (MethodWriter) mv;
if (mw.cw.cr == this) {
if (signature == mw.signature) {
boolean sameExceptions = false;
if (exceptions == null) {
sameExceptions = mw.exceptionCount == 0;
} else {
if (exceptions.length == mw.exceptionCount) {
sameExceptions = true;
for (j = exceptions.length - 1; j >= 0; --j)
{
w -= 2;
if (mw.exceptions[j] != readUnsignedShort(w))
{
sameExceptions = false;
break;
}
}
}
}
if (sameExceptions) {
/*
* we do not copy directly the code into
* MethodWriter to save a byte array copy
* operation. The real copy will be done in
* ClassWriter.toByteArray().
*/
mw.classReaderOffset = u0;
mw.classReaderLength = u - u0;
continue;
}
}
}
}
if (dann != 0) {
AnnotationVisitor dv = mv.visitAnnotationDefault();
readAnnotationValue(dann, c, null, dv);
if (dv != null) {
dv.visitEnd();
}
}
for (j = 1; j >= 0; --j) {
w = j == 0 ? ianns : anns;
if (w != 0) {
k = readUnsignedShort(w);
w += 2;
for (; k > 0; --k) {
w = readAnnotationValues(w + 2, c, true,
mv.visitAnnotation(readUTF8(w, c), j != 0));
}
}
}
if (mpanns != 0) {
readParameterAnnotations(mpanns, desc, c, true, mv);
}
if (impanns != 0) {
readParameterAnnotations(impanns, desc, c, false, mv);
}
while (cattrs != null) {
attr = cattrs.next;
cattrs.next = null;
mv.visitAttribute(cattrs);
cattrs = attr;
}
}
if (mv != null && v != 0) {
int maxStack = readUnsignedShort(v);
int maxLocals = readUnsignedShort(v + 2);
int codeLength = readInt(v + 4);
v += 8;
int codeStart = v;
int codeEnd = v + codeLength;
mv.visitCode();
// 1st phase: finds the labels
int label;
Label[] labels = new Label[codeLength + 2];
readLabel(codeLength + 1, labels);
while (v < codeEnd) {
w = v - codeStart;
int opcode = b[v] & 0xFF;
switch (ClassWriter.TYPE[opcode]) {
case ClassWriter.NOARG_INSN:
case ClassWriter.IMPLVAR_INSN:
v += 1;
break;
case ClassWriter.LABEL_INSN:
readLabel(w + readShort(v + 1), labels);
v += 3;
break;
case ClassWriter.LABELW_INSN:
readLabel(w + readInt(v + 1), labels);
v += 5;
break;
case ClassWriter.WIDE_INSN:
opcode = b[v + 1] & 0xFF;
if (opcode == Opcodes.IINC) {
v += 6;
} else {
v += 4;
}
break;
case ClassWriter.TABL_INSN:
// skips 0 to 3 padding bytes*
v = v + 4 - (w & 3);
// reads instruction
readLabel(w + readInt(v), labels);
j = readInt(v + 8) - readInt(v + 4) + 1;
v += 12;
for (; j > 0; --j) {
readLabel(w + readInt(v), labels);
v += 4;
}
break;
case ClassWriter.LOOK_INSN:
// skips 0 to 3 padding bytes*
v = v + 4 - (w & 3);
// reads instruction
readLabel(w + readInt(v), labels);
j = readInt(v + 4);
v += 8;
for (; j > 0; --j) {
readLabel(w + readInt(v + 4), labels);
v += 8;
}
break;
case ClassWriter.VAR_INSN:
case ClassWriter.SBYTE_INSN:
case ClassWriter.LDC_INSN:
v += 2;
break;
case ClassWriter.SHORT_INSN:
case ClassWriter.LDCW_INSN:
case ClassWriter.FIELDORMETH_INSN:
case ClassWriter.TYPE_INSN:
case ClassWriter.IINC_INSN:
v += 3;
break;
case ClassWriter.ITFMETH_INSN:
case ClassWriter.INDYMETH_INSN:
v += 5;
break;
// case MANA_INSN:
default:
v += 4;
break;
}
}
// parses the try catch entries
j = readUnsignedShort(v);
v += 2;
for (; j > 0; --j) {
Label start = readLabel(readUnsignedShort(v), labels);
Label end = readLabel(readUnsignedShort(v + 2), labels);
Label handler = readLabel(readUnsignedShort(v + 4), labels);
int type = readUnsignedShort(v + 6);
if (type == 0) {
mv.visitTryCatchBlock(start, end, handler, null);
} else {
mv.visitTryCatchBlock(start,
end,
handler,
readUTF8(items[type], c));
}
v += 8;
}
// parses the local variable, line number tables, and code
// attributes
int varTable = 0;
int varTypeTable = 0;
int stackMap = 0;
int stackMapSize = 0;
int frameCount = 0;
int frameMode = 0;
int frameOffset = 0;
int frameLocalCount = 0;
int frameLocalDiff = 0;
int frameStackCount = 0;
Object[] frameLocal = null;
Object[] frameStack = null;
boolean zip = true;
cattrs = null;
j = readUnsignedShort(v);
v += 2;
for (; j > 0; --j) {
attrName = readUTF8(v, c);
if ("LocalVariableTable".equals(attrName)) {
if (!skipDebug) {
varTable = v + 6;
k = readUnsignedShort(v + 6);
w = v + 8;
for (; k > 0; --k) {
label = readUnsignedShort(w);
if (labels[label] == null) {
readLabel(label, labels).status |= Label.DEBUG;
}
label += readUnsignedShort(w + 2);
if (labels[label] == null) {
readLabel(label, labels).status |= Label.DEBUG;
}
w += 10;
}
}
} else if ("LocalVariableTypeTable".equals(attrName)) {
varTypeTable = v + 6;
} else if ("LineNumberTable".equals(attrName)) {
if (!skipDebug) {
k = readUnsignedShort(v + 6);
w = v + 8;
for (; k > 0; --k) {
label = readUnsignedShort(w);
if (labels[label] == null) {
readLabel(label, labels).status |= Label.DEBUG;
}
labels[label].line = readUnsignedShort(w + 2);
w += 4;
}
}
} else if ("StackMapTable".equals(attrName)) {
if ((flags & SKIP_FRAMES) == 0) {
stackMap = v + 8;
stackMapSize = readInt(v + 2);
frameCount = readUnsignedShort(v + 6);
}
/*
* here we do not extract the labels corresponding to
* the attribute content. This would require a full
* parsing of the attribute, which would need to be
* repeated in the second phase (see below). Instead the
* content of the attribute is read one frame at a time
* (i.e. after a frame has been visited, the next frame
* is read), and the labels it contains are also
* extracted one frame at a time. Thanks to the ordering
* of frames, having only a "one frame lookahead" is not
* a problem, i.e. it is not possible to see an offset
* smaller than the offset of the current insn and for
* which no Label exist.
*/
/*
* This is not true for UNINITIALIZED type offsets. We
* solve this by parsing the stack map table without a
* full decoding (see below).
*/
} else if ("StackMap".equals(attrName)) {
if ((flags & SKIP_FRAMES) == 0) {
stackMap = v + 8;
stackMapSize = readInt(v + 2);
frameCount = readUnsignedShort(v + 6);
zip = false;
}
/*
* IMPORTANT! here we assume that the frames are
* ordered, as in the StackMapTable attribute, although
* this is not guaranteed by the attribute format.
*/
} else {
for (k = 0; k < attrs.length; ++k) {
if (attrs[k].type.equals(attrName)) {
attr = attrs[k].read(this,
v + 6,
readInt(v + 2),
c,
codeStart - 8,
labels);
if (attr != null) {
attr.next = cattrs;
cattrs = attr;
}
}
}
}
v += 6 + readInt(v + 2);
}
// 2nd phase: visits each instruction
if (stackMap != 0) {
// creates the very first (implicit) frame from the method
// descriptor
frameLocal = new Object[maxLocals];
frameStack = new Object[maxStack];
if (unzip) {
int local = 0;
if ((access & Opcodes.ACC_STATIC) == 0) {
if ("".equals(name)) {
frameLocal[local++] = Opcodes.UNINITIALIZED_THIS;
} else {
frameLocal[local++] = readClass(header + 2, c);
}
}
j = 1;
loop: while (true) {
k = j;
switch (desc.charAt(j++)) {
case 'Z':
case 'C':
case 'B':
case 'S':
case 'I':
frameLocal[local++] = Opcodes.INTEGER;
break;
case 'F':
frameLocal[local++] = Opcodes.FLOAT;
break;
case 'J':
frameLocal[local++] = Opcodes.LONG;
break;
case 'D':
frameLocal[local++] = Opcodes.DOUBLE;
break;
case '[':
while (desc.charAt(j) == '[') {
++j;
}
if (desc.charAt(j) == 'L') {
++j;
while (desc.charAt(j) != ';') {
++j;
}
}
frameLocal[local++] = desc.substring(k, ++j);
break;
case 'L':
while (desc.charAt(j) != ';') {
++j;
}
frameLocal[local++] = desc.substring(k + 1,
j++);
break;
default:
break loop;
}
}
frameLocalCount = local;
}
/*
* for the first explicit frame the offset is not
* offset_delta + 1 but only offset_delta; setting the
* implicit frame offset to -1 allow the use of the
* "offset_delta + 1" rule in all cases
*/
frameOffset = -1;
/*
* Finds labels for UNINITIALIZED frame types. Instead of
* decoding each element of the stack map table, we look
* for 3 consecutive bytes that "look like" an UNINITIALIZED
* type (tag 8, offset within code bounds, NEW instruction
* at this offset). We may find false positives (i.e. not
* real UNINITIALIZED types), but this should be rare, and
* the only consequence will be the creation of an unneeded
* label. This is better than creating a label for each NEW
* instruction, and faster than fully decoding the whole
* stack map table.
*/
for (j = stackMap; j < stackMap + stackMapSize - 2; ++j) {
if (b[j] == 8) { // UNINITIALIZED FRAME TYPE
k = readUnsignedShort(j + 1);
if (k >= 0 && k < codeLength) { // potential offset
if ((b[codeStart + k] & 0xFF) == Opcodes.NEW) { // NEW at this offset
readLabel(k, labels);
}
}
}
}
}
v = codeStart;
Label l;
while (v < codeEnd) {
w = v - codeStart;
l = labels[w];
if (l != null) {
mv.visitLabel(l);
if (!skipDebug && l.line > 0) {
mv.visitLineNumber(l.line, l);
}
}
while (frameLocal != null && (frameOffset == w || frameOffset == -1))
{
// if there is a frame for this offset,
// makes the visitor visit it,
// and reads the next frame if there is one.
if (!zip || unzip) {
mv.visitFrame(Opcodes.F_NEW,
frameLocalCount,
frameLocal,
frameStackCount,
frameStack);
} else if (frameOffset != -1) {
mv.visitFrame(frameMode,
frameLocalDiff,
frameLocal,
frameStackCount,
frameStack);
}
if (frameCount > 0) {
int tag, delta, n;
if (zip) {
tag = b[stackMap++] & 0xFF;
} else {
tag = MethodWriter.FULL_FRAME;
frameOffset = -1;
}
frameLocalDiff = 0;
if (tag < MethodWriter.SAME_LOCALS_1_STACK_ITEM_FRAME)
{
delta = tag;
frameMode = Opcodes.F_SAME;
frameStackCount = 0;
} else if (tag < MethodWriter.RESERVED) {
delta = tag
- MethodWriter.SAME_LOCALS_1_STACK_ITEM_FRAME;
stackMap = readFrameType(frameStack,
0,
stackMap,
c,
labels);
frameMode = Opcodes.F_SAME1;
frameStackCount = 1;
} else {
delta = readUnsignedShort(stackMap);
stackMap += 2;
if (tag == MethodWriter.SAME_LOCALS_1_STACK_ITEM_FRAME_EXTENDED)
{
stackMap = readFrameType(frameStack,
0,
stackMap,
c,
labels);
frameMode = Opcodes.F_SAME1;
frameStackCount = 1;
} else if (tag >= MethodWriter.CHOP_FRAME
&& tag < MethodWriter.SAME_FRAME_EXTENDED)
{
frameMode = Opcodes.F_CHOP;
frameLocalDiff = MethodWriter.SAME_FRAME_EXTENDED
- tag;
frameLocalCount -= frameLocalDiff;
frameStackCount = 0;
} else if (tag == MethodWriter.SAME_FRAME_EXTENDED)
{
frameMode = Opcodes.F_SAME;
frameStackCount = 0;
} else if (tag < MethodWriter.FULL_FRAME) {
j = unzip ? frameLocalCount : 0;
for (k = tag
- MethodWriter.SAME_FRAME_EXTENDED; k > 0; k--)
{
stackMap = readFrameType(frameLocal,
j++,
stackMap,
c,
labels);
}
frameMode = Opcodes.F_APPEND;
frameLocalDiff = tag
- MethodWriter.SAME_FRAME_EXTENDED;
frameLocalCount += frameLocalDiff;
frameStackCount = 0;
} else { // if (tag == FULL_FRAME) {
frameMode = Opcodes.F_FULL;
n = frameLocalDiff = frameLocalCount = readUnsignedShort(stackMap);
stackMap += 2;
for (j = 0; n > 0; n--) {
stackMap = readFrameType(frameLocal,
j++,
stackMap,
c,
labels);
}
n = frameStackCount = readUnsignedShort(stackMap);
stackMap += 2;
for (j = 0; n > 0; n--) {
stackMap = readFrameType(frameStack,
j++,
stackMap,
c,
labels);
}
}
}
frameOffset += delta + 1;
readLabel(frameOffset, labels);
--frameCount;
} else {
frameLocal = null;
}
}
int opcode = b[v] & 0xFF;
switch (ClassWriter.TYPE[opcode]) {
case ClassWriter.NOARG_INSN:
mv.visitInsn(opcode);
v += 1;
break;
case ClassWriter.IMPLVAR_INSN:
if (opcode > Opcodes.ISTORE) {
opcode -= 59; // ISTORE_0
mv.visitVarInsn(Opcodes.ISTORE + (opcode >> 2),
opcode & 0x3);
} else {
opcode -= 26; // ILOAD_0
mv.visitVarInsn(Opcodes.ILOAD + (opcode >> 2),
opcode & 0x3);
}
v += 1;
break;
case ClassWriter.LABEL_INSN:
mv.visitJumpInsn(opcode, labels[w
+ readShort(v + 1)]);
v += 3;
break;
case ClassWriter.LABELW_INSN:
mv.visitJumpInsn(opcode - 33, labels[w
+ readInt(v + 1)]);
v += 5;
break;
case ClassWriter.WIDE_INSN:
opcode = b[v + 1] & 0xFF;
if (opcode == Opcodes.IINC) {
mv.visitIincInsn(readUnsignedShort(v + 2),
readShort(v + 4));
v += 6;
} else {
mv.visitVarInsn(opcode,
readUnsignedShort(v + 2));
v += 4;
}
break;
case ClassWriter.TABL_INSN:
// skips 0 to 3 padding bytes
v = v + 4 - (w & 3);
// reads instruction
label = w + readInt(v);
int min = readInt(v + 4);
int max = readInt(v + 8);
v += 12;
Label[] table = new Label[max - min + 1];
for (j = 0; j < table.length; ++j) {
table[j] = labels[w + readInt(v)];
v += 4;
}
mv.visitTableSwitchInsn(min,
max,
labels[label],
table);
break;
case ClassWriter.LOOK_INSN:
// skips 0 to 3 padding bytes
v = v + 4 - (w & 3);
// reads instruction
label = w + readInt(v);
j = readInt(v + 4);
v += 8;
int[] keys = new int[j];
Label[] values = new Label[j];
for (j = 0; j < keys.length; ++j) {
keys[j] = readInt(v);
values[j] = labels[w + readInt(v + 4)];
v += 8;
}
mv.visitLookupSwitchInsn(labels[label],
keys,
values);
break;
case ClassWriter.VAR_INSN:
mv.visitVarInsn(opcode, b[v + 1] & 0xFF);
v += 2;
break;
case ClassWriter.SBYTE_INSN:
mv.visitIntInsn(opcode, b[v + 1]);
v += 2;
break;
case ClassWriter.SHORT_INSN:
mv.visitIntInsn(opcode, readShort(v + 1));
v += 3;
break;
case ClassWriter.LDC_INSN:
mv.visitLdcInsn(readConst(b[v + 1] & 0xFF, c));
v += 2;
break;
case ClassWriter.LDCW_INSN:
mv.visitLdcInsn(readConst(readUnsignedShort(v + 1),
c));
v += 3;
break;
case ClassWriter.FIELDORMETH_INSN:
case ClassWriter.ITFMETH_INSN: {
int cpIndex = items[readUnsignedShort(v + 1)];
String iowner = readClass(cpIndex, c);
cpIndex = items[readUnsignedShort(cpIndex + 2)];
String iname = readUTF8(cpIndex, c);
String idesc = readUTF8(cpIndex + 2, c);
if (opcode < Opcodes.INVOKEVIRTUAL) {
mv.visitFieldInsn(opcode, iowner, iname, idesc);
} else {
mv.visitMethodInsn(opcode, iowner, iname, idesc);
}
if (opcode == Opcodes.INVOKEINTERFACE) {
v += 5;
} else {
v += 3;
}
break;
}
case ClassWriter.INDYMETH_INSN: {
int cpIndex = items[readUnsignedShort(v + 1)];
int bsmIndex = bootstrapMethods[readUnsignedShort(cpIndex)];
cpIndex = items[readUnsignedShort(cpIndex + 2)];
String iname = readUTF8(cpIndex, c);
String idesc = readUTF8(cpIndex + 2, c);
int mhIndex = readUnsignedShort(bsmIndex);
Handle bsm = (Handle) readConst(mhIndex, c);
int bsmArgCount = readUnsignedShort(bsmIndex + 2);
Object[] bsmArgs = new Object[bsmArgCount];
bsmIndex += 4;
for(int a = 0; a < bsmArgCount; a++) {
int argIndex = readUnsignedShort(bsmIndex);
bsmArgs[a] = readConst(argIndex, c);
bsmIndex += 2;
}
mv.visitInvokeDynamicInsn(iname, idesc, bsm, bsmArgs);
v += 5;
break;
}
case ClassWriter.TYPE_INSN:
mv.visitTypeInsn(opcode, readClass(v + 1, c));
v += 3;
break;
case ClassWriter.IINC_INSN:
mv.visitIincInsn(b[v + 1] & 0xFF, b[v + 2]);
v += 3;
break;
// case MANA_INSN:
default:
mv.visitMultiANewArrayInsn(readClass(v + 1, c),
b[v + 3] & 0xFF);
v += 4;
break;
}
}
l = labels[codeEnd - codeStart];
if (l != null) {
mv.visitLabel(l);
}
// visits the local variable tables
if (!skipDebug && varTable != 0) {
int[] typeTable = null;
if (varTypeTable != 0) {
k = readUnsignedShort(varTypeTable) * 3;
w = varTypeTable + 2;
typeTable = new int[k];
while (k > 0) {
typeTable[--k] = w + 6; // signature
typeTable[--k] = readUnsignedShort(w + 8); // index
typeTable[--k] = readUnsignedShort(w); // start
w += 10;
}
}
k = readUnsignedShort(varTable);
w = varTable + 2;
for (; k > 0; --k) {
int start = readUnsignedShort(w);
int length = readUnsignedShort(w + 2);
int index = readUnsignedShort(w + 8);
String vsignature = null;
if (typeTable != null) {
for (int a = 0; a < typeTable.length; a += 3) {
if (typeTable[a] == start
&& typeTable[a + 1] == index)
{
vsignature = readUTF8(typeTable[a + 2], c);
break;
}
}
}
mv.visitLocalVariable(readUTF8(w + 4, c),
readUTF8(w + 6, c),
vsignature,
labels[start],
labels[start + length],
index);
w += 10;
}
}
// visits the other attributes
while (cattrs != null) {
attr = cattrs.next;
cattrs.next = null;
mv.visitAttribute(cattrs);
cattrs = attr;
}
// visits the max stack and max locals values
mv.visitMaxs(maxStack, maxLocals);
}
if (mv != null) {
mv.visitEnd();
}
}
// visits the end of the class
classVisitor.visitEnd();
}
/**
* Reads parameter annotations and makes the given visitor visit them.
*
* @param v start offset in {@link #b b} of the annotations to be read.
* @param desc the method descriptor.
* @param buf buffer to be used to call {@link #readUTF8 readUTF8},
* {@link #readClass(int,char[]) readClass} or
* {@link #readConst readConst}.
* @param visible true if the annotations to be read are visible
* at runtime.
* @param mv the visitor that must visit the annotations.
*/
private void readParameterAnnotations(
int v,
String desc,
char[] buf,
boolean visible,
MethodVisitor mv)
{
int i;
int n = b[v++] & 0xFF;
// workaround for a bug in javac (javac compiler generates a parameter
// annotation array whose size is equal to the number of parameters in
// the Java source file, while it should generate an array whose size is
// equal to the number of parameters in the method descriptor - which
// includes the synthetic parameters added by the compiler). This work-
// around supposes that the synthetic parameters are the first ones.
int synthetics = Type.getArgumentTypes(desc).length - n;
AnnotationVisitor av;
for (i = 0; i < synthetics; ++i) {
// virtual annotation to detect synthetic parameters in MethodWriter
av = mv.visitParameterAnnotation(i, "Ljava/lang/Synthetic;", false);
if (av != null) {
av.visitEnd();
}
}
for (; i < n + synthetics; ++i) {
int j = readUnsignedShort(v);
v += 2;
for (; j > 0; --j) {
av = mv.visitParameterAnnotation(i, readUTF8(v, buf), visible);
v = readAnnotationValues(v + 2, buf, true, av);
}
}
}
/**
* Reads the values of an annotation and makes the given visitor visit them.
*
* @param v the start offset in {@link #b b} of the values to be read
* (including the unsigned short that gives the number of values).
* @param buf buffer to be used to call {@link #readUTF8 readUTF8},
* {@link #readClass(int,char[]) readClass} or
* {@link #readConst readConst}.
* @param named if the annotation values are named or not.
* @param av the visitor that must visit the values.
* @return the end offset of the annotation values.
*/
private int readAnnotationValues(
int v,
char[] buf,
boolean named,
AnnotationVisitor av)
{
int i = readUnsignedShort(v);
v += 2;
if (named) {
for (; i > 0; --i) {
v = readAnnotationValue(v + 2, buf, readUTF8(v, buf), av);
}
} else {
for (; i > 0; --i) {
v = readAnnotationValue(v, buf, null, av);
}
}
if (av != null) {
av.visitEnd();
}
return v;
}
/**
* Reads a value of an annotation and makes the given visitor visit it.
*
* @param v the start offset in {@link #b b} of the value to be read (not
* including the value name constant pool index).
* @param buf buffer to be used to call {@link #readUTF8 readUTF8},
* {@link #readClass(int,char[]) readClass} or
* {@link #readConst readConst}.
* @param name the name of the value to be read.
* @param av the visitor that must visit the value.
* @return the end offset of the annotation value.
*/
private int readAnnotationValue(
int v,
char[] buf,
String name,
AnnotationVisitor av)
{
int i;
if (av == null) {
switch (b[v] & 0xFF) {
case 'e': // enum_const_value
return v + 5;
case '@': // annotation_value
return readAnnotationValues(v + 3, buf, true, null);
case '[': // array_value
return readAnnotationValues(v + 1, buf, false, null);
default:
return v + 3;
}
}
switch (b[v++] & 0xFF) {
case 'I': // pointer to CONSTANT_Integer
case 'J': // pointer to CONSTANT_Long
case 'F': // pointer to CONSTANT_Float
case 'D': // pointer to CONSTANT_Double
av.visit(name, readConst(readUnsignedShort(v), buf));
v += 2;
break;
case 'B': // pointer to CONSTANT_Byte
av.visit(name,
new Byte((byte) readInt(items[readUnsignedShort(v)])));
v += 2;
break;
case 'Z': // pointer to CONSTANT_Boolean
av.visit(name, readInt(items[readUnsignedShort(v)]) == 0
? Boolean.FALSE
: Boolean.TRUE);
v += 2;
break;
case 'S': // pointer to CONSTANT_Short
av.visit(name,
new Short((short) readInt(items[readUnsignedShort(v)])));
v += 2;
break;
case 'C': // pointer to CONSTANT_Char
av.visit(name,
new Character((char) readInt(items[readUnsignedShort(v)])));
v += 2;
break;
case 's': // pointer to CONSTANT_Utf8
av.visit(name, readUTF8(v, buf));
v += 2;
break;
case 'e': // enum_const_value
av.visitEnum(name, readUTF8(v, buf), readUTF8(v + 2, buf));
v += 4;
break;
case 'c': // class_info
av.visit(name, Type.getType(readUTF8(v, buf)));
v += 2;
break;
case '@': // annotation_value
v = readAnnotationValues(v + 2,
buf,
true,
av.visitAnnotation(name, readUTF8(v, buf)));
break;
case '[': // array_value
int size = readUnsignedShort(v);
v += 2;
if (size == 0) {
return readAnnotationValues(v - 2,
buf,
false,
av.visitArray(name));
}
switch (this.b[v++] & 0xFF) {
case 'B':
byte[] bv = new byte[size];
for (i = 0; i < size; i++) {
bv[i] = (byte) readInt(items[readUnsignedShort(v)]);
v += 3;
}
av.visit(name, bv);
--v;
break;
case 'Z':
boolean[] zv = new boolean[size];
for (i = 0; i < size; i++) {
zv[i] = readInt(items[readUnsignedShort(v)]) != 0;
v += 3;
}
av.visit(name, zv);
--v;
break;
case 'S':
short[] sv = new short[size];
for (i = 0; i < size; i++) {
sv[i] = (short) readInt(items[readUnsignedShort(v)]);
v += 3;
}
av.visit(name, sv);
--v;
break;
case 'C':
char[] cv = new char[size];
for (i = 0; i < size; i++) {
cv[i] = (char) readInt(items[readUnsignedShort(v)]);
v += 3;
}
av.visit(name, cv);
--v;
break;
case 'I':
int[] iv = new int[size];
for (i = 0; i < size; i++) {
iv[i] = readInt(items[readUnsignedShort(v)]);
v += 3;
}
av.visit(name, iv);
--v;
break;
case 'J':
long[] lv = new long[size];
for (i = 0; i < size; i++) {
lv[i] = readLong(items[readUnsignedShort(v)]);
v += 3;
}
av.visit(name, lv);
--v;
break;
case 'F':
float[] fv = new float[size];
for (i = 0; i < size; i++) {
fv[i] = Float.intBitsToFloat(readInt(items[readUnsignedShort(v)]));
v += 3;
}
av.visit(name, fv);
--v;
break;
case 'D':
double[] dv = new double[size];
for (i = 0; i < size; i++) {
dv[i] = Double.longBitsToDouble(readLong(items[readUnsignedShort(v)]));
v += 3;
}
av.visit(name, dv);
--v;
break;
default:
v = readAnnotationValues(v - 3,
buf,
false,
av.visitArray(name));
}
}
return v;
}
private int readFrameType(
Object[] frame,
int index,
int v,
char[] buf,
Label[] labels)
{
int type = b[v++] & 0xFF;
switch (type) {
case 0:
frame[index] = Opcodes.TOP;
break;
case 1:
frame[index] = Opcodes.INTEGER;
break;
case 2:
frame[index] = Opcodes.FLOAT;
break;
case 3:
frame[index] = Opcodes.DOUBLE;
break;
case 4:
frame[index] = Opcodes.LONG;
break;
case 5:
frame[index] = Opcodes.NULL;
break;
case 6:
frame[index] = Opcodes.UNINITIALIZED_THIS;
break;
case 7: // Object
frame[index] = readClass(v, buf);
v += 2;
break;
default: // Uninitialized
frame[index] = readLabel(readUnsignedShort(v), labels);
v += 2;
}
return v;
}
/**
* Returns the label corresponding to the given offset. The default
* implementation of this method creates a label for the given offset if it
* has not been already created.
*
* @param offset a bytecode offset in a method.
* @param labels the already created labels, indexed by their offset. If a
* label already exists for offset this method must not create a new
* one. Otherwise it must store the new label in this array.
* @return a non null Label, which must be equal to labels[offset].
*/
protected Label readLabel(int offset, Label[] labels) {
if (labels[offset] == null) {
labels[offset] = new Label();
}
return labels[offset];
}
/**
* Reads an attribute in {@link #b b}.
*
* @param attrs prototypes of the attributes that must be parsed during the
* visit of the class. Any attribute whose type is not equal to the
* type of one the prototypes is ignored (i.e. an empty
* {@link Attribute} instance is returned).
* @param type the type of the attribute.
* @param off index of the first byte of the attribute's content in
* {@link #b b}. The 6 attribute header bytes, containing the type
* and the length of the attribute, are not taken into account here
* (they have already been read).
* @param len the length of the attribute's content.
* @param buf buffer to be used to call {@link #readUTF8 readUTF8},
* {@link #readClass(int,char[]) readClass} or
* {@link #readConst readConst}.
* @param codeOff index of the first byte of code's attribute content in
* {@link #b b}, or -1 if the attribute to be read is not a code
* attribute. The 6 attribute header bytes, containing the type and
* the length of the attribute, are not taken into account here.
* @param labels the labels of the method's code, or null if the
* attribute to be read is not a code attribute.
* @return the attribute that has been read, or null to skip this
* attribute.
*/
private Attribute readAttribute(
Attribute[] attrs,
String type,
int off,
int len,
char[] buf,
int codeOff,
Label[] labels)
{
for (int i = 0; i < attrs.length; ++i) {
if (attrs[i].type.equals(type)) {
return attrs[i].read(this, off, len, buf, codeOff, labels);
}
}
return new Attribute(type).read(this, off, len, null, -1, null);
}
// ------------------------------------------------------------------------
// Utility methods: low level parsing
// ------------------------------------------------------------------------
/**
* Returns the number of constant pool items in {@link #b b}.
*
* @return the number of constant pool items in {@link #b b}.
*/
public int getItemCount() {
return items.length;
}
/**
* Returns the start index of the constant pool item in {@link #b b}, plus
* one. This method is intended for {@link Attribute} sub classes, and is
* normally not needed by class generators or adapters.
*
* @param item the index a constant pool item.
* @return the start index of the constant pool item in {@link #b b}, plus
* one.
*/
public int getItem(int item) {
return items[item];
}
/**
* Returns the maximum length of the strings contained in the constant pool
* of the class.
*
* @return the maximum length of the strings contained in the constant pool
* of the class.
*/
public int getMaxStringLength() {
return maxStringLength;
}
/**
* Reads a byte value in {@link #b b}. This method is intended for
* {@link Attribute} sub classes, and is normally not needed by class
* generators or adapters.
*
* @param index the start index of the value to be read in {@link #b b}.
* @return the read value.
*/
public int readByte(int index) {
return b[index] & 0xFF;
}
/**
* Reads an unsigned short value in {@link #b b}. This method is
* intended for {@link Attribute} sub classes, and is normally not needed by
* class generators or adapters.
*
* @param index the start index of the value to be read in {@link #b b}.
* @return the read value.
*/
public int readUnsignedShort(int index) {
byte[] b = this.b;
return ((b[index] & 0xFF) << 8) | (b[index + 1] & 0xFF);
}
/**
* Reads a signed short value in {@link #b b}. This method is intended
* for {@link Attribute} sub classes, and is normally not needed by class
* generators or adapters.
*
* @param index the start index of the value to be read in {@link #b b}.
* @return the read value.
*/
public short readShort(int index) {
byte[] b = this.b;
return (short) (((b[index] & 0xFF) << 8) | (b[index + 1] & 0xFF));
}
/**
* Reads a signed int value in {@link #b b}. This method is intended for
* {@link Attribute} sub classes, and is normally not needed by class
* generators or adapters.
*
* @param index the start index of the value to be read in {@link #b b}.
* @return the read value.
*/
public int readInt(int index) {
byte[] b = this.b;
return ((b[index] & 0xFF) << 24) | ((b[index + 1] & 0xFF) << 16)
| ((b[index + 2] & 0xFF) << 8) | (b[index + 3] & 0xFF);
}
/**
* Reads a signed long value in {@link #b b}. This method is intended
* for {@link Attribute} sub classes, and is normally not needed by class
* generators or adapters.
*
* @param index the start index of the value to be read in {@link #b b}.
* @return the read value.
*/
public long readLong(int index) {
long l1 = readInt(index);
long l0 = readInt(index + 4) & 0xFFFFFFFFL;
return (l1 << 32) | l0;
}
/**
* Reads an UTF8 string constant pool item in {@link #b b}. This method
* is intended for {@link Attribute} sub classes, and is normally not needed
* by class generators or adapters.
*
* @param index the start index of an unsigned short value in {@link #b b},
* whose value is the index of an UTF8 constant pool item.
* @param buf buffer to be used to read the item. This buffer must be
* sufficiently large. It is not automatically resized.
* @return the String corresponding to the specified UTF8 item.
*/
public String readUTF8(int index, char[] buf) {
int item = readUnsignedShort(index);
String s = strings[item];
if (s != null) {
return s;
}
index = items[item];
return strings[item] = readUTF(index + 2, readUnsignedShort(index), buf);
}
/**
* Reads UTF8 string in {@link #b b}.
*
* @param index start offset of the UTF8 string to be read.
* @param utfLen length of the UTF8 string to be read.
* @param buf buffer to be used to read the string. This buffer must be
* sufficiently large. It is not automatically resized.
* @return the String corresponding to the specified UTF8 string.
*/
private String readUTF(int index, int utfLen, char[] buf) {
int endIndex = index + utfLen;
byte[] b = this.b;
int strLen = 0;
int c;
int st = 0;
char cc = 0;
while (index < endIndex) {
c = b[index++];
switch (st) {
case 0:
c = c & 0xFF;
if (c < 0x80) { // 0xxxxxxx
buf[strLen++] = (char) c;
} else if (c < 0xE0 && c > 0xBF) { // 110x xxxx 10xx xxxx
cc = (char) (c & 0x1F);
st = 1;
} else { // 1110 xxxx 10xx xxxx 10xx xxxx
cc = (char) (c & 0x0F);
st = 2;
}
break;
case 1: // byte 2 of 2-byte char or byte 3 of 3-byte char
buf[strLen++] = (char) ((cc << 6) | (c & 0x3F));
st = 0;
break;
case 2: // byte 2 of 3-byte char
cc = (char) ((cc << 6) | (c & 0x3F));
st = 1;
break;
}
}
return new String(buf, 0, strLen);
}
/**
* Reads a class constant pool item in {@link #b b}. This method is
* intended for {@link Attribute} sub classes, and is normally not needed by
* class generators or adapters.
*
* @param index the start index of an unsigned short value in {@link #b b},
* whose value is the index of a class constant pool item.
* @param buf buffer to be used to read the item. This buffer must be
* sufficiently large. It is not automatically resized.
* @return the String corresponding to the specified class item.
*/
public String readClass(int index, char[] buf) {
// computes the start index of the CONSTANT_Class item in b
// and reads the CONSTANT_Utf8 item designated by
// the first two bytes of this CONSTANT_Class item
return readUTF8(items[readUnsignedShort(index)], buf);
}
/**
* Reads a numeric or string constant pool item in {@link #b b}. This
* method is intended for {@link Attribute} sub classes, and is normally not
* needed by class generators or adapters.
*
* @param item the index of a constant pool item.
* @param buf buffer to be used to read the item. This buffer must be
* sufficiently large. It is not automatically resized.
* @return the {@link Integer}, {@link Float}, {@link Long}, {@link Double},
* {@link String}, {@link Type} or {@link Handle} corresponding to
* the given constant pool item.
*/
public Object readConst(int item, char[] buf) {
int index = items[item];
switch (b[index - 1]) {
case ClassWriter.INT:
return readInt(index);
case ClassWriter.FLOAT:
return Float.intBitsToFloat(readInt(index));
case ClassWriter.LONG:
return readLong(index);
case ClassWriter.DOUBLE:
return Double.longBitsToDouble(readLong(index));
case ClassWriter.CLASS:
return Type.getObjectType(readUTF8(index, buf));
case ClassWriter.STR:
return readUTF8(index, buf);
case ClassWriter.MTYPE:
return Type.getMethodType(readUTF8(index, buf));
//case ClassWriter.HANDLE_BASE + [1..9]:
default: {
int tag = readByte(index);
int[] items = this.items;
int cpIndex = items[readUnsignedShort(index + 1)];
String owner = readClass(cpIndex, buf);
cpIndex = items[readUnsignedShort(cpIndex + 2)];
String name = readUTF8(cpIndex, buf);
String desc = readUTF8(cpIndex + 2, buf);
return new Handle(tag, owner, name, desc);
}
}
}
}