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/*
 * Copyright (c) 2000, 2022, Oracle and/or its affiliates.
 *
 * Licensed under the Universal Permissive License v 1.0 as shown at
 * https://oss.oracle.com/licenses/upl.
 */

package com.tangosol.util;


import com.tangosol.coherence.config.Config;

import com.tangosol.internal.util.invoke.Lambdas;

import com.tangosol.io.ByteArrayReadBuffer;
import com.tangosol.io.ByteArrayWriteBuffer;
import com.tangosol.io.ClassLoaderAware;
import com.tangosol.io.DefaultSerializer;
import com.tangosol.io.DeltaCompressor;
import com.tangosol.io.ExternalizableLite;
import com.tangosol.io.InputStreaming;
import com.tangosol.io.MultiBufferReadBuffer;
import com.tangosol.io.MultiBufferWriteBuffer;
import com.tangosol.io.ObjectStreamFactory;
import com.tangosol.io.ReadBuffer;
import com.tangosol.io.ReadBuffer.BufferInput;
import com.tangosol.io.Resolving;
import com.tangosol.io.ResolvingObjectInputStream;
import com.tangosol.io.ResolvingObjectOutputStream;
import com.tangosol.io.SerializationSupport;
import com.tangosol.io.Serializer;
import com.tangosol.io.SerializerAware;
import com.tangosol.io.Utf8Reader;
import com.tangosol.io.WrapperBufferInput;
import com.tangosol.io.WrapperBufferOutput;
import com.tangosol.io.WrapperDataInputStream;
import com.tangosol.io.WrapperDataOutputStream;
import com.tangosol.io.WrapperObjectOutputStream;
import com.tangosol.io.WrapperOutputStream;
import com.tangosol.io.WriteBuffer;
import com.tangosol.io.WriteBuffer.BufferOutput;

import com.tangosol.io.pof.ConfigurablePofContext;
import com.tangosol.io.pof.PofContext;
import com.tangosol.io.pof.PofInputStream;
import com.tangosol.io.pof.PofOutputStream;
import com.tangosol.io.pof.RawDate;
import com.tangosol.io.pof.RawDateTime;
import com.tangosol.io.pof.RawTime;

import com.tangosol.net.CacheFactory;
import com.tangosol.net.NamedCache;

import com.tangosol.net.cache.CacheMap;

import com.tangosol.run.xml.SimpleParser;
import com.tangosol.run.xml.XmlBean;
import com.tangosol.run.xml.XmlDocument;
import com.tangosol.run.xml.XmlElement;
import com.tangosol.run.xml.XmlHelper;
import com.tangosol.run.xml.XmlSerializable;

import com.tangosol.util.function.Remote;

import java.lang.invoke.MethodHandle;
import java.lang.invoke.MethodHandles;
import java.lang.invoke.MethodType;

import java.io.DataInput;
import java.io.DataOutput;
import java.io.EOFException;
import java.io.FilterInputStream;
import java.io.InputStream;
import java.io.IOException;
import java.io.InvalidClassException;
import java.io.ObjectInput;
import java.io.ObjectInputStream;
import java.io.ObjectOutput;
import java.io.ObjectOutputStream;
import java.io.ObjectStreamException;
import java.io.OutputStream;
import java.io.PrintWriter;
import java.io.Serializable;
import java.io.StreamCorruptedException;
import java.io.StringWriter;
import java.io.UTFDataFormatException;

import java.lang.Math;
import java.lang.ref.WeakReference;

import java.lang.reflect.Array;
import java.lang.reflect.InvocationHandler;
import java.lang.reflect.InvocationTargetException;
import java.lang.reflect.Method;
import java.lang.reflect.Proxy;

import java.math.BigDecimal;
import java.math.BigInteger;

import java.net.URL;

import java.nio.BufferOverflowException;

import java.security.AccessController;
import java.security.PrivilegedAction;

import java.sql.Date;
import java.sql.Time;
import java.sql.Timestamp;

import java.util.ArrayList;
import java.util.Collection;
import java.util.Collections;
import java.util.ConcurrentModificationException;
import java.util.HashMap;
import java.util.Iterator;
import java.util.List;
import java.util.Map;
import java.util.NoSuchElementException;
import java.util.Optional;
import java.util.OptionalDouble;
import java.util.OptionalInt;
import java.util.OptionalLong;
import java.util.WeakHashMap;

import java.util.function.BinaryOperator;

/**
* Helpers for the Serializable, Externalizable and the ExternalizableLite
* interface.
* 

* Note: This class is configured via the * ExternalizableHelper.xml document located in the same package as * the class. The location of the configuration file can be overridden using * the {@link #PROPERTY_CONFIG coherence.externalizable.config} system * property. * * @author cp 2003.03.28 */ @SuppressWarnings("Duplicates") public abstract class ExternalizableHelper extends BitHelper { // ----- Serializable helpers ------------------------------------------- /** * Write an object to a byte array. * * @param o the object to write into a byte array * * @return a byte array containing the serialized form of the passed object * * @throws WrapperException may contain an IOException */ public static byte[] toByteArray(Object o) { return toByteArray(o, ensureSerializer(null)); } /** * Write an object to a byte array using the specified Serializer. * * @param o the object to write into a byte array * @param serializer the Serializer to use * * @return a byte array containing the serialized form of the passed object * * @throws WrapperException may contain an IOException */ public static byte[] toByteArray(Object o, Serializer serializer) { try { return serializeInternal(serializer, o, false).toByteArray(); } catch (IOException e) { throw ensureRuntimeException(e); } } /** * Convert a long to an 8-byte byte array. * * @param l the long to convert * @param ab the byte array to populate or null if a new byte array should * be created * * @return an 8-byte byte array that represents the given long * * @see #toLong(byte[]) */ public static byte[] toByteArray(long l, byte[] ab) { if (ab == null || ab.length < 8) { ab = new byte[8]; } // hi word int n = (int) (l >>> 32); ab[0] = (byte) (n >>> 24); ab[1] = (byte) (n >>> 16); ab[2] = (byte) (n >>> 8); ab[3] = (byte) (n); // lo word n = (int) l; ab[4] = (byte) (n >>> 24); ab[5] = (byte) (n >>> 16); ab[6] = (byte) (n >>> 8); ab[7] = (byte) (n); return ab; } /** * Convert a byte array to a long. * * @param ab the byte array to convert * * @return a long based on the provided byte array * * @see #toByteArray(long, byte[]) */ public static long toLong(byte[] ab) { return Byte.toUnsignedLong(ab[0]) << 56L | Byte.toUnsignedLong(ab[1]) << 48L | Byte.toUnsignedLong(ab[2]) << 40L | Byte.toUnsignedLong(ab[3]) << 32L | Byte.toUnsignedLong(ab[4]) << 24L | Byte.toUnsignedInt (ab[5]) << 16L | Byte.toUnsignedInt (ab[6]) << 8L | Byte.toUnsignedInt (ab[7]); } /** * Read an object from a byte array. * * @param ab the byte array containing the object * * @return the object deserialized from the byte array * * @throws WrapperException may contain an IOException */ public static Object fromByteArray(byte[] ab) { return fromByteArray(ab, null); } /** * Read an object from a byte array. * * @param ab the byte array containing the object * @param loader the ClassLoader to use * * @return the object deserialized from the byte array * * @throws WrapperException may contain an IOException */ public static Object fromByteArray(byte[] ab, ClassLoader loader) { try { return deserializeInternal(ensureSerializer(loader), new ByteArrayReadBuffer(ab), null /* supplier */, Object.class); } catch (IOException e) { throw ensureRuntimeException(e); } } /** * Write an object into a Binary object. * * @param o the object to write into a Binary object * * @return a Binary object containing a serialized form of the passed * object * * @throws WrapperException may contain an IOException */ public static Binary toBinary(Object o) { return toBinary(o, ensureSerializer(null)); } /** * Write an object into a Binary object using the specified Serializer. * * @param o the object to write into a Binary object * @param serializer the Serializer to use * * @return a Binary object containing a serialized form of the passed * object * * @throws WrapperException may contain an IOException */ public static Binary toBinary(Object o, Serializer serializer) { try { return serializeInternal(serializer, o, true).toBinary(); } catch (IOException e) { throw ensureRuntimeException(e); } } /** * Read an object from a Binary object. * * @param the class of the deserialized object * @param bin the Binary object containing the serialized object * * @return the object deserialized from the Binary object * * @throws WrapperException may contain an IOException */ public static T fromBinary(Binary bin) { return fromBinary(bin, ensureSerializer(null)); } /** * Read an object from a Binary object. * * @param the class of the deserialized object * @param bin the Binary object containing the serialized object * @param loader the ClassLoader to use * * @return the object deserialized from the Binary object * * @throws WrapperException may contain an IOException */ public static T fromBinary(Binary bin, ClassLoader loader) { return fromBinary(bin, ensureSerializer(loader)); } /** * Read an object from a Binary object using the specified Serializer. * * @param the class of the deserialized object * @param bin the Binary object containing the serialized object * @param serializer the Serializer to use * * @return the object deserialized from the Binary object * * @throws WrapperException may contain an IOException */ @SuppressWarnings("unchecked") public static T fromBinary(Binary bin, Serializer serializer) { return (T) fromBinary(bin, serializer, null, Object.class); } /** * Read an object from a Binary object using the specified Serializer and expected class. * * @param the class of the deserialized object * @param bin the Binary object containing the serialized object * @param serializer the Serializer to use * @param clazz deserialize object as an instance of this class * * @return the object deserialized from the Binary object * * @throws RuntimeException may contain an IOException */ public static T fromBinary(Binary bin, Serializer serializer, Class clazz) { return fromBinary(bin, serializer, null /* supplier */, clazz); } /** * Read an object from a Binary object using the specified Serializer. * * @param the class of the deserialized object * @param bin the Binary object containing the serialized object * @param serializer the Serializer to use * @param supplier an optional Function that given a BufferInput returns * either the same or another BufferInput * * @return the object deserialized from the Binary object * * @throws RuntimeException may contain an IOException */ public static T fromBinary(Binary bin, Serializer serializer, Remote.Function supplier) { try { return (T) deserializeInternal(serializer, bin, supplier, Object.class); } catch (IOException e) { throw new RuntimeException(e); } } /** * Read an object from a Binary object using the specified Serializer and expected class. * * @param the class of the deserialized object * @param bin the Binary object containing the serialized object * @param serializer the Serializer to use * @param supplier an optional Function that given a BufferInput returns * either the same or another BufferInput * @param clazz deserialize object as an instance of this class * * @return the object deserialized from the Binary object * * @throws RuntimeException may contain an IOException */ public static T fromBinary(Binary bin, Serializer serializer, Remote.Function supplier, Class clazz) { try { return deserializeInternal(serializer, bin, supplier, clazz); } catch (IOException e) { throw new RuntimeException(e); } } /** * Obtain a Serializer for the specified ClassLoader. This method is * intended to provide configurable indirection for the serialization of * application objects. * * @param loader a ClassLoader * * @return the Serializer to use with the specified ClassLoader */ public static Serializer ensureSerializer(ClassLoader loader) { loader = ensureClassLoader(loader); Map map = s_mapSerializerByClassLoader; Serializer serializer = (Serializer) map.get(loader); if (serializer == null) { serializer = USE_POF_STREAMS && loader != NullImplementation.getClassLoader() ? new ConfigurablePofContext() : new DefaultSerializer(); ((ClassLoaderAware) serializer).setContextClassLoader(loader); map.put(loader, serializer); } return serializer; } /** * Write an ExternalizableLite object into a Binary object. Unlike the * {@link #toBinary(Object) toBinary}, this method only serializes the * object's content and not the identity part. To reconstruct the object * frm that binary you would instantiate and "read" it as follows: *

     *   ExternalizableLite o = new MyLiteObject();
     *   o.readExternal(bin.getBufferInput());
     * 
* * @param o the ExternalizableLite object to write into a Binary object * * @return a Binary object containing a serialized form of the passed * object * * @throws WrapperException may contain an IOException */ public static Binary toLiteBinary(ExternalizableLite o) { try { WriteBuffer buffer = new BinaryWriteBuffer(64); o.writeExternal(buffer.getBufferOutput()); return buffer.toBinary(); } catch (IOException e) { throw ensureRuntimeException(e); } } /** * Determine whether the sender of the content (the given DataInput) * runs a version that supersedes (greater or equal to) the specified * version. * * @param in the DataInput to interrogate * @param nMajor the major version * @param nMinor the minor version * @param nMicro the micro version * @param nPatchSet the patch set version * @param nPatch the patch version * * @return true iff the sender's version is greater or equal to the * specified one * * @throws IllegalArgumentException if the DataInput is not a {@link * WrapperBufferInput.VersionAwareBufferInput VersionAwareBufferInput} */ public static boolean isVersionCompatible(DataInput in, int nMajor, int nMinor, int nMicro, int nPatchSet, int nPatch) { if (!(in instanceof WrapperBufferInput.VersionAwareBufferInput)) { throw new IllegalArgumentException("Unexpected DataInput"); } return ((WrapperBufferInput.VersionAwareBufferInput) in) .isVersionCompatible(nMajor, nMinor, nMicro, nPatchSet, nPatch); } /** * Determine whether all the recipients of the content (the given DataOutput) * run versions that supersede (greater or equal to) the specified * version. * * @param out the DataOutput to interrogate * @param nMajor the major version * @param nMinor the minor version * @param nMicro the micro version * @param nPatchSet the patch set version * @param nPatch the patch version * * @return true iff the sender's version is greater or equal to the * specified one * * @throws IllegalArgumentException if the DataOutput is not a {@link * WrapperBufferOutput.VersionAwareBufferOutput VersionAwareBufferOutput} */ public static boolean isVersionCompatible(DataOutput out, int nMajor, int nMinor, int nMicro, int nPatchSet, int nPatch) { if (!(out instanceof WrapperBufferOutput.VersionAwareBufferOutput)) { throw new IllegalArgumentException("Unexpected DataOutput"); } return ((WrapperBufferOutput.VersionAwareBufferOutput) out) .isVersionCompatible(nMajor, nMinor, nMicro, nPatchSet, nPatch); } // ----- Externalizable helpers ----------------------------------------- /** * Read a signed three-byte integer value from a stream. * * @param in DataInput stream to read from * * @return a three-byte signed integer value as an int * * @throws IOException if an I/O exception occurs */ public static int readTrint(DataInput in) throws IOException { int n; if (in instanceof PofInputStream) { n = in.readInt(); } else { n = (in.readUnsignedByte() << 16) | (in.readUnsignedByte() << 8) | (in.readUnsignedByte() ); if ((n & 0x800000) != 0) { // sign-extend the negative value to 4 bytes n |= 0xFF000000; } } return n; } /** * Read an unsigned three-byte integer value from a stream. * * @param in DataInput stream to read from * * @return a three-byte unsigned integer value as an int * * @throws IOException if an I/O exception occurs */ public static int readUnsignedTrint(DataInput in) throws IOException { int n; if (in instanceof PofInputStream) { n = in.readInt(); } else { n = (in.readUnsignedByte() << 16) | (in.readUnsignedByte() << 8) | (in.readUnsignedByte() ); } return n; } /** * Write a three-byte integer value to a stream. * * @param out DataOutput stream to write to * @param n a three-byte integer value passed as an int * * @throws IOException if an I/O exception occurs */ public static void writeTrint(DataOutput out, int n) throws IOException { if (out instanceof PofOutputStream) { out.writeInt(n); } else { out.writeByte(n >>> 16); out.writeByte(n >>> 8); out.writeByte(n ); } } /** * Write a three-byte integer value to a stream. * * @param out DataOutput stream to write to * @param l a three-byte integer value passed as an long * * @throws IOException if an I/O exception occurs */ public static void writeTrint(DataOutput out, long l) throws IOException { writeTrint(out, (int) (l & 0xFFFFFFL)); } /** * Convert a long integer to a trint. * * @param l the long value to convert to a trint * * @return the equivalent unsigned 3-byte integer value (a "trint") */ public static int makeTrint(long l) { return (int) (l & 0xFFFFFFL); } /** * Read an int that uses variable length storage in the buffer. * * @param in a BufferInput to read from * * @return an int value * * @throws IOException if an I/O exception occurs */ public static int readInt(BufferInput in) throws IOException { return in.readPackedInt(); } /** * Read an int that uses variable length storage in the stream. * * @param in a DataInput stream to read from * * @return an int value * * @throws IOException if an I/O exception occurs */ public static int readInt(DataInput in) throws IOException { int n; if (in instanceof BufferInput) { n = ((BufferInput) in).readPackedInt(); } else if (in instanceof PofInputStream) { n = in.readInt(); } else { // this is an inlined version of BufferInput#readPackedInt() int b = in.readUnsignedByte(); n = b & 0x3F; // 6 bits of data in first byte int cBits = 6; boolean fNeg = (b & 0x40) != 0; // seventh bit is a sign bit while ((b & 0x80) != 0) // eighth bit is the continuation bit { b = in.readUnsignedByte(); n |= ((b & 0x7F) << cBits); cBits += 7; } if (fNeg) { n = ~n; } } return n; } /** * Calculate the number of bytes needed to store a packed integer using * a variable-length format. *

* The format differs from DataOutput in that DataOutput always uses * a fixed-length 4-byte Big Endian binary format for int values. * The "packed" format includes a sign bit (0x40) and a continuation * bit (0x80) in the first byte, followed by the least 6 significant * bits of the int value. Subsequent bytes (each appearing only if * the previous byte had its continuation bit set) include a * continuation bit (0x80) and the next least 7 significant bits of * the int value. In this way, a 32-bit value is encoded into 1-5 * bytes, depending on the magnitude of the int value being encoded. * * @param n the value to calculate the packed length of * * @return the number of bytes needed to store the value */ public static int calculatePackedLength(int n) { if (n < 0) { n = ~n; } return n < 0x40 ? 1 : (0x27 - Integer.numberOfLeadingZeros(n)) / 7; } /** * Write an int to a buffer using a variable length of storage. * * @param out a BufferOutput to write to * @param n an int value to write * * @throws IOException if an I/O exception occurs */ public static void writeInt(BufferOutput out, int n) throws IOException { out.writePackedInt(n); } /** * Write an int to a stream using a variable length of storage. * * @param out a DataOutput stream to write to * @param n an int value to write * * @throws IOException if an I/O exception occurs */ public static void writeInt(DataOutput out, int n) throws IOException { if (out instanceof BufferOutput) { ((BufferOutput) out).writePackedInt(n); } else if (out instanceof PofOutputStream) { out.writeInt(n); } else { // this is an inlined version of BufferOutput#writePackedInt() // first byte contains sign bit (bit 7 set if neg) int b = 0; if (n < 0) { b = 0x40; n = ~n; } // first byte contains only 6 data bits b |= (byte) (n & 0x3F); n >>>= 6; while (n != 0) { b |= 0x80; // bit 8 is a continuation bit out.writeByte(b); b = (n & 0x7F); n >>>= 7; } // remaining byte out.writeByte(b); } } /** * Read a 2-dimensional int-array from the stream. * * @param in the input stream to read from * * @return the 2-dimensional int-array * * @throws IOException if an I/O Exception occurs */ public static int[][] readIntArray2d(DataInput in) throws IOException { int cSizeOuter = readInt(in); int cSizeInner = readInt(in); int[][] aai = new int[cSizeOuter][cSizeInner]; for (int i = 0; i < cSizeOuter; i++) { int[] ai = aai[i]; for (int j = 0; j < cSizeInner; j++) { ai[j] = readInt(in); } } return aai; } /** * Write a 2-dimensional int-array to the stream * * @param out the output stream to write to * @param aai the 2-dimensional int-array to write * * @throws IOException if an I/O Exception occurs * @throws NullPointerException if the array is null */ public static void writeIntArray2d(DataOutput out, int[][] aai) throws IOException { int cSizeOuter = aai.length; int cSizeInner = cSizeOuter == 0 ? 0 : aai[0].length; writeInt(out, cSizeOuter); writeInt(out, cSizeInner); for (int i = 0; i < cSizeOuter; i++) { int[] ai = aai[i]; for (int j = 0; j < cSizeInner; j++) { writeInt(out, ai[j]); } } } /** * Read a long that uses variable length storage in the buffer. * * @param in a DataInput stream to read from * * @return a long value * * @throws IOException if an I/O exception occurs */ public static long readLong(BufferInput in) throws IOException { return in.readPackedLong(); } /** * Read a long that uses variable length storage in the stream. * * @param in a DataInput stream to read from * * @return a long value * * @throws IOException if an I/O exception occurs */ public static long readLong(DataInput in) throws IOException { long l; if (in instanceof BufferInput) { l = ((BufferInput) in).readPackedLong(); } else if (in instanceof PofInputStream) { l = in.readLong(); } else { // this is an inlined version of BufferInput#readPackedLong() int b = in.readUnsignedByte(); l = b & 0x3F; // only 6 bits of data in first byte int cBits = 6; boolean fNeg = (b & 0x40) != 0; // seventh bit is a sign bit while ((b & 0x80) != 0) // eighth bit is the continuation bit { b = in.readUnsignedByte(); l |= (((long) (b & 0x7F)) << cBits); cBits += 7; } if (fNeg) { l = ~l; } } return l; } /** * Calculate the number of bytes needed to store a packed long using * a variable-length format. *

* The format differs from DataOutput in that DataOutput always uses * a fixed-length 8-byte Big Endian binary format for long values. * The "packed" format includes a sign bit (0x40) and a continuation * bit (0x80) in the first byte, followed by the least 6 significant * bits of the long value. Subsequent bytes (each appearing only if * the previous byte had its continuation bit set) include a * continuation bit (0x80) and the next least 7 significant bits of * the long value. In this way, a 64-bit value is encoded into 1-10 * bytes, depending on the magnitude of the long value being encoded. * * @param l the long value to calculate the packed length of * * @return the number of bytes needed to store the value */ public static int calculatePackedLength(long l) { if (l < 0) { l = ~l; } return l < 0x40 ? 1 : (0x47 - Long.numberOfLeadingZeros(l)) / 7; } /** * Write a long to a buffer using a variable length of storage. * * @param out a BufferOutput stream to write to * @param l a long value to write * * @throws IOException if an I/O exception occurs */ public static void writeLong(BufferOutput out, long l) throws IOException { out.writePackedLong(l); } /** * Write a long to a stream using a variable length of storage. * * @param out a DataOutput stream to write to * @param l a long value to write * * @throws IOException if an I/O exception occurs */ public static void writeLong(DataOutput out, long l) throws IOException { if (out instanceof BufferOutput) { ((BufferOutput) out).writePackedLong(l); } else if (out instanceof PofOutputStream) { out.writeLong(l); } else { // this is an inlined version of BufferOutput#writePackedLong() // first byte contains sign bit (bit 7 set if neg) int b = 0; if (l < 0) { b = 0x40; l = ~l; } // first byte contains only 6 data bits b |= (byte) (((int) l) & 0x3F); l >>>= 6; while (l != 0) { b |= 0x80; // bit 8 is a continuation bit out.writeByte(b); b = (((int) l) & 0x7F); l >>>= 7; } // remaining byte out.writeByte(b); } } /** * Read a packed boolean array. * * @param in a DataInput stream to read from * * @return a boolean array value * * @throws IOException if an I/O exception occurs */ public static boolean[] readBooleanArray(DataInput in) throws IOException { boolean[] af; if (in instanceof PofInputStream) { af = (boolean[]) ((PofInputStream) in).readObject(); } else { int c = readInt(in); validateLoadArray(boolean[].class, c, in); af = c < CHUNK_THRESHOLD ? readBooleanArray(in, c) : readLargeBooleanArray(in, c); } return af; } /** * Write a packed boolean array. * * @param out a DataOutput stream to write to * @param af a boolean array value to write * * @throws IOException if an I/O exception occurs * @throws NullPointerException if null value if passed */ public static void writeBooleanArray(DataOutput out, boolean[] af) throws IOException { if (out instanceof PofOutputStream) { ((PofOutputStream) out).writeObject(af); } else { int c = af.length; writeInt(out, c); for (int of = 0, cb = (c + 7) / 8, i = 0; of < cb; ++of) { int nBits = 0; for (int nMask = 1; i < c && nMask <= 0xFF; nMask <<= 1) { if (af[i++]) { nBits |= nMask; } } out.writeByte(nBits); } } } /** * Read a variable-length encoded byte array. * * @param in a DataInput stream to read from * * @return a byte array value * * @throws IOException if an I/O exception occurs */ public static byte[] readByteArray(DataInput in) throws IOException { byte[] ab; if (in instanceof PofInputStream) { ab = (byte[]) ((PofInputStream) in).readObject(); } else { int cb = readInt(in); validateLoadArray(byte[].class, cb, in); if (cb < CHUNK_THRESHOLD) { ab = new byte[cb]; in.readFully(ab); } else { ab = readLargeByteArray(in, cb); } } return ab; } /** * Write a variable-length encoded byte array. * * @param out a DataOutput stream to write to * @param ab a byte array value to write * * @throws IOException if an I/O exception occurs * @throws NullPointerException if null value if passed */ public static void writeByteArray(DataOutput out, byte[] ab) throws IOException { if (out instanceof PofOutputStream) { ((PofOutputStream) out).writeObject(ab); } else { int cb = ab.length; writeInt(out, cb); out.write(ab, 0, cb); } } /** * Read a variable-length encoded UTF packed String. The major difference * between this implementation and DataInputStream is that this is not * limited to 64KB String values. *

* Note: This format changed in Coherence 3.0; previously the leading * integer value was the number of characters, and currently it is the * number of bytes as per the java.io package implementations. * * @param in a DataInput stream to read from * * @return a String value * * @throws IOException if an I/O exception occurs */ public static String readUTF(DataInput in) throws IOException { String s; if (in instanceof BufferInput) { s = ((BufferInput) in).readSafeUTF(); } else if (in instanceof PofInputStream) { s = in.readUTF(); } else { int cb = readInt(in); if (cb < 0) { return null; } else if (cb == 0) { return ""; } validateLoadArray(byte[].class, cb, in); // get the "UTF binary" byte[] ab; if (cb < CHUNK_THRESHOLD) { ab = new byte[cb]; in.readFully(ab); } else { ab = readLargeByteArray(in, cb); } s = convertUTF(ab, 0, cb, new char[cb]); } return s; } /** * Convert binary UTF-8 encode data to a String. This method is a helper * to allow various I/O implementations to share a single, efficient * implementation. * * @param ab an array of bytes containing UTF-8 encoded characters * @param of the offset into the array of the UTF-8 data to decode * @param cb the binary length in the array of the UTF-8 data to decode * @param ach a temp char array large enough to convert the UTF into * * @return a String value * * @throws UTFDataFormatException if the UTF data is corrupt */ public static String convertUTF(byte[] ab, int of, int cb, char[] ach) throws UTFDataFormatException { // first run through the bytes determining if we have to // translate them at all (they might all be in the range 0-127) boolean fAscii = true; int ofch = 0; int ofAsc = of; int ofEnd = of + cb; for ( ; ofAsc < ofEnd; ++ofAsc) { int n = ab[ofAsc] & 0xFF; if (n >= 0x80) { // it's not all "ascii" data fAscii = false; break; } else { ach[ofch++] = (char) n; } } if (!fAscii) { for ( ; ofAsc < ofEnd; ++ofAsc) { int ch = ab[ofAsc] & 0xFF; switch ((ch & 0xF0) >>> 4) { case 0x0: case 0x1: case 0x2: case 0x3: case 0x4: case 0x5: case 0x6: case 0x7: // 1-byte format: 0xxx xxxx ach[ofch++] = (char) ch; break; case 0xC: case 0xD: { // 2-byte format: 110x xxxx, 10xx xxxx int ch2 = ab[++ofAsc] & 0xFF; if ((ch2 & 0xC0) != 0x80) { throw new UTFDataFormatException(); } ach[ofch++] = (char) (((ch & 0x1F) << 6) | ch2 & 0x3F); break; } case 0xE: { // 3-byte format: 1110 xxxx, 10xx xxxx, 10xx xxxx int ch2 = ab[++ofAsc] & 0xFF; int ch3 = ab[++ofAsc] & 0xFF; if ((ch2 & 0xC0) != 0x80 || (ch3 & 0xC0) != 0x80) { throw new UTFDataFormatException(); } ach[ofch++] = (char) (((ch & 0x0F) << 12) | ((ch2 & 0x3F) << 6) | ((ch3 & 0x3F) ) ); break; } default: throw new UTFDataFormatException( "illegal leading UTF byte: " + ch); } } } return new String(ach, 0, ofch); } /** * Write a variable-length encoded UTF packed String. The major difference * between this implementation and DataOutput stream is that this is not * limited to 64KB String values. *

* Note: This format changed in Coherence 3.0; previously the leading * integer value was the number of characters, and currently it is the * number of bytes as per the java.io package implementations. * * @param out a DataOutput stream to write to * @param s a String value to write * * @throws IOException if an I/O exception occurs * @throws NullPointerException if null value if passed */ public static void writeUTF(DataOutput out, String s) throws IOException { if (out instanceof BufferOutput) { ((BufferOutput) out).writeSafeUTF(s); } else if (out instanceof PofOutputStream) { out.writeUTF(s); } else { // this is an inlined version of BufferOutput#writeSafeUTF() if (s == null) { writeInt(out, -1); } else { int cch = s.length(); if (cch == 0) { writeInt(out, 0); } else { // calculate the length (in bytes) of the resulting UTF int cb = cch; for (int ofch = 0; ofch < cch; ++ofch) { int ch = s.charAt(ofch); if (ch <= 0x007F) { // all bytes in this range use the 1-byte format // except for 0 if (ch == 0) { ++cb; } } else { // either a 2-byte format or a 3-byte format (if // over 0x07FF) cb += (ch <= 0x07FF ? 1 : 2); } } // write the UTF header (the length) writeInt(out, cb); // get a temp buffer to write the UTF binary into byte[] ab = new byte[cb]; // write the UTF into the temp buffer if (cb == cch) { // ask the string to convert itself to ascii bytes s.getBytes(0, cch, ab, 0); } else { for (int ofch = 0, ofb = 0; ofch < cch; ++ofch) { int ch = s.charAt(ofch); if (ch >= 0x0001 && ch <= 0x007F) { // 1-byte format: 0xxx xxxx ab[ofb++] = (byte) ch; } else if (ch <= 0x07FF) { // 2-byte format: 110x xxxx, 10xx xxxx ab[ofb++] = (byte) (0xC0 | ((ch >>> 6) & 0x1F)); ab[ofb++] = (byte) (0x80 | ((ch ) & 0x3F)); } else { // 3-byte format: 1110 xxxx, 10xx xxxx, 10xx xxxx ab[ofb++] = (byte) (0xE0 | ((ch >>> 12) & 0x0F)); ab[ofb++] = (byte) (0x80 | ((ch >>> 6) & 0x3F)); ab[ofb++] = (byte) (0x80 | ((ch ) & 0x3F)); } } } // write the temp buffer to this WriteBuffer out.write(ab, 0, cb); } } } } /** * Read a variable-length encoded UTF packed String in the buffer. * * @param in a BufferInput to read from * * @return a String value * * @throws IOException if an I/O exception occurs */ public static String readSafeUTF(BufferInput in) throws IOException { return in.readSafeUTF(); } /** * Read a variable-length encoded UTF packed String. The major difference * between this implementation and DataInputStream is that this is not * limited to 64KB String values and allows null value. *

* Note: This format changed in Coherence 3.0; previously the leading * integer value was the number of characters, and currently it is the * number of bytes as per the java.io package implementations. * * @param in a DataInput stream to read from * * @return a String value (could be null) * * @throws IOException if an I/O exception occurs */ public static String readSafeUTF(DataInput in) throws IOException { return readUTF(in); } /** * Write a variable-length encoded UTF packed String to the buffer. * * @param out a BufferOutput to write to * @param s a String value to write * * @throws IOException if an I/O exception occurs * @throws NullPointerException if null value if passed */ public static void writeSafeUTF(BufferOutput out, String s) throws IOException { out.writeSafeUTF(s); } /** * Write a variable-length encoded UTF packed String. The major difference * between this implementation and DataOutput stream is that this is not * limited to 64KB String values and allows null value. *

* Note: This format changed in Coherence 3.0; previously the leading * integer value was the number of characters, and currently it is the * number of bytes as per the java.io package implementations. * * @param out a DataOutput stream to write to * @param s a String value to write (could be null) * * @throws IOException if an I/O exception occurs */ public static void writeSafeUTF(DataOutput out, String s) throws IOException { writeUTF(out, s); } /** * Read a String array. * * @param in a DataInput stream to read from * * @return a String array value * * @throws IOException if an I/O exception occurs */ public static String[] readStringArray(DataInput in) throws IOException { String[] as; if (in instanceof PofInputStream) { Object[] ao = (Object[]) ((PofInputStream) in).readObject(); if (ao == null) { as = null; } else { int co = ao.length; as = new String[co]; System.arraycopy(ao, 0, as, 0, co); } } else { int c = readInt(in); validateLoadArray(String[].class, c, in); as = c < CHUNK_THRESHOLD >> 3 ? readStringArray(in, c) : readLargeStringArray(in, c); } return as; } /** * Write a String array. * * @param out a DataOutput stream to write to * @param as a String array to write * * @throws IOException if an I/O exception occurs * @throws NullPointerException if null value if passed */ public static void writeStringArray(DataOutput out, String[] as) throws IOException { if (out instanceof PofOutputStream) { ((PofOutputStream) out).writeObject(as); } else { int c = as.length; writeInt(out, c); for (int i = 0; i < c; ++i) { writeSafeUTF(out, as[i]); } } } /** * Read a BigInteger from a DataInput stream. * * @param in a DataInput stream to read from * * @return a BigInteger value * * @throws IOException if an I/O exception occurs */ public static BigInteger readBigInteger(DataInput in) throws IOException { BigInteger n; if (in instanceof PofInputStream) { n = (BigInteger) ((PofInputStream) in).readObject(); } else { n = new BigInteger(readByteArray(in)); } return n; } /** * Write a BigInteger to a DataOutput stream. * * @param out a DataOutput stream to write to * @param bigint a BigInteger value to write * * @throws IOException if an I/O exception occurs * @throws NullPointerException if null value if passed */ public static void writeBigInteger(DataOutput out, BigInteger bigint) throws IOException { if (out instanceof PofOutputStream) { ((PofOutputStream) out).writeObject(bigint); } else { writeByteArray(out, bigint.toByteArray()); } } /** * Read a BigDecimal from a DataInput stream. * * @param in a DataInput stream to read from * * @return a BigDecimal value * * @throws IOException if an I/O exception occurs */ public static BigDecimal readBigDecimal(DataInput in) throws IOException { BigDecimal dec; if (in instanceof PofInputStream) { dec = (BigDecimal) ((PofInputStream) in).readObject(); } else { dec = new BigDecimal(readBigInteger(in), readInt(in)); } return dec; } /** * Write a BigDecimal to a DataOutput stream. * * @param out a DataOutput stream to write to * @param dec a BigDecimal value to write * * @throws IOException if an I/O exception occurs * @throws NullPointerException if null value if passed */ public static void writeBigDecimal(DataOutput out, BigDecimal dec) throws IOException { if (out instanceof PofOutputStream) { ((PofOutputStream) out).writeObject(dec); } else { writeBigInteger(out, dec.unscaledValue()); writeInt(out, dec.scale()); } } /** * Read a Date from a DataInput stream. * * @param in a DataInput stream to read from * * @return a Date value * * @throws IOException if an I/O exception occurs */ public static Date readDate(DataInput in) throws IOException { Date date; if (in instanceof PofInputStream) { PofInputStream inPof = (PofInputStream) in; RawDate dateRaw = inPof.getPofReader().readRawDate(inPof.nextIndex()); date = dateRaw == null ? null : dateRaw.toSqlDate(); } else { date = new Date(readLong(in)); } return date; } /** * Write a Date to a DataOutput stream. * * @param out a DataOutput stream to write to * @param date a Date value to write * * @throws IOException if an I/O exception occurs * @throws NullPointerException if null value if passed */ public static void writeDate(DataOutput out, Date date) throws IOException { if (out instanceof PofOutputStream) { ((PofOutputStream) out).writeObject(date); } else { writeLong(out, date.getTime()); } } /** * Read a Time from a DataInput stream. * * @param in a DataInput stream to read from * * @return a Time value * * @throws IOException if an I/O exception occurs */ public static Time readTime(DataInput in) throws IOException { Time time; if (in instanceof PofInputStream) { PofInputStream inPof = (PofInputStream) in; RawTime timeRaw = inPof.getPofReader().readRawTime(inPof.nextIndex()); time = timeRaw == null ? null : timeRaw.toSqlTime(); } else { time = new Time(readLong(in)); } return time; } /** * Write a Time to a DataOutput stream. * * @param out a DataOutput stream to write to * @param time a Time value to write * * @throws IOException if an I/O exception occurs * @throws NullPointerException if null value if passed */ public static void writeTime(DataOutput out, Time time) throws IOException { if (out instanceof PofOutputStream) { PofOutputStream outPof = (PofOutputStream) out; outPof.getPofWriter().writeTimeWithZone(outPof.nextIndex(), time); } else { writeLong(out, time.getTime()); } } /** * Read a Timestamp from a DataInput stream. * * @param in a DataInput stream to read from * * @return a Timestamp value * * @throws IOException if an I/O exception occurs */ public static Timestamp readTimestamp(DataInput in) throws IOException { Timestamp dt; if (in instanceof PofInputStream) { PofInputStream inPof = (PofInputStream) in; RawDateTime dtRaw = inPof.getPofReader().readRawDateTime(inPof.nextIndex()); dt = dtRaw == null ? null : dtRaw.toSqlTimestamp(); } else { dt = new Timestamp(readLong(in)); dt.setNanos(readInt(in)); } return dt; } /** * Write a Timestamp to a DataOutput stream. * * @param out a DataOutput stream to write to * @param dt a Timestamp value to write * * @throws IOException if an I/O exception occurs * @throws NullPointerException if null value if passed */ public static void writeTimestamp(DataOutput out, Timestamp dt) throws IOException { if (out instanceof PofOutputStream) { PofOutputStream outPof = (PofOutputStream) out; outPof.getPofWriter().writeDateTimeWithZone(outPof.nextIndex(), dt); } else { writeLong(out, dt.getTime()); writeInt(out, dt.getNanos()); } } /** * Read an array of float numbers from a DataInput stream. * * @param in a DataInput stream to read from * * @return an array of floats * * @throws IOException if an I/O exception occurs */ public static float[] readFloatArray(DataInput in) throws IOException { float[] afl; if (in instanceof PofInputStream) { afl = (float[]) ((PofInputStream) in).readObject(); } else { int cfl = in.readInt(); validateLoadArray(float[].class, cfl, in); afl = cfl < CHUNK_THRESHOLD >> 2 ? readFloatArray(in, cfl) : readLargeFloatArray(in, cfl); } return afl; } /** * Write an array of float numbers to a DataOutput stream. * * @param out a DataOutput stream to write to * @param afl an array of floats to write * * @throws IOException if an I/O exception occurs * @throws NullPointerException if null value if passed */ public static void writeFloatArray(DataOutput out, float[] afl) throws IOException { if (out instanceof PofOutputStream) { ((PofOutputStream) out).writeObject(afl); } else { int cfl = afl.length; out.writeInt(cfl); if (cfl > 0) { byte[] ab = new byte[cfl << 2]; for (int i = 0, of = 0; i < cfl; i++) { int iValue = Float.floatToIntBits(afl[i]); ab[of++] = (byte)(iValue >>> 24); ab[of++] = (byte)(iValue >>> 16); ab[of++] = (byte)(iValue >>> 8); ab[of++] = (byte)(iValue); } out.write(ab); } } } /** * Read an array of double numbers from a DataInput stream. * * @param in a DataInput stream to read from * * @return an array of doubles * * @throws IOException if an I/O exception occurs */ public static double[] readDoubleArray(DataInput in) throws IOException { double[] adbl; if (in instanceof PofInputStream) { adbl = (double[]) ((PofInputStream) in).readObject(); } else { int c = in.readInt(); validateLoadArray(float[].class, c, in); adbl = c <= 0 ? new double[0] : c < CHUNK_THRESHOLD >> 3 ? readDoubleArray(in, c) : readLargeDoubleArray(in, c); } return adbl; } /** * Write an array of double numbers to a DataOutput stream. * * @param out a DataOutput stream to write to * @param ad an array of doubles to write * * @throws IOException if an I/O exception occurs * @throws NullPointerException if null value if passed */ public static void writeDoubleArray(DataOutput out, double[] ad) throws IOException { if (out instanceof PofOutputStream) { ((PofOutputStream) out).writeObject(ad); } else { int cd = ad.length; out.writeInt(cd); if (cd > 0) { byte[] ab = new byte[cd << 3]; for (int i = 0, of = 0; i < cd; i++) { long lValue = Double.doubleToLongBits(ad[i]); int iUpper = (int) (lValue >>> 32); int iLower = (int) lValue; ab[of++] = (byte)(iUpper >>> 24); ab[of++] = (byte)(iUpper >>> 16); ab[of++] = (byte)(iUpper >>> 8); ab[of++] = (byte)(iUpper); ab[of++] = (byte)(iLower >>> 24); ab[of++] = (byte)(iLower >>> 16); ab[of++] = (byte)(iLower >>> 8); ab[of++] = (byte)(iLower); } out.write(ab); } } } /** * Read map content from a DataInput stream and update the specified map. *

* This method reads entries from the stream and "puts" them into the * specified map one-by-one using the "put" method. * * @param in a DataInput stream to read from * @param map a map to add the entries into * @param loader the ClassLoader to use * * @return the number of read and inserted entries * * @throws IOException if an I/O exception occurs * * @see #readMap(DataInput, Map, int, ClassLoader) */ public static int readMap(DataInput in, Map map, ClassLoader loader) throws IOException { int cEntries; if (in instanceof PofInputStream) { PofInputStream inPof = (PofInputStream) in; inPof.getPofReader().readMap(inPof.nextIndex(), map); cEntries = map.size(); } else { cEntries = in.readInt(); for (int i = 0; i < cEntries; ++i) { Object oKey = readObject(in, loader); Object oVal = readObject(in, loader); map.put(oKey, oVal); } } return cEntries; } /** * Read map content from a DataInput stream and update the specified map * using the "putAll" method. *

* While the method {@link #readMap(DataInput, Map, ClassLoader)} reads * entries from the stream and "puts" them into the specified map * one-by-one, this method collects up to the "block" number of entries * into a temporary map and then updates the passed in map using the * "putAll" method. * * @param in a DataInput stream to read from * @param map a map to add the entries into * @param cBlock the maximum number of entries to read at once * @param loader the ClassLoader to use * * @return the number of read and inserted entries * * @throws IOException if an I/O exception occurs */ public static int readMap(DataInput in, Map map, int cBlock, ClassLoader loader) throws IOException { int cEntries; if (in instanceof PofInputStream) { PofInputStream inPof = (PofInputStream) in; Map mapTemp = inPof.getPofReader().readMap(inPof.nextIndex(), (Map) null); if (mapTemp == null) { cEntries = 0; } else { cEntries = mapTemp.size(); map.putAll(mapTemp); } } else { if (cBlock <= 0) { throw new IllegalArgumentException("Illegal block size: " + cBlock); } cEntries = in.readInt(); Map mapTmp = new HashMap(Math.min(cEntries, cBlock)); int cTmp = 0; for (int i = 0; i < cEntries; ++i) { Object oKey = readObject(in, loader); Object oVal = readObject(in, loader); mapTmp.put(oKey, oVal); if (++cTmp == cBlock) { map.putAll(mapTmp); mapTmp.clear(); cTmp = 0; } } if (cTmp > 0) { map.putAll(mapTmp); } } return cEntries; } /** * Write map content to a DataOutput stream. * * @param out a DataOutput stream to write to * @param map the map to write * * @throws IOException if an I/O exception occurs */ public static void writeMap(DataOutput out, Map map) throws IOException { if (out instanceof PofOutputStream) { ((PofOutputStream) out).writeObject(map); } else { int cEntries = map.size(); int cCheck = 0; out.writeInt(cEntries); try { for (Iterator iter = map.entrySet().iterator(); iter.hasNext(); ++cCheck) { Map.Entry entry = (Map.Entry) iter.next(); writeObject(out, entry.getKey()); writeObject(out, entry.getValue()); } } catch (ConcurrentModificationException e) {} catch (NoSuchElementException e) {} if (cCheck != cEntries) { throw new IOException("Expected to write " + cEntries + " objects but actually wrote " + cCheck); } } } /** * Read collection content from a DataInput stream and update the * specified collection. *

* This method reads elements from the stream and adds them into the * specified collection one-by-one using the "add" method. * * @param in a DataInput stream to read from * @param collection a collection to add the elements into * @param loader the ClassLoader to use * * @return the number of read and inserted elements * * @throws IOException if an I/O exception occurs */ public static int readCollection(DataInput in, Collection collection, ClassLoader loader) throws IOException { int cItems; if (in instanceof PofInputStream) { PofInputStream inPof = (PofInputStream) in; inPof.getPofReader().readCollection(inPof.nextIndex(), collection); cItems = collection.size(); } else { cItems = in.readInt(); for (int i = 0; i < cItems; ++i) { collection.add(readObject(in, loader)); } } return cItems; } /** * Write collection content to a DataOutput stream. * * @param out a DataOutput stream to write to * @param collection the collection to write * * @throws IOException if an I/O exception occurs */ public static void writeCollection(DataOutput out, Collection collection) throws IOException { if (out instanceof PofOutputStream) { ((PofOutputStream) out).writeObject(collection); } else { int cItems = collection.size(); int cCheck = 0; out.writeInt(cItems); try { for (Iterator iter = collection.iterator(); iter.hasNext(); ++cCheck) { writeObject(out, iter.next()); } } catch (ConcurrentModificationException e) {} catch (NoSuchElementException e) {} if (cCheck != cItems) { throw new IOException("Expected to write " + cItems + " objects but actually wrote " + cCheck); } } } /** * Read an XmlSerializable object from a DataInput stream. * * @param in a DataInput stream to read from * * @return an XmlSerializable value * * @throws IOException if an I/O exception occurs */ public static XmlSerializable readXmlSerializable(DataInput in) throws IOException { return readXmlSerializable(in, null); } /** * Read an XmlSerializable object from a DataInput stream. * * @param in a DataInput stream to read from * @param loader the ClassLoader to use * * @return an XmlSerializable value * * @throws IOException if an I/O exception occurs */ public static XmlSerializable readXmlSerializable(DataInput in, ClassLoader loader) throws IOException { XmlSerializable value; if (in instanceof PofInputStream) { value = (XmlSerializable) ((PofInputStream) in).readObject(); } else { // instantiate the object String sClass = readUTF(in); try { value = (XmlSerializable) loadClass(sClass, loader, null).newInstance(); } catch (Exception e) { throw new IOException( "Class initialization failed: " + e + "\n" + getStackTrace(e) + "\nClass: " + sClass + "\nClassLoader: " + loader + "\nContextClassLoader: " + getContextClassLoader()); } String sXml = readUTF(in); // Bug 32341371 - Do not validate the XML to prevent XXE (XML eXternal Entity) injection XmlElement xml = new SimpleParser(/* fValidate */ false).parseXml(sXml); value.fromXml(xml); } return value; } /** * Write an XmlSerializable object to a DataOutput stream. * * @param out a DataOutput stream to write to * @param o an XmlSerializable value to write * * @throws IOException if an I/O exception occurs * @throws NullPointerException if null value if passed */ public static void writeXmlSerializable(DataOutput out, XmlSerializable o) throws IOException { if (out instanceof PofOutputStream) { ((PofOutputStream) out).writeObject(o); } else { StringWriter writerRaw = new StringWriter(); PrintWriter writerPrn = new PrintWriter(writerRaw); o.toXml().writeXml(writerPrn, false); writerPrn.close(); writeUTF(out, o.getClass().getName()); writeUTF(out, writerRaw.toString()); } } /** * Read an ExternalizableLite object from a DataInput stream. * * @param in a DataInput stream to read from * * @return an ExternalizableLite value * * @throws IOException if an I/O exception occurs */ public static ExternalizableLite readExternalizableLite(DataInput in) throws IOException { return readExternalizableLite(in, null); } /** * Read an ExternalizableLite object from a DataInput stream. * * @param in a DataInput stream to read from * @param loader the ClassLoader to use * * @return an ExternalizableLite value * * @throws IOException if an I/O exception occurs */ public static ExternalizableLite readExternalizableLite(DataInput in, ClassLoader loader) throws IOException { ExternalizableLite value; if (in instanceof PofInputStream) { value = (ExternalizableLite) ((PofInputStream) in).readObject(); } else { // instantiate the object String sClass = readUTF(in); WrapperDataInputStream inWrapper = in instanceof WrapperDataInputStream ? (WrapperDataInputStream) in : null; try { Class clz = loadClass(sClass, loader, inWrapper == null ? null : inWrapper.getClassLoader()); validateLoadClass(clz, in); value = (ExternalizableLite) clz.newInstance(); } catch (InstantiationException e) { throw new IOException( "Unable to instantiate an instance of class '" + sClass + "'; this is most likely due to a missing public " + "no-args constructor: " + e + "\n" + getStackTrace(e) + "\nClass: " + sClass + "\nClassLoader: " + loader + "\nContextClassLoader: " + getContextClassLoader()); } catch (Exception e) { throw new IOException( "Class initialization failed: " + e + "\n" + getStackTrace(e) + "\nClass: " + sClass + "\nClassLoader: " + loader + "\nContextClassLoader: " + getContextClassLoader(), e); } if (loader != null) { if (inWrapper == null) { in = new WrapperDataInputStream(in, loader); } else if (loader != inWrapper.getClassLoader()) { inWrapper.setClassLoader(loader); } } value.readExternal(in); if (value instanceof SerializerAware) { ((SerializerAware) value).setContextSerializer(ensureSerializer(loader)); } } return value; } /** * Validate that the given class is permitted to be deserialized by * consulting any associated ObjectInputFilters. * * @param clz the class to be validated * @param in input context to use to validate if class is allowed to be loaded * * @throws InvalidClassException if ObjectInputFilter associated with * in rejects class clz */ protected static void validateLoadClass(Class clz, DataInput in) throws InvalidClassException { if (!checkObjectInputFilter(clz, in)) { throw new InvalidClassException("Deserialization of class " + clz.getName() + " was rejected"); } } /** * Validate that the given class and array length is permitted to be deserialized by * consulting any associated ObjectInputFilters. * * @param clz the array type to be validated * @param cLength the array length to be validated * @param in input context to use to validate if class is allowed to be loaded * * @throws InvalidClassException if ObjectInputFilter associated with * in rejects array length */ public static void validateLoadArray(Class clz, int cLength, DataInput in) throws InvalidClassException { if (!checkObjectInputFilter(clz, cLength, in)) { throw new InvalidClassException("Deserialization of class " + clz.getName() + " with array length " + cLength + " was rejected"); } } /** * Write an ExternalizableLite object to a DataOutput stream. * * @param out a DataOutput stream to write to * @param o an ExternalizableLite value to write * * @throws IOException if an I/O exception occurs * @throws NullPointerException if null value if passed */ public static void writeExternalizableLite(DataOutput out, ExternalizableLite o) throws IOException { if (out instanceof PofOutputStream) { ((PofOutputStream) out).writeObject(o); } else { writeUTF(out, o.getClass().getName()); o.writeExternal(out); } } /** * Read an XmlBean object from a DataInput stream. * * @param in a DataInput stream to read from * @param loader the ClassLoader to use * * @return an XmlBean value * * @throws IOException if an I/O exception occurs */ public static XmlBean readXmlBean(DataInput in, ClassLoader loader) throws IOException { XmlBean bean; if (in instanceof PofInputStream) { bean = (XmlBean) ((PofInputStream) in).readObject(); } else if (USE_XMLBEAN_CLASS_CACHE) { int nBeanId = readInt(in); if (nBeanId < 0) { // this XmlBean is not serialization-optimized bean = (XmlBean) readExternalizableLite(in, loader); } else { try { Class clz = XMLBEAN_CLASS_CACHE.getClass(nBeanId, loader); validateLoadClass(clz, in); bean = (XmlBean) clz.newInstance(); } catch (Exception e) { throw new IOException( "Class instantiation failed: " + e + "\n" + getStackTrace(e) + "\nXmlBean ID: " + nBeanId + "\nClassLoader: " + loader + "\nContextClassLoader: " + getContextClassLoader()); } bean.readExternal(in); } } else { bean = (XmlBean) readExternalizableLite(in, loader); } return bean; } /** * Write an XmlBean object to a DataOutput stream. * * @param out a DataOutput stream to write to * @param bean an XmlBean value to write * * @throws IOException if an I/O exception occurs * @throws NullPointerException if null value if passed */ public static void writeXmlBean(DataOutput out, XmlBean bean) throws IOException { if (out instanceof PofOutputStream) { ((PofOutputStream) out).writeObject(bean); } else if (USE_XMLBEAN_CLASS_CACHE) { int nBeanId = bean.getBeanInfo().getBeanId(); writeInt(out, nBeanId); if (nBeanId < 0) { // this XmlBean is not serialization-optimized writeExternalizableLite(out, bean); } else { bean.writeExternal(out); } } else { writeExternalizableLite(out, bean); } } /** * Read an object from a DataInput stream. * * @param in a DataInput stream to read from * * @return a value object * * @throws IOException if an I/O exception occurs */ public static Object readSerializable(DataInput in) throws IOException { return readSerializable(in, null); } /** * Read an object from a DataInput stream. * * @param in a DataInput stream to read from * @param loader the ClassLoader to use * * @return a value object * * @throws IOException if an I/O exception occurs */ public static Object readSerializable(DataInput in, ClassLoader loader) throws IOException { Object o; if (in instanceof PofInputStream) { o = ((PofInputStream) in).readObject(); } else { // read the object; theoretically speaking only the following // exceptions are thrown: // // ClassNotFoundException Class of a serialized object // cannot be found // InvalidClassException Something is wrong with a class // used by serialization // StreamCorruptedException Control information in the stream // is inconsistent // OptionalDataException Primitive data was found in the // stream instead of objects // IOException Any of the usual Input/Output // related exceptions // // However, ClassCastException and IndexOutOfBoundsException // could be thrown as well, so to make the processing logic more // consistent we convert them all into a generic IOException. // (After all, it is the "read from stream" that fails.) ObjectInput streamObj = getObjectInput(in, loader); try { o = streamObj.readObject(); if (o instanceof SerializerAware) { ((SerializerAware) o).setContextSerializer(ensureSerializer(loader)); } } catch (IOException e) { throw e; } catch (Exception e) { throw new IOException( "readObject failed: " + e + "\n" + getStackTrace(e) + "\nClassLoader: " + loader); } } return o; } /** * Write an object to a DataOutput stream. * * @param out a DataOutput stream to write to * @param o a value object to write * * @throws IOException if an I/O exception occurs */ public static void writeSerializable(DataOutput out, Object o) throws IOException { if (out instanceof PofOutputStream) { ((PofOutputStream) out).writeObject(o); } else { ObjectOutput streamObj = getObjectOutput(out); streamObj.writeObject(o); streamObj.close(); } } /** * Read an Object from the passed DataInput object. * * @param the class of the object read * @param in the DataInput stream to read an object from * * @return the object read from the DataInput; may be null * * @throws IOException if an I/O exception occurs */ public static T readObject(DataInput in) throws IOException { return readObject(in, null); } /** * Read an Object from the passed DataInput object. * * @param the class of the object read * @param in the DataInput stream to read an object from * @param loader the ClassLoader to use * * @return the object read from the DataInput; may be null * * @throws IOException if an I/O exception occurs */ @SuppressWarnings("unchecked") public static T readObject(DataInput in, ClassLoader loader) throws IOException { if (in instanceof PofInputStream) { return (T) ((PofInputStream) in).readObject(); } Object o = readObjectInternal(in, in.readUnsignedByte(), loader); return (T) safeRealize(o, ensureSerializer(loader), in); } /** * {@link #realize(Object, Serializer) Realize} deserialized instance o for possible replacement. * If replacement occurs, the replacement's class is validated against {@link DataInput} in's ObjectInputFilter. * * @param o deserialized instance * @param serializer the serializer * @param in DataInput context * @param replacement type * * @return either deserialized instance o or its {@link SerializationSupport#readResolve} replacement. * * @throws IOException if ObjectInputFilter associated with in rejects a replacements class */ private static T safeRealize(Object o, Serializer serializer, DataInput in) throws IOException { T oReplace = (T) realize(o, serializer); if (o != oReplace && oReplace != null && o.getClass() != oReplace.getClass()) { // validate the replacement against the ObjectInputFilter if (oReplace.getClass().isArray()) { validateLoadArray(oReplace.getClass(), Array.getLength(oReplace), in); } else { validateLoadClass(oReplace.getClass(), in); } } return oReplace; } /** * Read an object of a known type from the specified DataInput. */ private static Object readObjectInternal(DataInput in, int nType, ClassLoader loader) throws IOException { switch (nType) { default: throw new StreamCorruptedException("invalid type: " + nType); case FMT_UNKNOWN: // while exactly the same as FMT_OBJ_SER, we want to have a // distinct stack trace in a case of failure return readSerializable(in, loader); case FMT_NULL: return null; case FMT_INT: return Integer.valueOf(readInt(in)); case FMT_LONG: return Long.valueOf(readLong(in)); case FMT_STRING: return readUTF(in); case FMT_DOUBLE: return new Double(in.readDouble()); case FMT_INTEGER: return readBigInteger(in); case FMT_DECIMAL: return readBigDecimal(in); case FMT_BINARY: { Binary bin = new Binary(); bin.readExternal(in); return bin; } case FMT_B_ARRAY: return readByteArray(in); case FMT_XML_SER: return readXmlSerializable(in, loader); case FMT_OBJ_EXT: return readExternalizableLite(in, loader); case FMT_OBJ_SER: return readSerializable(in, loader); case FMT_OPT: return in.readBoolean() ? Optional.of(readObject(in)) : Optional.empty(); case FMT_OPT_INT: return in.readBoolean() ? OptionalInt.of(readInt(in)) : OptionalInt.empty(); case FMT_OPT_LONG: return in.readBoolean() ? OptionalLong.of(readLong(in)) : OptionalLong.empty(); case FMT_OPT_DOUBLE: return in.readBoolean() ? OptionalDouble.of(in.readDouble()) : OptionalDouble.empty(); case FMT_XML_BEAN: return readXmlBean(in, loader); case FMT_FLOAT: return new Float(in.readFloat()); case FMT_SHORT: return new Short(in.readShort()); case FMT_BYTE: return new Byte(in.readByte()); case FMT_BOOLEAN: return in.readBoolean() ? Boolean.TRUE : Boolean.FALSE; } } /** * Write the specified data to the passed DataOutput object. * * @param out the DataOutput stream to write to * @param o the data to write to the DataOutput; may be null * * @throws IOException if an I/O exception occurs */ public static void writeObject(DataOutput out, Object o) throws IOException { if (out instanceof PofOutputStream) { ((PofOutputStream) out).writeObject(o); } else { o = replace(o); int nType = getStreamFormat(o); out.writeByte(nType); switch (nType) { case FMT_UNKNOWN: // while the same as FMT_OBJ_SER, we want to have a distinct // stack trace in a case of failure writeSerializable(out, o); break; case FMT_NULL: // no data to write break; case FMT_INT: writeInt(out, ((Integer) o).intValue()); break; case FMT_LONG: writeLong(out, ((Long) o).longValue()); break; case FMT_STRING: writeUTF(out, (String) o); break; case FMT_DOUBLE: out.writeDouble(((Double) o).doubleValue()); break; case FMT_INTEGER: writeBigInteger(out, (BigInteger) o); break; case FMT_DECIMAL: writeBigDecimal(out, (BigDecimal) o); break; case FMT_BINARY: Binary.writeExternal(out, (ReadBuffer) o); break; case FMT_B_ARRAY: writeByteArray(out, (byte[]) o); break; case FMT_XML_SER: writeXmlSerializable(out, (XmlSerializable) o); break; case FMT_OBJ_EXT: writeExternalizableLite(out, (ExternalizableLite) o); break; case FMT_OBJ_SER: writeSerializable(out, o); break; case FMT_XML_BEAN: writeXmlBean(out, (XmlBean) o); break; case FMT_OPT: { Optional opt = (Optional) o; boolean fPresent = opt.isPresent(); out.writeBoolean(fPresent); if (fPresent) { writeObject(out, opt.get()); } } break; case FMT_OPT_INT: { OptionalInt opt = (OptionalInt) o; boolean fPresent = opt.isPresent(); out.writeBoolean(fPresent); if (fPresent) { writeInt(out, opt.getAsInt()); } } break; case FMT_OPT_LONG: { OptionalLong opt = (OptionalLong) o; boolean fPresent = opt.isPresent(); out.writeBoolean(fPresent); if (fPresent) { writeLong(out, opt.getAsLong()); } } break; case FMT_OPT_DOUBLE: { OptionalDouble opt = (OptionalDouble) o; boolean fPresent = opt.isPresent(); out.writeBoolean(fPresent); if (fPresent) { out.writeDouble(opt.getAsDouble()); } } break; case FMT_FLOAT: out.writeFloat(((Float) o).floatValue()); break; case FMT_SHORT: out.writeShort(((Short) o).shortValue()); break; case FMT_BYTE: out.writeByte(((Byte) o).byteValue()); break; case FMT_BOOLEAN: out.writeBoolean(((Boolean) o).booleanValue()); break; default: throw azzert(); } } } /** * Serialize the passed object into a buffer created for that purpose. * * @param serializer the serializer to use * @param o the object to write * @param fBinary pass true to prefer a buffer type that is optimized for * producing a Binary result * * @return the WriteBuffer that was created to hold the serialized form of * the object * * @throws IOException if an I/O exception occurs */ private static WriteBuffer serializeInternal(Serializer serializer, Object o, boolean fBinary) throws IOException { // estimate the size of the buffer boolean fDeco = false; int nDeco = 0; int cb = 1; boolean fUser = false; Stats stats = null; // start by unwrapping any int-decorated object if (o instanceof IntDecoratedObject) { // note: does not support recursive IDO IntDecoratedObject ido = (IntDecoratedObject) o; fDeco = true; nDeco = ido.getDecoration(); cb += 5; o = ido.getValue(); } o = replace(o); int nType = serializer instanceof DefaultSerializer ? getStreamFormat(o) : FMT_EXT; switch (nType) { case FMT_NULL: break; case FMT_BOOLEAN: case FMT_BYTE: cb += 1; break; case FMT_SHORT: cb += 2; break; case FMT_INT: cb += BufferOutput.MAX_PACKED_INT_SIZE; break; case FMT_LONG: cb += BufferOutput.MAX_PACKED_LONG_SIZE; break; case FMT_INTEGER: cb += ((BigInteger) o).bitLength() / 8 + 1; break; case FMT_FLOAT: cb += 4; break; case FMT_DOUBLE: cb += 8; break; case FMT_DECIMAL: cb += ((BigDecimal) o).unscaledValue().bitLength() / 8 + 2; break; case FMT_BINARY: cb += ((ReadBuffer) o).length() + 4; break; case FMT_B_ARRAY: cb += ((byte[]) o).length + 5; break; case FMT_STRING: // optimize assuming single byte characters cb += ((String) o).length() + 5; break; case FMT_EXT: azzert(serializer != null); // break through case FMT_UNKNOWN: case FMT_XML_SER: case FMT_OBJ_EXT: case FMT_OBJ_SER: case FMT_OPT: case FMT_OPT_INT: case FMT_OPT_LONG: case FMT_OPT_DOUBLE: case FMT_XML_BEAN: fUser = true; stats = findStats(o); if (stats == null) { cb = 64; } break; default: throw azzert(); } // presize a write buffer as efficiently as possible WriteBuffer buf = stats == null ? fBinary ? new BinaryWriteBuffer(cb) : new ByteArrayWriteBuffer(cb) : stats.instantiateBuffer(fBinary); // write out the object BufferOutput out = buf.getBufferOutput(); if (fDeco) { out.writeByte(FMT_IDO); out.writePackedInt(nDeco); } out.writeByte(nType); // optimize for the most common code path if (nType == FMT_EXT) { serializer.serialize(out, o); } else { writeObjectInternal(out, nType, o); } // update stats for values of user types if (fUser) { updateStats(o, stats, buf.length()); } return buf; } /** * Write an object of a known type to the specified BufferOutput. This method * is used only by the DefaultSerializer. *

* This method is very similar to writeObject, except that it is only used * internally to optimize a common code path and uses BufferOutput instead * of DataOutput. */ private static void writeObjectInternal(BufferOutput out, int nType, Object o) throws IOException { switch (nType) { case FMT_NULL: // no data to write break; case FMT_INT: out.writePackedInt(((Integer) o).intValue()); break; case FMT_LONG: out.writePackedLong(((Long) o).longValue()); break; case FMT_STRING: out.writeSafeUTF((String) o); break; case FMT_DOUBLE: out.writeDouble(((Double) o).doubleValue()); break; case FMT_INTEGER: writeBigInteger(out, (BigInteger) o); break; case FMT_DECIMAL: writeBigDecimal(out, (BigDecimal) o); break; case FMT_BINARY: Binary.writeExternal(out, (ReadBuffer) o); break; case FMT_B_ARRAY: writeByteArray(out, (byte[]) o); break; case FMT_XML_SER: writeXmlSerializable(out, (XmlSerializable) o); break; case FMT_OBJ_EXT: writeExternalizableLite(out, (ExternalizableLite) o); break; case FMT_OBJ_SER: writeSerializable(out, o); break; case FMT_OPT: { Optional opt = (Optional) o; boolean fPresent = opt.isPresent(); out.writeBoolean(fPresent); if (fPresent) { writeObject(out, opt.get()); } } break; case FMT_OPT_INT: { OptionalInt opt = (OptionalInt) o; boolean fPresent = opt.isPresent(); out.writeBoolean(fPresent); if (fPresent) { writeInt(out, opt.getAsInt()); } } break; case FMT_OPT_LONG: { OptionalLong opt = (OptionalLong) o; boolean fPresent = opt.isPresent(); out.writeBoolean(fPresent); if (fPresent) { writeLong(out, opt.getAsLong()); } } break; case FMT_OPT_DOUBLE: { OptionalDouble opt = (OptionalDouble) o; boolean fPresent = opt.isPresent(); out.writeBoolean(fPresent); if (fPresent) { out.writeDouble(opt.getAsDouble()); } } break; case FMT_XML_BEAN: writeXmlBean(out, (XmlBean) o); break; case FMT_FLOAT: out.writeFloat(((Float) o).floatValue()); break; case FMT_SHORT: out.writeShort(((Short) o).shortValue()); break; case FMT_BYTE: out.writeByte(((Byte) o).byteValue()); break; case FMT_BOOLEAN: out.writeBoolean(((Boolean) o).booleanValue()); break; case FMT_UNKNOWN: // while exactly the same as FMT_OBJ_SER, we want to have a // distinct stack trace in a case of failure writeSerializable(out, o); break; default: throw azzert(); } } /** * Read an Object from the passed ReadBuffer using the specified Serializer. * * @param serializer the Serializer to use * @param buf the ReadBuffer object to read an object from * * @return the object read from the ReadBuffer; may be null * * @throws IOException if an I/O exception occurs */ private static T deserializeInternal(Serializer serializer, ReadBuffer buf, Remote.Function supplierBufferIn, Class clazz) throws IOException { BufferInput in = buf.getBufferInput(); int nType = in.readUnsignedByte(); switch (nType) { case FMT_IDO: // read is not symmetrical to the write; // it returns the decorated value itself! readInt(in); // skip the decoration nType = in.readUnsignedByte(); break; case FMT_BIN_DECO: case FMT_BIN_EXT_DECO: long nMask = nType == FMT_BIN_DECO ? in.readByte() : in.readPackedLong(); if ((nMask & (1L << DECO_VALUE)) == 0L) { throw new EOFException("Decorated value is missing a value"); } // get a BufferInput that corresponds just to the portion of // the value within the decorated binary int cb = in.readPackedInt(); in = buf.getReadBuffer(in.getOffset(), cb).getBufferInput(); nType = in.readUnsignedByte(); break; } if (supplierBufferIn != null) { in = supplierBufferIn.apply(in); } Object o = nType == FMT_EXT ? serializer.deserialize(in, clazz) : readObjectInternal(in, nType, ((ClassLoaderAware) serializer).getContextClassLoader()); return safeRealize(o, serializer, in); } // ----- inner class: Stats --------------------------------------------- /** * Verify that the requested buffer size is smaller than the configured * maximum. * * @param cb size of the buffer being requested * * @throws BufferOverflowException if cb > {@link #MAX_BUFFER } */ public static void validateBufferSize(int cb) { // ensure that we don't allocate more than the configured maximum int cbMax = MAX_BUFFER; if (cbMax > 0 && cb > cbMax) { BufferOverflowException e = new BufferOverflowException(); e.initCause(new IOException("serialization exceeded maximum size (" + cb + " out of " + cbMax + ")")); throw e; } } /** * If statistics are being maintained for the class of the specified * Object value, then find and return those stats. * * @param o the value to search for a Stats object for * * @return the Stats object for the specified Object value, or null */ private static Stats findStats(Object o) { return s_astats[calculateStatsId(o)]; } /** * If statistics are being maintained for the class of the specified * Object value, then find and return those stats. * * @param o the object that has been written * @param stats the statistics that track the serialized sizes of objects * @param cb the size in bytes of the object as it was written */ private static void updateStats(Object o, Stats stats, int cb) { if (stats == null) { s_astats[calculateStatsId(o)] = stats = new Stats(); } stats.update(cb); } /** * Calculate a somewhat unique ID for the type of the passed Object. * * @param o a user type value * * @return an ID that is hopefully unique across the set of user type * classes in use within this JVM at this general point in time */ private static int calculateStatsId(Object o) { if (o == null) { return 0; } int n = o.getClass().hashCode(); return ((n >>> 1) + (n & 0x01)) % s_astats.length; } /** * Serialization statistics for a given user type. * Do not document. */ protected static class Stats implements MultiBufferWriteBuffer.WriteBufferPool { // ----- statistics-related ----------------------------------------- /** * Update the serialization statistics with the size (in bytes) of a * newly serialized object. * * @param cb the number of bytes used to serialize */ void update(int cb) { int cbMax = (int) (m_lStats >>> 32); long lAccum = m_lAccum; int cItems = (int) (lAccum >>> 48); long cbTotal = lAccum & 0xFFFFFFFFFFFFL; if (cItems > 0) { boolean fResetStats = false; int cbOldAvg = (int) cbTotal / cItems; long ldtNow = 0; if (Math.abs(cbOldAvg - cb) > (cb / 2)) { // reset the stats because cb differs by more than // 50% from the current average ldtNow = getSafeTimeMillis(); fResetStats = true; } else if ((cItems & 0x3FF) == 0) { ldtNow = getSafeTimeMillis(); if (ldtNow > m_ldtCreated + EXPIRY_MILLIS || // stats expiry (cItems & 0xFFFF) == 0) // cItems overflow { // reset the stats periodically fResetStats = true; } } if (fResetStats) { cbMax = 0; lAccum = 0L; cItems = 0; m_ldtCreated = ldtNow; } } // accumulate the total bytes (uses lowest 48 out of 64 bits) cbTotal = (lAccum + cb) & 0xFFFFFFFFFFFFL; // recalculate the average int cbAvg = (int) (cbTotal / ++cItems); // check for a new max size if (cb > cbMax) { cbMax = cb; } // the item count and total bytes are stored in a "volatile long" // so that they are accessed (and modified) atomically m_lAccum = ((long) cItems << 48) | cbTotal; // the average and max are stored in a "volatile long" so that // they are subsequently accessed atomically m_lStats = ((long) cbMax << 32) | cbAvg; } /** * Instantiate a WriteBuffer to write a user type for which this * Stats object maintains serialization statistics. * * @param fBinary true if the serialization should be optimized to * produce a Binary object * * @return a WriteBuffer to write the */ WriteBuffer instantiateBuffer(boolean fBinary) { long lStats = m_lStats; int cbMax = (int) (lStats >>> 32); int cbAvg = (int) (lStats & 0x7fffffffL); return cbMax > MAX_ALLOC || (cbMax > 1024 && cbMax > cbAvg + (cbAvg >>> 3)) ? new MultiBufferWriteBuffer(this) : fBinary ? new BinaryWriteBuffer((cbMax + 0xF) & ~0xF) : new ByteArrayWriteBuffer((cbMax + 0xF) & ~0xF); } // ----- WriteBufferPool interface ---------------------------------- /** * Determine the largest amount of aggregate WriteBuffer capacity * that this factory can provide. * * @return the number of bytes that can be stored in the WriteBuffer * objects that may be returned from this factory */ public int getMaximumCapacity() { return Integer.MAX_VALUE; } /** * Allocate a WriteBuffer for use by the MultiBufferWriteBuffer. The * MultiBufferWriteBuffer calls this factory method when it exhausts * the storage capacity of previously allocated WriteBuffer objects. *

* Note that the returned WriteBuffer is expected to be empty, and * its capacity is expected to be identical to its maximum capacity, * i.e. it is not expected to resize itself, since the purpose of the * MultiBufferWriteBuffer is to act as a dynamically-sized * WriteBuffer. * * @param cbPreviousTotal the total number of bytes of capacity of * the WriteBuffer objects that the MultiBufferWriteBuffer has * thus far consumed * * @return an empty WriteBuffer suitable for writing to */ public WriteBuffer allocate(int cbPreviousTotal) { int cb; if (cbPreviousTotal <= 0) { // the smaller of: the biggest we've ever seen, or 1/8 more // than the average long lStats = m_lStats; int cbMax = (int) (lStats >>> 32); int cbAvg = (int) (lStats & 0x7fffffffL); int cbNew = cbAvg + (cbAvg >>> 3); cb = Math.min(MAX_ALLOC, Math.min(cbMax, cbNew <= 0 ? Integer.MAX_VALUE : cbNew)); } else if (cbPreviousTotal <= 1024) { // grow 100% (and at least by the minimum allocation size) cb = Math.max(MIN_ALLOC, cbPreviousTotal); } else if (cbPreviousTotal <= 4096) { // grow 50% cb = cbPreviousTotal >>> 1; } else { // grow 25% cb = Math.min(MAX_ALLOC, cbPreviousTotal >>> 2); } validateBufferSize(cb + cbPreviousTotal); return new BinaryWriteBuffer(cb); } /** * Returns a WriteBuffer to the pool. * * @param buffer the WriteBuffer that is no longer being used */ public void release(WriteBuffer buffer) { } // ----- constants -------------------------------------------------- /** * The smallest allocation for a MultiBufferWriteBuffer. */ private static final int MIN_ALLOC = 128; // 1/8 KB /** * The largest allocation for a MultiBufferWriteBuffer. */ private static final int MAX_ALLOC = 1 << 20; // 1 MB /** * The expiry for statistics (in milliseconds). */ private static final int EXPIRY_MILLIS = 10 * 60 * 1000; // 10 minutes // ----- data members ----------------------------------------------- /** *

    *
  • high 2 bytes - Number of items that have been submitted for * statistics keeping.
  • *
  • low 6 bytes - Total number of bytes of all the items * submitted.
  • *
*/ private volatile long m_lAccum; /** *
    *
  • highWord - Largest size in bytes of all the items * submitted.
  • *
  • lowWord - The average size in bytes of all the items * submitted.
  • *
*/ private volatile long m_lStats; /** * Time at which this Stats object was created. */ private volatile long m_ldtCreated; } // ----- inner class: FormatAwareCompressor ----------------------------- /** * Return a DeltaCompressor suitable for compressing/extracting binaries * produced by ExternalizableHelper using the specified serializer. The * returned DeltaCompressor will use the specified compressor to * compress/extract binaries in the format produced directly by the specified * serializer. * * @param serializer the serializer whose produced binary format is consumed * by the specified compressor * @param compressor the compressor * * @return a DeltaCompressor */ public static DeltaCompressor getDeltaCompressor( Serializer serializer, DeltaCompressor compressor) { return serializer instanceof DefaultSerializer ? compressor : new FormatAwareCompressor(compressor); } /** * A DeltaCompressor wrapper implementation that removes/replaces the * serialization format byte (FMT_EXT) before/after delegating to the * underlying compressor. */ public static class FormatAwareCompressor implements DeltaCompressor { /** * Construct a FormatAwareCompressor. * * @param compressor the underlying compressor */ public FormatAwareCompressor(DeltaCompressor compressor) { m_compressor = compressor; } // ----- DeltaCompressor methods ------------------------------------ /** * Compare an old value to a new value and generate a delta that represents * the changes that must be made to the old value in order to transform it * into the new value. The generated delta must be a ReadBuffer of non-zero * length. *

* If the old value is null, the generated delta must be a "replace", meaning * that applying it to any value must produce the specified new value. * * @param bufOld the old value * @param bufNew the new value; must not be null * * @return the changes that must be made to the old value in order to * transform it into the new value, or null to indicate no change */ public ReadBuffer extractDelta(ReadBuffer bufOld, ReadBuffer bufNew) { // strip the FMT_EXT byte if (bufOld != null) { azzert(bufOld.byteAt(0) == FMT_EXT); bufOld = bufOld.getReadBuffer(1, bufOld.length() - 1); } azzert(bufNew.byteAt(0) == FMT_EXT); bufNew = bufNew.getReadBuffer(1, bufNew.length() - 1); return m_compressor.extractDelta(bufOld, bufNew); } /** * Apply a delta to an old value in order to create a new value. * * @param bufOld the old value * @param bufDelta the delta information returned from * {@link #extractDelta} to apply to the old value * * @return the new value */ public ReadBuffer applyDelta(ReadBuffer bufOld, ReadBuffer bufDelta) { // strip the FMT_EXT byte from the old value if (bufOld != null && bufOld.length() > 0) { azzert(bufOld.byteAt(0) == FMT_EXT); bufOld = bufOld.getReadBuffer(1, bufOld.length() - 1); } ReadBuffer bufNew = m_compressor.applyDelta(bufOld, bufDelta); WriteBuffer buffer = new BinaryWriteBuffer(bufNew.length() + 1); // replace the FMT_EXT byte try { BufferOutput out = buffer.getBufferOutput(); out.writeByte(FMT_EXT); out.writeBuffer(bufNew); } catch (IOException e) { throw ensureRuntimeException(e); } return buffer.toBinary(); } // ----- Object methods --------------------------------------------- /** * Returns a string representation of the object. * * @return a string representation of the object */ public String toString() { return "FormatAwareCompressor {" + m_compressor + "}"; } // ----- data members ----------------------------------------------- /** * The wrapped DeltaCompressor. */ protected DeltaCompressor m_compressor; } // ----- inner class: DecoratedMultiBufferReadBuffer -------------------- /** * DecoratedMultiBufferReadBuffer is a MultiBufferWriteBuffer that * represents a binary "decorated" value, and allows a more * optimized {@link #getUndecorated(ReadBuffer)} operation. * * @see #decorate(ReadBuffer, int, ReadBuffer) * @see #getUndecorated(ReadBuffer) */ public static class DecoratedMultiBufferReadBuffer extends MultiBufferReadBuffer { // ----- constructors ----------------------------------------------- /** * Construct a DecoratedMultiBufferReadBuffer for the specified value. * * @param bufValue the undecorated value * @param abuf the array of ReadBuffers from which to construct this * DecoratedMultiBufferReadBuffer */ public DecoratedMultiBufferReadBuffer(ReadBuffer bufValue, ReadBuffer[] abuf) { super(abuf); m_bufValue = bufValue; } // ----- accessors -------------------------------------------------- /** * Return the undecorated value. * * @return the undecorated value */ public ReadBuffer getUndecorated() { return m_bufValue; } // ----- data members ----------------------------------------------- /** * The undecorated value. */ protected final ReadBuffer m_bufValue; } // ----- ClassLoader helpers -------------------------------------------- /** * Attempt to load the specified class using sequentionally all of the * specified loaders, the ContextClassLoader and the current class loader. * * @param sClass the class name * @param loader1 first ClassLoader to try * @param loader2 second ClassLoader to try * * @return the Class for the specified name * * @throws ClassNotFoundException if all the attempts fail */ public static Class loadClass(String sClass, ClassLoader loader1, ClassLoader loader2) throws ClassNotFoundException { for (int i = 1; i <= 3; i++) { ClassLoader loader; switch (i) { case 1: loader = loader1; break; case 2: loader = loader2; break; case 3: loader = getContextClassLoader(); if (loader == loader1 || loader == loader2) { loader = null; } break; default: throw new IllegalStateException(); } try { if (loader != null) { return Class.forName(sClass, false, loader); } } catch (ClassNotFoundException e) {} } // nothing worked; try the current class loader as a last chance return Class.forName(sClass); } /** * Attempt to find a valid, resolvable URL for the specified resource, * first by using each of the specified ClassLoaders, then using the * ContextClassLoader. * * @param sName the resource name * @param loader1 first ClassLoader to try * @param loader2 second ClassLoader to try * * @return the URL for the specified resource name, or null if the * resource could not be found */ public static URL loadResource(String sName, ClassLoader loader1, ClassLoader loader2) { for (int i = 1; i <= 3; i++) { ClassLoader loader; switch (i) { case 1: loader = loader1; break; case 2: loader = loader2; break; case 3: loader = getContextClassLoader(); if (loader == loader1 || loader == loader2) { loader = null; } break; default: throw new IllegalStateException(); } if (loader != null) { URL url = loader.getResource(sName); if (url != null) { return url; } } } return null; } // ----- stream wrappers ------------------------------------------------ /** * Get an InputStream for the passed DataInput object. * * @param in an Object implementing the DataInput interface * * @return an Object of type InputStream */ public static InputStream getInputStream(final DataInput in) { return in instanceof InputStream ? (InputStream) in : new InputStream() { public int read() throws IOException { try { return in.readUnsignedByte(); } catch (EOFException e) { return -1; } } }; } /** * Get an OutputStream for the passed DataOutput object. * * @param out an Object implementing the DataOutput interface * * @return an Object of type OutputStream */ public static OutputStream getOutputStream(DataOutput out) { return out instanceof ObjectOutput ? new ShieldedObjectOutputStream((ObjectOutput) out) : new ShieldedDataOutputStream(out); } /** * Get a shielded OutputStream for the passed OutputStream object. * * @param out an OutputStream * * @return an OutputStream that implements the Shielded interface */ public static OutputStream getShieldedOutputStream(OutputStream out) { return out instanceof Shielded ? out : out instanceof ObjectOutput ? new ShieldedObjectOutputStream((ObjectOutput) out) : out instanceof DataOutput ? new ShieldedDataOutputStream((DataOutput) out) : new ShieldedOutputStream(out); } /** * Get an ObjectInput for the passed DataInput object. * * @param in an Object implementing the DataInput interface * @param loader the ClassLoader to use * * @return an Object of type ObjectInput * * @throws IOException if an I/O exception occurs */ public static ObjectInput getObjectInput(DataInput in, ClassLoader loader) throws IOException { return s_streamfactory.getObjectInput(in, loader, false); } /** * Get a new ObjectInput for the passed DataInput, even if the passed * DataInput is an ObjectInput. * * @param in an Object implementing the DataInput interface * @param loader the ClassLoader to use * * @return an Object of type ObjectInput that is guaranteed not to be * the same reference as in * * @throws IOException if an I/O exception occurs */ public static ObjectInput getNewObjectInput(DataInput in, ClassLoader loader) throws IOException { return s_streamfactory.getObjectInput(in, loader, true); } /** * Get an ObjectOutput for the passed DataOutput object. * * @param out an Object implementing the DataOutput interface * * @return an Object of type ObjectOutput * * @throws IOException if an I/O exception occurs */ public static ObjectOutput getObjectOutput(DataOutput out) throws IOException { return s_streamfactory.getObjectOutput(out); } /** * Determine whether the passed DataOutput handles ClassLoader resolving. * Note that the ClassLoader resolving on the "write" side is necessary * only to make the stream format symetrical for the "read" side. * * @param out an object implementing DataOutput * * @return true if the object implementing DataOutput also implements * ObjectOutput and handles ClassLoader resolving */ public static boolean isResolving(DataOutput out) { return out instanceof Resolving || out instanceof ShieldedObjectOutputStream && ((ShieldedObjectOutputStream) out).isResolving(); } // ----- custom stream format support ----------------------------------- /** * Return the ObjectStreamFactory used to convert DataInput/Output into * ObjectInput/Output streams. * * @return the currently used ObjectStreamFactory */ public static ObjectStreamFactory getObjectStreamFactory() { return s_streamfactory; } /** * Specify an ObjectStreamFactory that should be used to convert * DataInput/Output into ObjectInput/Output streams. *

* Warning: This facility should be used with extreme care; failure * to set the ObjectStreamFactory identically on all cluster nodes may * render some of all clustered services completely inoperable, * * @param factory the ObjectStreamFactory to use */ public static void setObjectStreamFactory(ObjectStreamFactory factory) { s_streamfactory = factory; } /** * Determine if the resource object can be serialized using the * DefaultSerializer. * * @param o the resource object * * @return true iff the resource object can be serialized by the * DefaultSerializer */ public static boolean isSerializable(Object o) { return getStreamFormat(o) != FMT_UNKNOWN; } /** * Internal: Select an optimal stream format to use to store the passed * object in a stream (as used by the DefaultSerializer). * * @param o an Object * * @return a stream format to use to store the object in a stream */ public static int getStreamFormat(Object o) { return o == null ? FMT_NULL : o instanceof String ? FMT_STRING : o instanceof Number ? ( o instanceof Integer ? FMT_INT : o instanceof Long ? FMT_LONG : o instanceof Double ? FMT_DOUBLE : o instanceof BigInteger ? FMT_INTEGER : o instanceof BigDecimal ? FMT_DECIMAL : o instanceof Float ? FMT_FLOAT : o instanceof Short ? FMT_SHORT : o instanceof Byte ? FMT_BYTE : FMT_OBJ_SER ) : o instanceof byte[] ? FMT_B_ARRAY : o instanceof ReadBuffer ? FMT_BINARY : o instanceof XmlBean ? FMT_XML_BEAN : o instanceof IntDecoratedObject ? FMT_IDO : o instanceof ExternalizableLite ? FMT_OBJ_EXT : o instanceof Boolean ? FMT_BOOLEAN : o instanceof Serializable ? FMT_OBJ_SER : o instanceof Optional ? FMT_OPT : o instanceof OptionalInt ? FMT_OPT_INT : o instanceof OptionalLong ? FMT_OPT_LONG : o instanceof OptionalDouble ? FMT_OPT_DOUBLE : o instanceof XmlSerializable ? FMT_XML_SER : FMT_UNKNOWN; } /** * Determines whether or not the specified serializers are compatible. * In other words, this method returns true iff object serialized with the * first Serializer can be deserialized by the second and visa versa. * * @param serializerThis the first Serializer * @param serializerThat the second Serializer * * @return true iff the two Serializers are stream compatible */ public static boolean isSerializerCompatible( Serializer serializerThis, Serializer serializerThat) { return serializerThis instanceof PofContext ? serializerThat instanceof PofContext : serializerThis == null || serializerThat == null ? serializerThis == serializerThat : serializerThis.getClass() == serializerThat.getClass(); } /** * Log the message explaining the serializer incompatibility between the * specified cache and a service. * * @param cache the NamedCache reference * @param sService the service name * @param serializer the serializer used by the service */ public static void reportIncompatibleSerializers(NamedCache cache, String sService, Serializer serializer) { CacheFactory.log("The serializer used by cache \"" + cache.getCacheName() + "\" (" + cache.getCacheService().getSerializer() + ") is incompatible with the" + " serializer configured for service \"" + sService + "\" (" + serializer + "); therefore, cached keys and values will be" + " converted via serialization. This will result in" + " increased CPU and memory utilization. If possible," + " consider reconfiguring either serializer.", LOG_WARN); } // ----- decorated Binary support --------------------------------------- /** * If the ReadBuffer is the result of serialization by ExternalizableHelper, * determine if the buffer contains decorations. *

* Note: This method can only be used against ReadBuffers that result * from serialization by ExternalizableHelper or buffers that are already * decorated. * * @param buf the ReadBuffer to check * * @return true iff the ReadBuffer is decorated */ public static boolean isDecorated(ReadBuffer buf) { if (buf != null && buf.length() > 1) { byte b = buf.byteAt(0); return (b == FMT_BIN_DECO || b == FMT_BIN_EXT_DECO); } return false; } /** * If the ReadBuffer is the result of serialization by ExternalizableHelper, * determine if the buffer contains the specified decoration. *

* Note: This method can only be used against ReadBuffers that result * from serialization by ExternalizableHelper or buffers that are already * decorated. * * @param buf the ReadBuffer to check * @param nId the identifier for the decoration to check * * @return true iff the ReadBuffer is decorated with the specified decoration */ public static boolean isDecorated(ReadBuffer buf, int nId) { if (buf != null && buf.length() > 1) { byte b = buf.byteAt(0); if (b == FMT_BIN_DECO) { if (nId >= Byte.SIZE) { return false; } long nBits = buf.byteAt(1) & 0xFF; long nMask = 1L << nId; return (nBits & nMask) != 0L; } else if (b == FMT_BIN_EXT_DECO) { BufferInput in = buf.getBufferInput(); try { int nFmt = in.readUnsignedByte(); long nBits = in.readPackedLong(); long nMask = 1L << nId; return (nBits & nMask) != 0L; } catch (IOException e) { throw ensureRuntimeException(e); } } } return false; } /** * Decorate the passed value with the specified decoration and return the * resulting Binary. The passed value may or may not already be decorated. *

* The decoration id must be in range defined by {@link #DECO_ID_MIN} and * {@link #DECO_ID_MAX}. A series of DECO_* constants are defined * for the pre-approved decorations, including: *

  • {@link #DECO_VALUE} stores the original, undecorated value;
  • *
  • {@link #DECO_EXPIRY}, {@link #DECO_STORE}, {@link #DECO_TX} and * {@link #DECO_PUSHREP} are used by various facilities of Coherence * and {@link #DECO_WLS} are assigned to Oracle * products;
  • *
  • {@link #DECO_APP_1}, {@link #DECO_APP_2} and {@link #DECO_APP_3} are * made available for use by application developers;
  • *
  • {@link #DECO_CUSTOM} is another application-definable decoration, * but one that has also been used by Oracle frameworks and products in the * past, which means that a potential exists for collisions.
*

* All other potential decoration id values are reserved. Product and * framework developers that require a new decoration id to be assigned to * them should contact the Coherence product development team. *

* Note: This method can only be used against Binary values that result * from serialization by ExternalizableHelper or Binary values that are * already decorated. * * @param bin the Binary to decorate, which may already be * decorated * @param nId the identifier for the decoration, one of the * DECO_* constants * @param binDecoration the decoration to apply; a null value will remove * the specified decoration * * @return a decorated Binary containing the passed decoration */ public static Binary decorate(Binary bin, int nId, Binary binDecoration) { // Note: "upcasts" are necessary in order to bind to the correct method return asBinary(decorate((ReadBuffer) bin, nId, (ReadBuffer) binDecoration)); } /** * Decorate the passed value with the specified decoration and return the * resulting ReadBuffer. The passed value may or may not already be decorated. *

* The decoration id must be in range defined by {@link #DECO_ID_MIN} and * {@link #DECO_ID_MAX}. A series of DECO_* constants are defined * for the pre-approved decorations, including: *

  • {@link #DECO_VALUE} stores the original, undecorated value;
  • *
  • {@link #DECO_EXPIRY}, {@link #DECO_STORE}, {@link #DECO_TX} and * {@link #DECO_PUSHREP} are used by various facilities of Coherence;
  • *
  • {@link #DECO_WLS} are assigned to Oracle products;
  • *
  • {@link #DECO_APP_1}, {@link #DECO_APP_2} and {@link #DECO_APP_3} are * made available for use by application developers;
  • *
  • {@link #DECO_CUSTOM} is another application-definable decoration, * but one that has also been used by Oracle frameworks and products in the * past, which means that a potential exists for collisions.
*

* All other potential decoration id values are reserved. Product and * framework developers that require a new decoration id to be assigned to * them should contact the Coherence product development team. *

* Note: This method can only be used against ReadBuffers that result from * serialization by ExternalizableHelper or buffers that are already * decorated. * * @param bufOrig the ReadBuffer to decorate, which may already be decorated * @param nId the identifier for the decoration, one of the * DECO_* constants * @param bufDeco the decoration to apply; a null value will remove the * specified decoration * * @return a decorated ReadBuffer containing the passed decoration */ public static ReadBuffer decorate(ReadBuffer bufOrig, int nId, ReadBuffer bufDeco) { // consider a null decoration to indicate that the decoration should // be removed if (bufDeco == null) { return undecorate(bufOrig, nId); } if (nId < DECO_ID_MIN || nId > DECO_ID_MAX) { throw new IndexOutOfBoundsException( "decoration index is out of range: index=" + nId + ", min=" + DECO_ID_MIN + ", max=" + DECO_ID_MAX); } boolean fDecorated = isDecorated(bufOrig); if (!fDecorated && nId == DECO_VALUE && !isDecorated(bufDeco)) { // the "value" decoration can be returned as the result, as long // as there are no other decorations, except if the value is // itself decorated, in which case it must be stored as a "value" // decoration so that the corresponding call to getDecoration() // will return the correct value return bufDeco; } // this algorithm inserts/replaces/appends a decoration by determining // which portion (the "front") of the current decorated value needs to // be copied to the start of the new value, and which portion (the // "back") of the current decorated value needs to be copied to the // end of the new value: // 1) assuming the updated decoration will not be the first decoration // in the resulting decorated binary, then the offset to copy from // will be 2 for the 8-bit FMT_BIN_DECO (the first byte after the // format identifier and the bit mask for the decoration // identifiers) or somewhere between 2 and 11 for the packed-long- // utilizing FMT_BIN_EXT_DECO // 2) if the new decoration is replacing an existing decoration, then // the offset of the decoration to be replaced needs to be located; // otherwise the offset of the following decoration needs to be // located; either way, that will be the offset to copy up to (before // the new decoration) // 3) then the new decoration will be appended // 4) then the first existing decoration past the new decoration will // be appended, along with all trailing decorations // the algorithm is modified slightly if the current value is not // decorated long nBits = (1L << nId); int ofFront = -1; int cbFront = 0; int ofBack = -1; int cbBack = 0; // there is a situation in which the front data to copy has not yet // been length-encoded since it is not yet a decorated binary boolean fEncodeFrontLength = false; // up to 8 bits can be encoded in the legacy format, otherwise the // "extended" format will be used boolean fExtended = false; if (bufOrig == null) { // there is no old value to decorate bufOrig = Binary.NO_BINARY; } else if (fDecorated) { try { BufferInput in = bufOrig.getBufferInput(); // the first byte is the format, either "legacy" or "extended" fExtended = in.readByte() != FMT_BIN_DECO; // next comes the bit-mask of decoration id's long nPrevBits = fExtended ? in.readPackedLong() : (long) in.readUnsignedByte(); // the offset is now at the start of the first decoration ofFront = in.getOffset(); // incorporate the previously existing decorations into the // bits we're collecting for the new decorated value nBits |= nPrevBits; // determine which decoration id's are the last to come before // and the first to come after the specified decoration id int nLastFront = indexOfMSB(nPrevBits & ((1L << nId) - 1L)); int nFirstBack = indexOfLSB(nPrevBits & (-1L << (nId + 1))); for (int iCurrentId = 0; nPrevBits != 0; ++iCurrentId) { if ((nPrevBits & 0x01L) != 0) { if (iCurrentId == nFirstBack) { // we're at the start of the first decoration that // follows the one that we're inserting/replacing ofBack = in.getOffset(); cbBack = bufOrig.length() - ofBack; } // the format for each decoration is its packed length // followed by the bytes of its binary value in.skipBytes(in.readPackedInt()); if (iCurrentId == nLastFront) { // we're at the end of the last decoration // that precedes the one that we're // inserting/replacing/appending, i.e. at the // point where we'll write the new decoration cbFront = in.getOffset() - ofFront; } } nPrevBits >>>= 1; } } catch (IOException e) { throw ensureRuntimeException(e); } } else { // the value to decorate is not yet decorated; // store the old value itself as the "value decoration" nBits |= (1L << DECO_VALUE); ofFront = 0; cbFront = bufOrig.length(); fEncodeFrontLength = true; } // determine if the new decorated binary will use the extended format fExtended |= nId >= Byte.SIZE; // figure out the total length of the decorated binary int cbNew = bufDeco.length(); // testing has shown that for small binaries, avoiding the "copy" is a // performance loss. For larger binaries, it is a win. if (cbFront + cbNew + cbBack > 128) { WriteBuffer bufWrite = new ByteArrayWriteBuffer(1 + 10 + 5 + 5); BufferOutput out = bufWrite.getBufferOutput(); try { // write the format id and the decoration id's (as a bit mask) if (fExtended) { out.writeByte(FMT_BIN_EXT_DECO); out.writePackedLong(nBits); } else { out.writeByte(FMT_BIN_DECO); out.writeByte((byte) nBits); } if (fEncodeFrontLength) { // here, cbFront is the length of the value. // Write the value length right after the mask out.writePackedInt(cbFront); } // portion of the temp buffer that precedes the existing decorations int cbHead = out.getOffset(); // write the new decoration length out.writePackedInt(cbNew); // portion of the temp buffer that follows the existing decorations int cbTail = out.getOffset() - cbHead; ReadBuffer bufRead = bufWrite.toBinary(); ReadBuffer[] abuf = new ReadBuffer[] {bufRead.getReadBuffer(0, cbHead), cbFront > 0 ? bufOrig.getReadBuffer(ofFront, cbFront) : Binary.NO_BINARY, bufRead.getReadBuffer(cbHead, cbTail), bufDeco, cbBack > 0 ? bufOrig.getReadBuffer(ofBack, cbBack) : Binary.NO_BINARY}; return fEncodeFrontLength // fEncodeFrontLength implies bufOrig is undecorated ? new DecoratedMultiBufferReadBuffer(bufOrig, abuf) : new MultiBufferReadBuffer(abuf); } catch (IOException e) { throw ensureRuntimeException(e); } } else { int cbTotal = 1 + (fExtended ? calculatePackedLength(nBits) : 1) + cbFront + calculatePackedLength(cbNew) + cbNew + cbBack; if (fEncodeFrontLength) { cbTotal += calculatePackedLength(cbFront); } WriteBuffer bufNew = new BinaryWriteBuffer(cbTotal, cbTotal); BufferOutput out = bufNew.getBufferOutput(); try { // write the format id and the decoration id's (as a bit mask) if (fExtended) { out.writeByte(FMT_BIN_EXT_DECO); out.writePackedLong(nBits); } else { out.writeByte(FMT_BIN_DECO); out.writeByte((byte) nBits); } // write any leading decorations if (fEncodeFrontLength) { // here, cbFront is the length of the value. // Write the value length right after the mask out.writePackedInt(cbFront); } if (cbFront > 0) { // copy any bytes in front of the decoration out.writeBuffer(bufOrig, ofFront, cbFront); } // write the new decoration out.writePackedInt(cbNew); out.writeBuffer(bufDeco); // write any trailing decorations if (cbBack > 0) { out.writeBuffer(bufOrig, ofBack, cbBack); } assert out.getOffset() == cbTotal; return bufNew.toBinary(); } catch (IOException e) { throw ensureRuntimeException(e); } } } /** * Decorate the passed Binary with the passed decorations. If the passed * Binary is decorated, use its decorations as the defaults and the passed * decorations as the overrides; if the passed Binary is not decorated, * then use it as the default for the {@link #DECO_VALUE "value"} * decoration. *

* Note: This method can only be used against Binary values that result * from serialization by ExternalizableHelper or Binary values that are * already decorated. * * @param bin the Binary to decorate, which may already be * decorated; may be null * @param abinDecorations the decorations to apply; each non-null element * is assumed to be a decoration to add whose * identifier is its index in the array; the array * contents will not be modified by this method * * @return a decorated Binary containing the passed decorations * * @deprecated as of Coherence 3.7.2 */ public static Binary decorate(Binary bin, Binary[] abinDecorations) { // Note: "upcasts" are necessary in order to bind the correct method return asBinary(decorate((ReadBuffer) bin, (ReadBuffer[]) abinDecorations)); } /** * Decorate the passed Binary with the passed decorations. If the passed * Binary is decorated, use its decorations as the defaults and the passed * decorations as the overrides; if the passed Binary is not decorated, * then use it as the default for the {@link #DECO_VALUE "value"} * decoration. *

* Note: This method can only be used against Binary values that result * from serialization by ExternalizableHelper or Binary values that are * already decorated. * * @param buf the Binary to decorate, which may already be * decorated; may be null * @param abufDeco the decorations to apply; each non-null element * is assumed to be a decoration to add whose * identifier is its index in the array; the array * contents will not be modified by this method * * @return a decorated Binary containing the passed decorations */ public static ReadBuffer decorate(ReadBuffer buf, ReadBuffer[] abufDeco) { // if a decorated Binary was passed in, use its decorations to fill in // any missing decorations in the passed decoration array; otherwise, // if the Binary passed in is NOT decorated, then use it to fill in // the "value" decoration in the passed decoration array if (isDecorated(buf)) { // whatever decorations already exist in the passed-in binary // should be retained, unless the passed in decorations // override them ReadBuffer[] abufOrig = getDecorations(buf); ReadBuffer[] abufNew = abufDeco; int cbufOrig = abufOrig.length; int cbufOver = abufNew.length; if (cbufOrig >= cbufOver) { abufDeco = abufOrig; for (int i = 0; i < cbufOver; ++i) { if (abufNew[i] != null) { abufDeco[i] = abufNew[i]; } } } else { // avoid changing the contents of the passed array abufDeco = abufDeco.clone(); for (int i = 0; i < cbufOrig; ++i) { if (abufDeco[i] == null) { abufDeco[i] = abufOrig[i]; } } } } else if (buf != null && (abufDeco.length < 1 || abufDeco[0] == null)) { // the passed-in binary is the value to be decorated, which // is encoded as the "zero-eth" decoration ReadBuffer[] abufOverride = abufDeco; int cbufOverride = abufOverride.length; abufDeco = new ReadBuffer[Math.max(1, cbufOverride)]; if (cbufOverride > 0) { System.arraycopy(abufOverride, 0, abufDeco, 0, cbufOverride); } abufDeco[0] = buf; } // at this point, all of the information that will be in the resulting // Binary is in the abufDeco array; the contents need to be // analyzed to determine what the result will look like int cbTotal = 1; // 1-byte serialization format identifier int cDecorations = 0; int nLastId = -1; long nBits = 0L; int cBufDeco = abufDeco.length; for (int i = 0; i < cBufDeco; ++i) { ReadBuffer bufDeco = abufDeco[i]; if (bufDeco != null) { int cb = bufDeco.length(); cbTotal += calculatePackedLength(cb) + cb; cDecorations += 1; nLastId = i; nBits |= (1L << i); } } if (cDecorations == 0) { // there is nothing return null; } else if (cDecorations == 1 && nLastId == DECO_VALUE && !isDecorated(abufDeco[DECO_VALUE])) { // all there is is a value, which itself is undecorated, so return // it as an undecorated value return abufDeco[DECO_VALUE]; } else if (nLastId > DECO_ID_MAX) { // there is too much throw new IndexOutOfBoundsException("decoration id out of bounds: " + nLastId); } // use the legacy binary decoration format for id's up to 7; otherwise // use the "extended" binary decoration format boolean fExtended = nLastId >= Byte.SIZE; cbTotal += fExtended ? calculatePackedLength(nBits) : 1; BinaryWriteBuffer bufNew = new BinaryWriteBuffer(cbTotal, cbTotal); BufferOutput out = bufNew.getBufferOutput(); try { out.writeByte(fExtended ? FMT_BIN_EXT_DECO : FMT_BIN_DECO); if (fExtended) { out.writePackedLong(nBits); } else { out.write((byte) nBits); } for (int i = 0; i <= nLastId; ++i) { ReadBuffer bufDeco = abufDeco[i]; if (bufDeco != null) { out.writePackedInt(bufDeco.length()); out.writeBuffer(bufDeco); } } assert out.getOffset() == cbTotal; } catch (IOException e) { throw ensureRuntimeException(e); } return bufNew.toBinary(); } /** * Extract and return the specified decoration from the passed Binary. *

* Note: This method can only be used against Binary values that result * from serialization by ExternalizableHelper or Binary values that are * already decorated. * * @param bin the Binary that may be decorated * @param nId the identifier for the decoration * * @return the Binary decoration, or null if the passed Binary is not * decorated or if no decoration was found for the specified * identifier * * @deprecated as of Coherence 3.7.2 */ public static Binary getDecoration(Binary bin, int nId) { // Note: "upcast" is necessary in order to bind the correct method return asBinary(getDecoration((ReadBuffer) bin, nId)); } /** * Extract and return the specified decoration from the passed ReadBuffer. *

* Note: This method can only be used against ReadBuffers that result * from serialization by ExternalizableHelper or buffers that are already * decorated. * * @param buf the ReadBuffer that may be decorated * @param nId the identifier for the decoration * * @return the decoration, or null if the passed ReadBuffer is not decorated * or if no decoration was found for the specified identifier */ public static ReadBuffer getDecoration(ReadBuffer buf, int nId) { if (!isDecorated(buf) || nId < DECO_ID_MIN || nId > DECO_ID_MAX) { return nId == DECO_VALUE ? buf : null; } // first byte is the format identifier, followed by the 1-byte bit- // encoded list of decoration IDs (or a packed long for the extended // format), followed by the length of the first decoration's Binary, // followed by the first decoration's binary data, and so on BufferInput in = buf.getBufferInput(); try { int nFmt = in.readUnsignedByte(); long nBits = nFmt == FMT_BIN_DECO ? (long) in.readUnsignedByte() : in.readPackedLong(); long nMask = 1L << nId; if ((nBits & nMask) == 0L) { return null; } for (int i = 0; i < nId; ++i) { if ((nBits & 0x01L) != 0) { in.skipBytes(in.readPackedInt()); } nBits >>>= 1; } int cb = in.readPackedInt(); int of = in.getOffset(); return buf.getReadBuffer(of, cb); } catch (IOException e) { throw ensureRuntimeException(e); } } /** * Return an array containing all of the decorations from the passed * ReadBuffer. *

* If the passed value is not decorated, then the result is a single- * element array containing the undecorated value, which is the * DECO_VALUE decoration. *

* Note: This method can only be used against ReadBuffers that result * from serialization by ExternalizableHelper or buffers that are * already decorated. * * @param buf the ReadBuffer that may be decorated * * @return an array of all decorations on the passed ReadBuffer, indexed by * the DECO_* constants */ public static ReadBuffer[] getDecorations(ReadBuffer buf) { if (!isDecorated(buf)) { // The value is translated into the DECO_VALUE decoration return new ReadBuffer[] {buf}; } BufferInput in = buf.getBufferInput(); try { // determine how many decorations there are (there has to be at // least one, or it wouldn't be "decorated") int nFmt = in.readUnsignedByte(); long nBits = nFmt == FMT_BIN_DECO ? in.readUnsignedByte() : in.readPackedLong(); int ofMSB = indexOfMSB(nBits); assert ofMSB >= DECO_ID_MIN && ofMSB <= DECO_ID_MAX; int cbufDeco = ofMSB + 1; ReadBuffer[] abufDeco = new ReadBuffer[cbufDeco]; for (int i = 0; i < cbufDeco; i++) { if ((nBits & 0x01L) != 0) { int cb = in.readPackedInt(); int of = in.getOffset(); abufDeco[i] = buf.getReadBuffer(of, cb); in.skipBytes(cb); } nBits >>>= 1; } return abufDeco; } catch (IOException e) { throw ensureRuntimeException(e); } } /** * Remove the specified decoration from the passed Binary. If the resulting * Binary has no decorations remaining, then return the undecorated Binary; * otherwise return the decorated Binary with the remaining decorations. *

* Note: This method can only be used against Binary values that result * from serialization by ExternalizableHelper or Binary values that are * already decorated. * * @param bin the Binary to undecorate * @param nId the identifier for the decoration to remove * * @return a Binary that may be decorated or undecorated * * @deprecated as of Coherence 3.7.2 */ public static Binary undecorate(Binary bin, int nId) { // Note: "upcast" is necessary in order to bind the correct method return asBinary(undecorate((ReadBuffer) bin, nId)); } /** * Remove the specified decoration from the passed ReadBuffer and return the * resulting contents (which may be undecorated, or contain the remaining * decorations). *

* Note: This method can only be used against ReadBuffers that result from * serialization by ExternalizableHelper or buffers that are already decorated. * * @param buf the ReadBuffer to undecorate * @param nId the identifier for the decoration to remove * * @return a ReadBuffer that may or may not be decorated */ public static ReadBuffer undecorate(ReadBuffer buf, int nId) { // verify that the binary is decorated and that the ID to remove is // even legitimate if (!isDecorated(buf, nId) || nId < DECO_ID_MIN || nId > DECO_ID_MAX) { return nId == DECO_VALUE && !isDecorated(buf) ? null : buf; } int nFmt; long nBits; try { BufferInput in = buf.getBufferInput(); nFmt = in.readUnsignedByte(); nBits = nFmt == FMT_BIN_DECO ? (long) in.readUnsignedByte() : in.readPackedLong(); } catch (IOException e) { throw ensureRuntimeException(e); } long nMask = 1L << nId; if ((nBits & nMask) == 0L) { return buf; } long nRemains = nBits & ~nMask; if (nRemains == 0L) { // nothing left return null; } else if (nRemains == (1L << DECO_VALUE)) { // only the original value is left; if it's undecorated, just // return it, but if it's decorated, then returning it would // be incorrect, since those decorations intrinsic within the // "value" portion of the decorated binary would become the // decorations of the binary itself ReadBuffer bufValue = getUndecorated(buf); if (!isDecorated(bufValue)) { return bufValue; } } // extract all the decorations, remove the specified one and // re-assemble the remaining ones ReadBuffer[] abufDeco = getDecorations(buf); abufDeco[nId] = null; return decorate(null, abufDeco); } /** * If the passed Binary is decorated, extract the original Binary value * that the decorations were added to, otherwise return the passed Binary * value. *

* Note: This method can only be used against Binary values that result * from serialization by ExternalizableHelper or Binary values that are * already decorated. * * @param bin the Binary object * * @return the undecorated Binary value, or null if the Binary value is * decorated but does not contain an original Binary value * * @deprecated as of Coherence 3.7.2 */ public static Binary getUndecorated(Binary bin) { return asBinary(getDecoration((ReadBuffer) bin, DECO_VALUE)); } /** * If the passed ReadBuffer is decorated, extract the original contents * that the decorations were added to, otherwise return the passed Binary * value. *

* Note: This method can only be used against ReadBuffers that result from * serialization by ExternalizableHelper or buffers that are already decorated. * * @param buf the ReadBuffer object * * @return the undecorated ReadBuffer, or null if the specified buffer is * decorated but does not contain an actual value */ public static ReadBuffer getUndecorated(ReadBuffer buf) { return buf instanceof DecoratedMultiBufferReadBuffer ? ((DecoratedMultiBufferReadBuffer) buf).getUndecorated() : getDecoration(buf, DECO_VALUE); } /** * Return a Binary representing the contents of the specified ReadBuffer, or * null if the buffer is null. * * @param buf the read buffer * * @return the contents of the read buffer as a Binary object, or null */ public static Binary asBinary(ReadBuffer buf) { return buf == null ? null : buf.toBinary(); } // ----- SerializationSupport helpers ----------------------------------- /** * Potentially replaces specified argument with a different object before * serialization. * * @param o the object to replace, if necessary * * @return the replacement object * * @throws ObjectStreamException if an error occurs */ public static Object replace(Object o) throws ObjectStreamException { // support either static or dynamic lambda o = Lambdas.ensureSerializable(o); if (o instanceof SerializationSupport) { o = ((SerializationSupport) o).writeReplace(); } return o; } /** * Realizes object after deserialization by applying post-serialization rules. * * @param the class of realized object * @param o the object to realize * @param serializer the serializer that was used to deserialize the object * * @return fully realized object * * @throws ObjectStreamException if an error occurs */ public static T realize(Object o, Serializer serializer) throws ObjectStreamException { if (o instanceof SerializerAware) { ((SerializerAware) o).setContextSerializer(serializer); } if (o instanceof SerializationSupport) { o = ((SerializationSupport) o).readResolve(); if (o instanceof SerializerAware) { ((SerializerAware) o).setContextSerializer(serializer); } } return (T) o; } // ----- command line --------------------------------------------------- /** * Parse a hex string representing a serialized object. *

* Example: *

     *   java com.tangosol.util.ExternalizableHelper 0x0603486921
     * 
* * @param asArgs the hex string as the command line arguments */ public static void main(String[] asArgs) { if (asArgs.length == 0) { out("Usage:"); out("java com.tangosol.util.ExternalizableHelper "); } else { Object o = fromByteArray(parseHex(asArgs[0])); if (o != null) { out("Class: " + o.getClass().getName()); } out("Value: " + o); } } // ----- constants ------------------------------------------------------ /** * Serialization format: Unknown value (alias to FMT_UNKNOWN). */ public static final int FMT_NONE = 255; /** * Serialization format: Unknown value. */ public static final int FMT_UNKNOWN = 255; /** * Serialization format: Null value. */ public static final int FMT_NULL = 0; /** * Serialization format: Integer value. */ public static final int FMT_INT = 1; /** * Serialization format: Long value. */ public static final int FMT_LONG = 2; /** * Serialization format: Double value. */ public static final int FMT_DOUBLE = 3; /** * Serialization format: BigInteger value. */ public static final int FMT_INTEGER = 4; /** * Serialization format: BigDecimal value. */ public static final int FMT_DECIMAL = 5; /** * Serialization format: String value. */ public static final int FMT_STRING = 6; /** * Serialization format: Binary value. */ public static final int FMT_BINARY = 7; /** * Serialization format: Byte array value. */ public static final int FMT_B_ARRAY = 8; /** * Serialization format: XmlSerializable value. */ public static final int FMT_XML_SER = 9; /** * Serialization format: ExternalizableLite value. */ public static final int FMT_OBJ_EXT = 10; /** * Serialization format: Serializable value. */ public static final int FMT_OBJ_SER = 11; /** * Serialization format: XmlBean value. */ public static final int FMT_XML_BEAN = 12; /** * Serialization format: Integer-decorated value. */ public static final int FMT_IDO = 13; /** * Serialization format: Float value. */ public static final int FMT_FLOAT = 14; /** * Serialization format: Short value. */ public static final int FMT_SHORT = 15; /** * Serialization format: Byte value. */ public static final int FMT_BYTE = 16; /** * Serialization format: Boolean value. */ public static final int FMT_BOOLEAN = 17; /** * Serialization format: Decorated Binary value. *

* Structure is: *

     * byte 0    : format identifier (18)
     * byte 1    : bit mask of decoration identifiers (see DECO_* constants)
     * byte 2    : packed int specifying the length of the first decoration
     * byte next : binary data
     * ...
     * 
* For each decoration, there is a packed int for its length, followed by * its binary data. The first decoration is the decorated value itself, if * present. *

* Note: FMT_IDO cannot be combined with FMT_BIN_DECO. */ public static final int FMT_BIN_DECO = 18; /** * Serialization format: Extended-range Decorated Binary value. *

* Structure is: *

     * byte 0    : format identifier (19)
     * byte 1    : bit mask of decoration identifiers (see DECO_* constants),
     *             in the packed long format (1-10 bytes)
     * byte next : packed int specifying the length of the first decoration
     * byte next : binary data
     * ...
     * 
* For each decoration, there is a packed int for its length, followed by * its binary data. The first decoration is the decorated value itself, if * present. *

* Note: FMT_IDO cannot be combined with FMT_BIN_EXT_DECO. */ public static final int FMT_BIN_EXT_DECO = 19; /** * Serialization format: A DefaultSerializer is NOT used. */ public static final int FMT_EXT = 21; /** * Serialization format: Optional value. */ public static final int FMT_OPT = 22; /** * Serialization format: OptionalInt value. */ public static final int FMT_OPT_INT = 23; /** * Serialization format: OptionalLong value. */ public static final int FMT_OPT_LONG = 24; /** * Serialization format: OptionalDouble value. */ public static final int FMT_OPT_DOUBLE = 25; /** * Decoration range: The minimum decoration identifier. */ public static final int DECO_ID_MIN = 0; /** * Decoration range: The maximum decoration identifier. */ public static final int DECO_ID_MAX = 63; /** * Decoration: The original value (before being decorated). */ public static final int DECO_VALUE = 0; /** * Decoration: The expiry for the value. */ public static final int DECO_EXPIRY = 1; /** * Decoration: The persistent state for the value. */ public static final int DECO_STORE = 2; /** * Decoration: Information managed on behalf of the transactions * implementation. */ public static final int DECO_TX = 3; /** * Decoration: Information managed on behalf of Push Replication. */ public static final int DECO_PUSHREP = 4; /** * Decoration: Reserved for future use by Coherence; do not use. */ public static final int DECO_RSVD_2 = 5; /** * Decoration: Reserved for future use by Coherence; do not use. */ public static final int DECO_RSVD_1 = 6; /** * Decoration: A client specific value (opaque). The original intent of the * "custom" decoration was that it would be reserved for use by application * code, but previous to Coherence 3.7 it was also used for the * OptimisticNamedCache implementation, the TopLink Grid implementation and * the Coherence Incubator's "Push Replication" project. As of Coherence * 3.7, this attribute is once again made available to frameworks and * applications, although care must be taken to avoid using the versions * of any of the frameworks that utilized this decoration. Applications are * instead encouraged to use the new {@link #DECO_APP_1}, * {@link #DECO_APP_2} and {@link #DECO_APP_3} decorations. */ public static final int DECO_CUSTOM = 7; /** * Decoration: Information managed on behalf of WebLogic. */ public static final int DECO_WLS = 9; /** * Decoration: Application-assignable decoration; this decoration will not * be used, modified or overwritten by Coherence or other Oracle products. */ public static final int DECO_APP_1 = 10; /** * Decoration: Application-assignable decoration; this decoration will not * be used, modified or overwritten by Coherence or other Oracle products. */ public static final int DECO_APP_2 = 11; /** * Decoration: Application-assignable decoration; this decoration will not * be used, modified or overwritten by Coherence or other Oracle products. */ public static final int DECO_APP_3 = 12; /** * Decoration: Information managed on behalf of Memcached acceptor. */ public static final int DECO_MEMCACHED = 13; /** * Decoration: Holds JCache specific meta-information for an entry. */ public static final int DECO_JCACHE = 14; /** * Decoration: Indicates if an update or delete is considered * to be synthetic for JCache. * (this is not the same as a Coherence synthetic update) */ public static final int DECO_JCACHE_SYNTHETIC = 15; /** * Decoration: Information about a queue element */ public static final int DECO_QUEUE_METADATA = 16; /** * The maximum number of bytes the header of the binary-decorated value * may contain. */ protected static final int MAX_DECO_HEADER_BYTES = 7; /** * Trints use 6 hexits (3 bytes), so the trint domain span is 0x01000000. */ public static final int TRINT_DOMAIN_SPAN = 0x01000000; /** * Trints use 6 hexits (3 bytes), so the trint maximum is 0x00FFFFFF. */ public static final int TRINT_MAX_VALUE = 0x00FFFFFF; /** * Trints use 6 hexits (3 bytes), so the trint maximum variance (from a * "current" value) is half the trint domain span, or 0x00800000. */ public static final int TRINT_MAX_VARIANCE = 0x00800000; /** * An empty array of Binary objects. */ public static final Binary[] EMPTY_BINARY_ARRAY = new Binary[0]; // ----- converters ----------------------------------------------------- /** * A converter from Object to Binary format that uses the DefaultSerializer. * * @since Coherence 2.4 */ public static final Converter CONVERTER_TO_BINARY = new Converter() { public Object convert(Object o) { return toBinary(o, ensureSerializer(null)); } }; /** * A converter from Binary to Object format, which uses the DefaultSerializer. * * @since Coherence 2.4 */ public static final Converter CONVERTER_FROM_BINARY = new Converter() { public Object convert(Object o) { return o == null ? null : fromBinary((Binary) o, ensureSerializer(null)); } }; /** * A pass-through Binary converter that removes an IntDecoration if present. * * @since Coherence 3.4 */ public static final Converter CONVERTER_STRIP_INTDECO = new Converter() { public Object convert(Object o) { if (o != null) { Binary bin = (Binary) o; if (isIntDecorated(bin)) { return removeIntDecoration(bin); } } return o; } }; // ----- stream wrappers ------------------------------------------------ /** * Marker interface. */ public interface Shielded { } /** * An InputStream that delegates all operations other than close to an * underlying InputStream. */ public static class ShieldedInputStream extends FilterInputStream implements InputStreaming, Shielded { public ShieldedInputStream(InputStream in) { super(in); } public final void close() { } } /** * An OutputStream that delegates all operations other than flush and * close to an underlying OutputStream. */ public static class ShieldedOutputStream extends WrapperOutputStream implements Shielded { public ShieldedOutputStream(OutputStream out) { super(out); } public final void flush() { } public final void close() { } } /** * An OutputStream that implements DataOutput that delegates all * operations other than flush and close to an underlying object that * implements DataOutput. */ public static class ShieldedDataOutputStream extends WrapperDataOutputStream implements Shielded { public ShieldedDataOutputStream(DataOutput out) { super(out); } public final void flush() { } public final void close() { } } /** * An OutputStream that implements ObjectOutput that delegates all * operations other than flush and close to an underlying object that * implements ObjectOutput. */ public static class ShieldedObjectOutputStream extends WrapperObjectOutputStream implements Shielded { public ShieldedObjectOutputStream(ObjectOutput out) { super(out); } public final void flush() { } public final void close() { } /** * Determine whether the underlying DataOutput is resolving. */ boolean isResolving() { return ExternalizableHelper.isResolving(this.getObjectOutput()); } } /** * Default ObjectStreamFactory implementation. */ public static class DefaultObjectStreamFactory implements ObjectStreamFactory { /** * Obtain an ObjectInput based on the passed DataInput. * * @param in the DataInput to be wrapped * @param loader the ClassLoader to be used * @param fForceNew if true, a new ObjectInput must be returned; otherwise, * if the passed stream is already an ObjectInput, it's * allowed to be returned instead * * @return an ObjectInput that delegates to ("wraps") the passed DataInput * * @throws IOException if an I/O exception occurs */ public ObjectInput getObjectInput(DataInput in, ClassLoader loader, boolean fForceNew) throws IOException { // check if the passed DataInput supports the necessary contracts if (!fForceNew && in instanceof ObjectInput && (!FORCE_RESOLVING_STREAMS || in instanceof Resolving)) { return (ObjectInput) in; } InputStream stream = getInputStream(in); loader = ensureClassLoader(loader == null && in instanceof WrapperDataInputStream ? ((WrapperDataInputStream) in).getClassLoader() : loader); return new ResolvingObjectInputStream(stream, loader); } /** * Obtain an ObjectOutput based on the passed DataOutput. * * @param out the DataOutput to be wrapped * * @return an ObjectOutput that delegates to ("wraps") the passed DataOutput * * @throws IOException if an I/O exception occurs */ public ObjectOutput getObjectOutput(DataOutput out) throws IOException { if (out instanceof ObjectOutput && (!FORCE_RESOLVING_STREAMS || isResolving(out))) { // the passed stream supports the necessary contracts, but we // have to prevent a nested close() from closing the stream that // we have been entrusted with return out instanceof Shielded ? (ObjectOutput) out : new ShieldedObjectOutputStream((ObjectOutput) out); } else { // block a nested close() from closing the underlying stream OutputStream stream = getOutputStream(out); return new ResolvingObjectOutputStream(stream); } } } // ----- Expiry-decoration helpers -------------------------------------- /** * Return a ReadBuffer whose contents represent the specified buffer with * the specified expiry encoded as a DECO_EXPIRY decoration. The * encoded expiry can be decoded via the {@link #decodeExpiry} method. * * @param buf the buffer to encode * @param ldtExpiry the expiry time, or {@link CacheMap#EXPIRY_DEFAULT} or * {@link CacheMap#EXPIRY_NEVER} * * @return an expiry-encoded ReadBuffer */ public static ReadBuffer encodeExpiry(ReadBuffer buf, long ldtExpiry) { if (ldtExpiry == CacheMap.EXPIRY_DEFAULT) { return undecorate(buf, DECO_EXPIRY); } WriteBuffer bufWrite = new BinaryWriteBuffer(8, 8); try { BufferOutput out = bufWrite.getBufferOutput(); out.writeLong(ldtExpiry < 0L ? CacheMap.EXPIRY_NEVER : ldtExpiry); } catch (IOException e) { throw ensureRuntimeException(e); } return decorate(buf, DECO_EXPIRY, bufWrite.toBinary()); } /** * Decode the expiry time from the specified ReadBuffer. * * @param buf the buffer to decode * * @return the decoded expiry, or {@link CacheMap#EXPIRY_DEFAULT} if none exists */ public static long decodeExpiry(ReadBuffer buf) { long ldtExpiry = CacheMap.EXPIRY_DEFAULT; if (!isDecorated(buf, DECO_EXPIRY)) { return ldtExpiry; } ReadBuffer bufExpiry = getDecoration(buf, DECO_EXPIRY); if (bufExpiry != null) { try { ldtExpiry = bufExpiry.getBufferInput().readLong(); } catch (Exception e) {} } return ldtExpiry; } // ----- int-Decorated values ------------------------------------------- /** * Decorate the specified value with the specified integer decoration. * * @param oValue the value to be decorated * @param nDecoration the integer decoration * * @return the decorated object */ public static IntDecoratedObject decorate(Object oValue, int nDecoration) { return new IntDecoratedObject(oValue, nDecoration); } /** * Decorate the specified ReadBuffer with the specified integer decoration. * * @param bufValue the ReadBuffer to be decorated * @param nDecoration the integer decoration * * @return the decorated (with integer decoration) ReadBuffer */ public static ReadBuffer decorateBinary(ReadBuffer bufValue, int nDecoration) { try { WriteBuffer buf = new BinaryWriteBuffer(6 + bufValue.length()); BufferOutput out = buf.getBufferOutput(); assert nDecoration != HashEncoded.UNENCODED; out.writeByte(FMT_IDO); out.writePackedInt(nDecoration); out.writeBuffer(bufValue); return buf.toBinary(); } catch (IOException e) { throw ensureRuntimeException(e); } } /** * Check whether or not the specified ReadBuffer is a representation of an * IntDecoratedObject. * * @param buf the ReadBuffer * * @return true iff the buffer contains (starts with) a representation of an * IntDecoratedObject * * @deprecated use {@link #isIntDecorated(ByteSequence)} instead */ @Deprecated public static boolean isIntDecorated(ReadBuffer buf) { return isIntDecorated((ByteSequence) buf); } /** * Check whether or not the specified ByteSequence is a representation of an * IntDecoratedObject. * * @param buf the ByteSequence * * @return true iff the buffer contains (starts with) a representation of an * IntDecoratedObject */ public static boolean isIntDecorated(ByteSequence buf) { try { return buf.byteAt(0) == FMT_IDO; } catch (IndexOutOfBoundsException e) { return false; } } /** * Extract a decoration value from the specified ReadBuffer that contains a * representation of an IntDecoratedObject. * * @param buf the ReadBuffer * * @return the integer decoration value */ public static int extractIntDecoration(ReadBuffer buf) { if (buf instanceof HashEncoded) { return ((HashEncoded) buf).getEncodedHash(); } try { DataInput in = buf.getBufferInput(); in.readUnsignedByte(); // skip the type return readInt(in); } catch (IOException e) { throw new IllegalArgumentException("invalid binary"); } } /** * Remove a decoration value from the specified Binary that contains a * representation of an IntDecoratedObject. * * @param bin the Binary object * * @return the undecorated Binary value * * @deprecated as of Coherence 3.7.2 */ public static Binary removeIntDecoration(Binary bin) { // Note: "upcast" is necessary in order to bind to the correct method return asBinary(removeIntDecoration((ReadBuffer) bin)); } /** * Remove a decoration value from the specified ReadBuffer that contains * a representation of an IntDecoratedObject. * * @param buf the ReadBuffer * * @return the undecorated ReadBuffer */ public static ReadBuffer removeIntDecoration(ReadBuffer buf) { try { BufferInput in = buf.getBufferInput(); in.readUnsignedByte(); // skip the type readInt(in); // skip the int decoration int of = in.getOffset(); return buf.getReadBuffer(of, buf.length() - of); } catch (IOException e) { throw new IllegalArgumentException("invalid binary"); } } /** * Read a char array. * * @param in a DataInput stream to read from * * @return a char array value * * @throws IOException if an I/O exception occurs */ public static char[] readCharArray(DataInput in) throws IOException { int cch = in.readInt(); validateLoadArray(char[].class, cch, in); Utf8Reader reader = new Utf8Reader((InputStream) in); return cch < CHUNK_THRESHOLD >> 1 ? readCharArray(reader, cch) : readLargeCharArray(reader, cch); } /** * Read an array of long numbers from a DataInput stream that use * fixed-length 8-byte Big Endian binary format. * * @param in a DataInput stream to read from * * @return an array of longs * * @throws IOException if an I/O exception occurs */ public static long[] readLongArray(DataInput in) throws IOException { int c = in.readInt(); validateLoadArray(long[].class, c, in); return c <= 0 ? new long[0] : c < CHUNK_THRESHOLD >> 3 ? readLongArray(in, c) : readLargeLongArray(in, c); } /** * Read an array of int numbers from a DataInput stream which * use fixed-length 4-byte Big Endian binary format. * * @param in a DataInput stream to read from * * @return an array of ints * * @throws IOException if an I/O exception occurs */ public static int[] readIntArray(DataInput in) throws IOException { int c = in.readInt(); validateLoadArray(int[].class, c, in); return c <= 0 ? new int[0] : c < CHUNK_THRESHOLD >> 2 ? readIntArray(in, c) : readLargeIntArray(in, c); } /** * Read an array of object from a DataInput stream. * * @param in a DataInput stream to read from * * @return an array of object * * @throws IOException if an I/O exception occurs */ public static Object[] readObjectArray(DataInput in) throws IOException { int c = in.readInt(); validateLoadArray(Object[].class, c, in); return c <= 0 ? new Object[0] : c < CHUNK_THRESHOLD >> 4 ? readObjectArray(in, c) : readLargeObjectArray(in, c); } /** * Return true if the provided class is allowed to be deserialized. * * @param clz the class to be checked * @param ois the ObjectInputStream * * @return true if the provided class is allowed to be deserialized */ protected static boolean checkObjectInputFilter(Class clz, ObjectInputStream ois) { return checkObjectInputFilter(clz, -1, (DataInput) ois); } /** * Return true if the provided class is allowed to be deserialized. * * @param clz the class to be checked * @param in input context containing ObjectInputFilter * * @return true if the provided class is allowed to be deserialized from in */ protected static boolean checkObjectInputFilter(Class clz, DataInput in) { return checkObjectInputFilter(clz, -1, in); } /** * Return true if the provided class is allowed to be deserialized. * * @param clz the class to be checked * @param cLength array length to be checked * @param in input context containing ObjectInputFilter * * @return true if the provided class is allowed to be deserialized from in */ protected static boolean checkObjectInputFilter(Class clz, int cLength, DataInput in) { Object oFilter = getObjectInputFilter(in); try { if (oFilter == null) { return true; } DynamicFilterInfo dynamic = s_tloHandler.get(); dynamic.setClass(clz); dynamic.setArrayLength(cLength); Object oFilterInfo = dynamic.getFilterInfo(); Enum status = (Enum) HANDLE_CHECKINPUT.invoke(oFilter, oFilterInfo); dynamic.setClass(null); dynamic.setArrayLength(-1); // TODO: we would like this to be programmatically enabled/disabled thus will // introduce a mechanism to do so which will remove the necessity for a single JVM arg. if (SERIAL_FILTER_LOGGING) { // similar to ObjectInputStream serialfilter logging, // only log status ACCEPTED(1)/REJECTED(2) when logging enabled // and FINE logging, UNDECIDED(0) is logged at FINER int nLogLevel = status.ordinal() > 0 ? Base.LOG_DEBUG : Base.LOG_QUIET; if (CacheFactory.isLogEnabled(nLogLevel)) { CacheFactory.log(String.format("ExternalizableHelper checkInput %-9s %s, array length: %s", status, clz, cLength), nLogLevel); } } return !status.name().equals("REJECTED"); } catch (ClassNotFoundException | IllegalAccessException | InvocationTargetException e) { err("Unable to invoke checkInput on " + oFilter.getClass().getName() + " due to exception " + e.getClass().getName() + " : " + e.getMessage()); } catch (Throwable t) {} return false; } /** * Return ObjectInputFilter associated with {@link DataInput}. * * @param in DataInput that may or may not have a ObjectInputFilter associated with it * * @return ObjectInputFilter associated with {@link DataInput in} or null when one does not exist */ protected static Object getObjectInputFilter(DataInput in) { try { while (in instanceof WrapperDataInputStream) { in = ((WrapperDataInputStream) in).getDataInput(); } return in instanceof BufferInput ? ((BufferInput) in).getObjectInputFilter() : HANDLE_GET_FILTER != null && in instanceof ObjectInputStream ? HANDLE_GET_FILTER.invoke((ObjectInputStream) in) : null; } catch (ClassNotFoundException | IllegalAccessException | InvocationTargetException e) { err("Unable to invoke method handle " + HANDLE_GET_FILTER + " on " + in.getClass().getName() + " due to exception " + e.getClass().getName() + ": " + e.getMessage()); } catch (Throwable t) {} return null; } /** * Return the static JVM-wide serial filter or {@code null} if not configured. * * @return ObjectInputFilter as an Object to enable working with Java versions before 9 or * null if no filter has been configured. */ public static Object getConfigSerialFilter() { Object oFilter = m_oFilterSerial; if (oFilter != null || HANDLE_CONFIG_GET_FILTER == null) { return oFilter; } else { try { oFilter = HANDLE_CONFIG_GET_FILTER.invoke(); if (oFilter != null) { synchronized (HANDLE_CONFIG_GET_FILTER) { if (m_oFilterSerial == null) { m_oFilterSerial = oFilter; } } if (SERIAL_FILTER_LOGGING) { CacheFactory.log("JVM wide ObjectInputFilter=" + oFilter, Base.LOG_INFO); } } return oFilter; } catch (ClassNotFoundException | IllegalAccessException | InvocationTargetException e) { err("Unable to invoke getSerialFilter on ObjectInputFilter$Config" + " due to exception " + e.getClass().getName() + ": " + e.getMessage()); } catch (Throwable t) {} } return null; } /** * Return the static JVM-wide serial filter factory. * * @return deserialization filter factory for Java version 17 and greater, null otherwise. */ public static BinaryOperator getConfigSerialFilterFactory() { BinaryOperator factory = m_serialFilterFactory; if (HANDLE_CONFIG_GET_FILTER_FACTORY == null || factory != null) { return factory; } else { try { factory = (BinaryOperator) HANDLE_CONFIG_GET_FILTER_FACTORY.invoke(); synchronized (HANDLE_CONFIG_GET_FILTER_FACTORY) { if (m_serialFilterFactory == null) { m_serialFilterFactory = factory; } } return factory; } catch (ClassNotFoundException | IllegalAccessException | InvocationTargetException | IllegalStateException e) { err("Unable to invoke getSerialFilterFactory on ObjectInputFilter$Config" + " due to exception " + e.getClass().getName() + ": " + e.getMessage()); } catch (Throwable t) { } } return null; } /** * Read an array of the specified number of int from a DataInput stream. * * @param in a DataInput stream to read from * @param c length to read * * @return an array of ints * * @throws IOException if an I/O exception occurs */ protected static int[] readIntArray(DataInput in, int c) throws IOException { int[] ai = new int[c]; for (int i = 0; i < c; i++) { ai[i] = in.readInt(); } return ai; } /** * Read an array of ints with length larger than {@link #CHUNK_THRESHOLD} {@literal >>} 2. * * @param in a DataInput stream to read from * @param cLength length to read * * @return an array of ints * * @throws IOException if an I/O exception occurs */ protected static int[] readLargeIntArray(DataInput in, int cLength) throws IOException { int cBatchMax = CHUNK_SIZE >> 2; int cBatch = cLength / cBatchMax + 1; int[] aMerged = null; int cRead = 0; int cAllocate = cBatchMax; int[] ai; for (int i = 0; i < cBatch && cRead < cLength; i++) { ai = readIntArray(in, cAllocate); aMerged = mergeIntArray(aMerged, ai); cRead += ai.length; cAllocate = Math.min(cLength - cRead, cBatchMax); } return aMerged; } /** * Read an array of the specified number of object from a DataInput stream. * * @param in a DataInput stream to read from * @param cLength length to read * * @return an array of objects * * @throws IOException if an I/O exception occurs */ protected static Object[] readObjectArray(DataInput in, int cLength) throws IOException { Object[] ao = new Object[cLength]; for (int i = 0; i < cLength; i++) { ao[i] = readObject(in); } return ao; } /** * Read an array of objects with length larger than {@link #CHUNK_THRESHOLD} {@literal >>} 4. * * @param in a DataInput stream to read from * @param cLength length to read * * @return an array of objects * * @throws IOException if an I/O exception occurs */ protected static Object[] readLargeObjectArray(DataInput in, int cLength) throws IOException { int cBatchMax = CHUNK_SIZE >> 4; int cBatch = cLength / cBatchMax + 1; Object[] aMerged = null; int cRead = 0; int cAllocate = cBatchMax; Object[] ao; for (int i = 0; i < cBatch && cRead < cLength; i++) { ao = readObjectArray(in, cAllocate); aMerged = mergeArray(aMerged, ao); cRead += ao.length; cAllocate = Math.min(cLength - cRead, cBatchMax); } return aMerged; } /** * Read an array of the specified number of longs from a DataInput stream. * * @param in a DataInput stream to read from * @param cLength length to read * * @return an array of longs * * @throws IOException if an I/O exception occurs */ protected static long[] readLongArray(DataInput in, int cLength) throws IOException { long[] al = new long[cLength]; for (int i = 0; i < cLength; i++) { al[i] = in.readLong(); } return al; } /** * Read an array of longs with length larger than {@link #CHUNK_THRESHOLD} {@literal >>} 3. * * @param in a DataInput stream to read from * @param cLength length to read * * @return an array of longs * * @throws IOException if an I/O exception occurs */ protected static long[] readLargeLongArray(DataInput in, int cLength) throws IOException { int cBatchMax = CHUNK_SIZE >> 3; int cBatch = cLength / cBatchMax + 1; long[] aMerged = null; int cRead = 0; int cAllocate = cBatchMax; long[] al; for (int i = 0; i < cBatch && cRead < cLength; i++) { al = readLongArray(in, cAllocate); aMerged = mergeLongArray(aMerged, al); cRead += al.length; cAllocate = Math.min(cLength - cRead, cBatchMax); } return aMerged; } /** * Read an array of char for the specified length from the reader. * * @param reader the Utf8Reader to read from * @param cLength the length to read */ protected static char[] readCharArray(Utf8Reader reader, int cLength) throws IOException { int of = 0; char[] ach = new char[cLength]; while (of < cLength) { int cchBlock = reader.read(ach, of,cLength - of); if (cchBlock < 0) { throw new EOFException(); } else { of += cchBlock; } } return ach; } /** * Read an array of char for the specified length from the reader. * * @param reader the Utf8Reader to read from * @param cLength the length to read */ protected static char[] readLargeCharArray(Utf8Reader reader, int cLength) throws IOException { int cBatchMax = CHUNK_SIZE >> 1; int cBatch = cLength / cBatchMax + 1; char[] aMerged = null; int cRead = 0; int cAllocate = cBatchMax; char[] ach; for (int i = 0; i < cBatch && cRead < cLength; i++) { ach = readCharArray(reader, cAllocate); aMerged = mergeCharArray(aMerged, ach); cRead += ach.length; cAllocate = Math.min(cLength - cRead, cBatchMax); } return aMerged; } /** * Read byte array with length larger than {@link #CHUNK_THRESHOLD}. * * @param in a DataInput stream to read from * @param cb number of bytes to read * * @return a read byte array value * * @throws IOException if an I/O exception occurs */ protected static byte[] readLargeByteArray(DataInput in, int cb) throws IOException { int cBatchMax = CHUNK_SIZE; int cBatch = cb / cBatchMax + 1; byte[] ab = new byte[cBatchMax]; byte[] aMerged = null; int cbRead = 0; for (int i = 0; i < cBatch && cbRead < cb; i++) { in.readFully(ab); aMerged = mergeByteArray(aMerged, ab); cbRead += ab.length; ab = new byte[Math.min(cb - cbRead, cBatchMax)]; } return aMerged; } /** * Read the specified number of booleans from a boolean array. * * @param in a DataInput stream to read from * @param cLength the length to read * * @return a boolean array value * * @throws IOException if an I/O exception occurs */ protected static boolean[] readBooleanArray(DataInput in, int cLength) throws IOException { boolean[] af = new boolean[cLength]; for (int of = 0, cb = (cLength + 7) / 8, i = 0; of < cb; ++of) { int nBits = in.readUnsignedByte(); for (int nMask = 1; i < cLength && nMask <= 0xFF; nMask <<= 1) { af[i++] = (nBits & nMask) != 0; } } return af; } /** * Read a boolean array with length larger than {@link #CHUNK_THRESHOLD}. * * @param in a DataInput stream to read from * @param cLength length to read * * @return the read boolean array * * @throws IOException if an I/O exception occurs */ protected static boolean[] readLargeBooleanArray(DataInput in, int cLength) throws IOException { int cBatchMax = CHUNK_SIZE & ~0x7; int cBatch = cLength / cBatchMax + 1; int cRead = 0; int cAllocate = cBatchMax; boolean[] aMerged = null; boolean[] af; for (int i = 0; i < cBatch && cRead < cLength; i++) { af = readBooleanArray(in, cAllocate); aMerged = mergeBooleanArray(aMerged, af); cRead += af.length; cAllocate = Math.min(cLength - cRead, cBatchMax); } return aMerged; } /** * Read an array of the specified number of floats from a DataInput stream. * * @param in a DataInput stream to read from * @param cfl the length to read * * @return an array of floats * * @throws IOException if an I/O exception occurs */ protected static float[] readFloatArray(DataInput in, int cfl) throws IOException { byte[] ab = new byte[cfl << 2]; in.readFully(ab); float[] afl = new float[cfl]; for (int i = 0, of = 0; i < cfl; i++) { // Unfortunately we cannot win this battle: // the standard serialization goes native and does not // do any conversion at all: // // ival = ((bytes[srcpos + 0] & 0xFF) << 24) + // ((bytes[srcpos + 1] & 0xFF) << 16) + // ((bytes[srcpos + 2] & 0xFF) << 8) + // ((bytes[srcpos + 3] & 0xFF) << 0); // u.i = (long) ival; // floats[dstpos] = (jfloat) u.f; int iValue = ((ab[of++] & 0xff) << 24) + ((ab[of++] & 0xff) << 16) + ((ab[of++] & 0xff) << 8) + ((ab[of++] & 0xff)); afl[i] = Float.intBitsToFloat(iValue); } return afl; } /** * Read a float array with length larger than {@link #CHUNK_THRESHOLD} {@literal >>} 2. * * @param in a DataInput stream to read from * @param cLength length to read * * @return the read float array value * * @throws IOException if an I/O exception occurs */ protected static float[] readLargeFloatArray(DataInput in, int cLength) throws IOException { int cBatchMax = CHUNK_SIZE >> 2; int cBatch = cLength / cBatchMax + 1; float[] aflMerged = null; int cRead = 0; int cAllocate = cBatchMax; float[] afl; for (int i = 0; i < cBatch && cRead < cLength; i++) { afl = readFloatArray(in, cAllocate); aflMerged = mergeFloatArray(aflMerged, afl); cRead += afl.length; cAllocate = Math.min(cLength - cRead, cBatchMax); } return aflMerged; } /** * Read an array of the specified number of doubles from a DataInput stream. * * @param in a DataInput stream to read from * @param cdfl length to read * * @return an array of doubles * * @throws IOException if an I/O exception occurs */ protected static double[] readDoubleArray(DataInput in, int cdfl) throws IOException { byte[] ab = new byte[cdfl << 3]; in.readFully(ab); double[] adfl = new double[cdfl]; for (int i = 0, of = 0; i < cdfl; i++) { int iUpper = ((ab[of++] & 0xff) << 24) + ((ab[of++] & 0xff) << 16) + ((ab[of++] & 0xff) << 8) + ((ab[of++] & 0xff)); int iLower = ((ab[of++] & 0xff) << 24) + ((ab[of++] & 0xff) << 16) + ((ab[of++] & 0xff) << 8) + ((ab[of++] & 0xff)); adfl[i] = Double.longBitsToDouble( (((long) iUpper) << 32) + (iLower & 0xFFFFFFFFL)); } return adfl; } /** * Read a double array with length larger than {@link #CHUNK_THRESHOLD} {@literal >>} 3. * * @param in a DataInput stream to read from * @param cLength the length to read * * @return an array of doubles * * @throws IOException if an I/O exception occurs */ protected static double[] readLargeDoubleArray(DataInput in, int cLength) throws IOException { int cBatchMax = CHUNK_SIZE >> 3; int cBatch = cLength / cBatchMax + 1; int cAllocate = cBatchMax; double[] adflMerged = null; int cdflRead = 0; double[] adfl; for (int i = 0; i < cBatch && cdflRead < cLength; i++) { adfl = readDoubleArray(in, cAllocate); adflMerged = mergeDoubleArray(adflMerged, adfl); cdflRead += adfl.length; cAllocate = Math.min(cLength - cdflRead, cBatchMax); } return adflMerged; } /** * Read array of string for the specified size. * * @param in a DataInput stream to read from * @param c length to read * * @return the read string array value * * @throws IOException if an I/O exception occurs */ protected static String[] readStringArray(DataInput in, int c) throws IOException { String[] as = new String[c]; for (int i = 0; i < c; ++i) { as[i] = readSafeUTF(in); } return as; } /** * Read array of string with length larger than threshold {@link #CHUNK_THRESHOLD} {@literal >>} 3. * * @param in a DataInput stream to read from * @param c length to read * * @return the read string array value * * @throws IOException if an I/O exception occurs */ protected static String[] readLargeStringArray(DataInput in, int c) throws IOException { int cBatchMax = CHUNK_SIZE >> 3; int cBatch = c / cBatchMax + 1; int cRead = 0; int cAllocate = cBatchMax; String[] asMerged = null; String[] as; for (int i = 0; i < cBatch && cRead < c; i++) { as = readStringArray(in, cAllocate); asMerged = mergeArray(asMerged, as); cRead += as.length; cAllocate = Math.min(c - cRead, cBatchMax); } return asMerged; } /** * Return class for the specified class name; null if not found. * * @param sClass the class name * * @return the class for the specified class name */ public static Class getClass(String sClass) { try { return Class.forName(sClass); } catch (ClassNotFoundException cnfe) { return null; } } /** * Integer decorated object. */ protected static final class IntDecoratedObject extends ExternalizableHelper implements Serializable { // ----- constructors ----------------------------------------------- /** * Construct an IntDecorated object with the specified value and decoration. * * @param oValue the value to decorate * @param nDecoration the int decoration */ public IntDecoratedObject(Object oValue, int nDecoration) { azzert(!(oValue instanceof IntDecoratedObject)); m_oValue = oValue; m_nDecoration = nDecoration; } // ----- accessors -------------------------------------------------- /** * Return the underlying value. * * @return the underlying value */ public Object getValue() { return m_oValue; } /** * Return the int decoration. * * @return the int decoration */ public int getDecoration() { return m_nDecoration; } // ----- Serializable interface ------------------------------------- /** * Psuedo-interface. Standard serialization is not allowed. */ private void writeObject(ObjectOutputStream stream) throws IOException { throw new IOException("not allowed"); } /** * Psuedo-interface. Standard de-serialization is not allowed. */ private void readObject(ObjectInputStream stream) throws IOException, ClassNotFoundException { throw new IOException("not allowed"); } // ----- data members ----------------------------------------------- /** * The decorated (original) object value. */ private Object m_oValue; /** * The decoration integer value. */ private int m_nDecoration; } // ----- XmlBean class caching ------------------------------------------ /** * An interface for caching class reference by integer ID values. */ public interface XmlBeanClassCache { /** * Initialize the XmlBeanClassCache. * * @param xml the XML configuration for the cache */ public void init(XmlElement xml); /** * Look up the class ID for the specified class. * * @param clz the class to look up * * @return the ID if the class is known; otherwise -1 */ public int getClassId(Class clz); /** * Look up the class for the specified ID. * * @param nId the class ID * @param loader the ClassLoader for the class to load * * @return the class for that class ID */ public Class getClass(int nId, ClassLoader loader); } /** * An implementation XmlBeanClassCache that uses a pre-defined list of * XmlBean implementations. */ public static class SimpleXmlBeanClassCache extends Base implements XmlBeanClassCache { // ----- XmlBeanClassCache methods ---------------------------------- /** * Initialize the XmlBeanClassCache. * * @param xml the XML configuration for the cache */ public void init(XmlElement xml) { // build list of classes List list = new ArrayList(); for (Iterator iter = xml.getSafeElement("xmlbean-list") .getElements("xmlbean-class"); iter.hasNext(); ) { XmlElement xmlClassName = (XmlElement) iter.next(); String sClass = xmlClassName.getString(null); list.add(sClass == null ? null : sClass.intern()); } m_asBeans = (String[]) list.toArray(new String[list.size()]); // determine whether or not this implementation needs to be // ClassLoader-aware if (xml.getSafeElement("classloader-aware").getBoolean()) { m_fAware = true; // note that the large load factor will guarantee that the // map will never resize m_mapBeanClasses = new WeakHashMap(101, 1000.0F); } } /** * Look up the class ID for the specified class. * * @param clz the class to look up * * @return the ID if the class is known; otherwise -1 */ public int getClassId(Class clz) { String sName = clz.getName(); String[] asBeans = m_asBeans; for (int i = 0, c = asBeans.length; i < c; ++i) { if (equals(asBeans[i], sName)) { return i; } } return -1; } /** * Look up the class for the specified ID. * * @param nId the class ID * @param loader the ClassLoader for the class to load * * @return the class for that class ID */ public Class getClass(int nId, ClassLoader loader) { Class clz = null; if (m_fAware) { WeakReference[] aref = (WeakReference[]) m_mapBeanClasses.get(loader); if (aref == null) { aref = initClassLoader(loader); } try { clz = (Class) aref[nId].get(); } catch (NullPointerException e) { } } else { Class[] aclz = m_aclzBeans; if (aclz == null) { m_aclzBeans = aclz = initClasses(loader); } try { clz = aclz[nId]; } catch (IndexOutOfBoundsException e) { } } if (clz == null) { if (nId < 0) { throw new IndexOutOfBoundsException("Class ID=" + nId + "; a negative XmlBean ID is used to indicate" + " an \"unknown\" XmlBean class"); } else { throw new IndexOutOfBoundsException("Class ID=" + nId + ", Max ID=" + (m_aclzBeans.length - 1)); } } return clz; } // ----- internal --------------------------------------------------- /** * Given the specified ClassLoader, make sure that the XmlBean * classes have all been looked up within that ClassLoader. * * @param loader the ClassLoader to use to look up the XmlBean * classes * * @return an array of WeakReferences to Classes, one for each * specified XmlBean */ private WeakReference[] initClassLoader(ClassLoader loader) { azzert(m_fAware); Class[] aclz = initClasses(loader); int c = aclz.length; WeakReference[] aref = new WeakReference[c]; for (int i = 0; i < c; ++i) { aref[i] = new WeakReference(aclz[i]); } Map map = m_mapBeanClasses; synchronized (map) { map.put(loader, aref); } return aref; } /** * Given the specified ClassLoader, load all the XmlBean classes * that have been specified to be serialization-optimized. * * @param loader the ClassLoader to load for * * @return an array of classes, one for each specified XmlBean */ private Class[] initClasses(ClassLoader loader) { String[] asBeans = m_asBeans; int cBeans = asBeans.length; Class[] aclz = new Class[cBeans]; for (int i = 0; i < cBeans; ++i) { String sBean = asBeans[i]; if (sBean != null && sBean.length() > 0) { try { aclz[i] = loadClass(sBean, loader, null); } catch (ClassNotFoundException e) { throw ensureRuntimeException(e); } } } return aclz; } // ----- data members ----------------------------------------------- /** * XmlBean class cache is ClassLoader aware or not. */ private boolean m_fAware; /** * Array of class names. */ private String[] m_asBeans; /** * Array of classes. This array is only used if the implementation is * ClassLoader un-aware. */ private Class[] m_aclzBeans; /** * Map of arrays of WeakReferences to Classes, keyed by ClassLoader. */ private WeakHashMap m_mapBeanClasses; } /** * DynamicFilterInfo is an InvocationHandler that has association with * a single proxy instance. */ private static class DynamicFilterInfo implements InvocationHandler { // ----- DynamicFilterInfo methods ---------------------------------- public DynamicFilterInfo() {}; /** * Return the proxy instance. * * @return the proxy instance */ public Object getFilterInfo() { Object oProxy = m_oProxy; if (oProxy == null) { oProxy = m_oProxy = Proxy.newProxyInstance(getContextClassLoader(), new Class[]{s_clzFilterInfo}, this); } return oProxy; } /** * Set the class to be checked. * * @param clz the class to check */ public void setClass(Class clz) { m_clz = clz; } /** * Set the array length to be checked * * @param cLength array length to check, -1 indicates not an array */ public void setArrayLength(int cLength) { m_cArrayLength = cLength; } // ----- InvocationHandler interface -------------------------------- @Override public Object invoke(Object proxy, Method method, Object[] args) throws Throwable { if (method.getName().equals("serialClass")) { return m_clz; } else if (method.getName().equals("arrayLength")) { return (long) m_cArrayLength; } else if (method.getName().equals("depth")) { return Long.valueOf(1); } else if (method.getName().equals("references")) { return Long.valueOf(0); } else if (method.getName().equals("streamBytes")) { return Long.valueOf(0); } return null; } // ----- data members ----------------------------------------------- /** * The class to be checked by ObjectInputFilter. */ private Class m_clz; /** * The array length, -1 indicates not an array. */ private int m_cArrayLength = -1; /** * The dynamic proxy. */ private Object m_oProxy; } // ----- configurable options ------------------------------------------- /** * The name of the system property that can be used to override the location * of the ExternalizableHelper configuration file. *

* The value of this property must be the name of a resource that contains * an XML document with the structure defined in the * /com/tangosol/util/ExternalizableHelper.xml configuration * descriptor. */ public static final String PROPERTY_CONFIG = "coherence.externalizable.config"; /** * Option: Always use a ResolvingObjectInputStream, even if a regular * ObjectInputStream is available. */ public static final boolean FORCE_RESOLVING_STREAMS; /** * Option: Use an XmlBean class cache. */ public static final boolean USE_XMLBEAN_CLASS_CACHE; /** * Option: XmlBean class cache implementation. */ public static final XmlBeanClassCache XMLBEAN_CLASS_CACHE; /** * The total buffer allocation limit; zero for no limit. */ private static final int MAX_BUFFER; /** * Option: Use POF as the default serialization format. */ public static final boolean USE_POF_STREAMS; /** * Option: Configurable ObjectStreamFactory. */ public static ObjectStreamFactory s_streamfactory; /** * MethodHandle for getfilter from ObjectInputStream. */ private static final MethodHandle HANDLE_GET_FILTER; /** * MethodHandle for checkInput from ObjectInputFilter. */ private static final MethodHandle HANDLE_CHECKINPUT; /** * MethodHandle for method getSerialFilter from ObjectInputFilter$Config. */ private static final MethodHandle HANDLE_CONFIG_GET_FILTER; /** * MethodHandle for method getSerialFilterFactory from ObjectInputFilter$Config. */ private static final MethodHandle HANDLE_CONFIG_GET_FILTER_FACTORY; /** * Filter info class. */ private static Class s_clzFilterInfo = null; /** * The DynamicFilterInfo ThreadLocal. */ private final static ThreadLocal s_tloHandler = ThreadLocal.withInitial(DynamicFilterInfo::new); static { boolean fResolve = true; boolean fCache = false; XmlBeanClassCache cache = null; int cbMax = 0; boolean fPof = false; ObjectStreamFactory factory = null; try { XmlDocument xml = AccessController.doPrivileged(new PrivilegedAction() { public XmlDocument run() { String sConfig = Config.getProperty(PROPERTY_CONFIG); XmlDocument xml = null; if (sConfig != null && sConfig.length() > 0) { URL url = Resources.findResource(sConfig, null); Throwable e = null; if (url != null) { try { xml = XmlHelper.loadXml(url.openStream()); } catch (Throwable t) {e = t;} } if (xml == null) { err("Unable to load ExternalizableHelper configuration file \"" + sConfig + "\";"); if (e != null) { err(e); } err("Using default configuration."); } } if (xml == null) { xml = XmlHelper.loadXml(ExternalizableHelper.class, "ISO-8859-1"); } XmlHelper.replaceSystemProperties(xml, "system-property"); return xml; } }); final XmlElement xmlFactory = xml.getSafeElement("object-stream-factory"); factory = AccessController.doPrivileged(new PrivilegedAction() { public ObjectStreamFactory run() { try { if (!XmlHelper.isInstanceConfigEmpty(xmlFactory)) { return (ObjectStreamFactory) XmlHelper.createInstance( xmlFactory, ExternalizableHelper.class.getClassLoader(), null); } } catch (Exception e) { err("Unable to instantiate an ObjectStreamFactory \"" + xmlFactory + "\":"); err(e); } return new DefaultObjectStreamFactory(); } }); fResolve = xml.getSafeElement("force-classloader-resolving").getBoolean(fResolve); fCache = xml.getSafeElement("enable-xmlbean-class-cache").getBoolean(fCache); if (fCache) { XmlElement xmlCfg = xml.getElement("xmlbean-class-cache-config"); if (xmlCfg != null) { String sImpl = xml.getSafeElement("cache-class").getString(null); try { if (sImpl == null) { cache = new SimpleXmlBeanClassCache(); } else { cache = (XmlBeanClassCache) Class.forName(sImpl).newInstance(); } cache.init(xmlCfg); } catch (Throwable e) { fCache = false; err("Unable to instantiate and configure class cache \"" + sImpl + "\":"); err(e); } } } String sMax = xml.getSafeElement("serialization-maxbuffer").getString("0"); cbMax = (int) parseMemorySize(sMax, POWER_0); fPof = xml.getSafeElement("enable-pof-serialization").getBoolean(fPof); } catch (Throwable e) {} FORCE_RESOLVING_STREAMS = fResolve; USE_XMLBEAN_CLASS_CACHE = fCache; XMLBEAN_CLASS_CACHE = cache; MAX_BUFFER = cbMax; USE_POF_STREAMS = fPof; s_streamfactory = factory; // initialize method handles for potential JEP-290 checks Class clzFilterInfo = null; MethodHandle handleGetFilter = null; MethodHandle handleCheckInput = null; MethodHandle handleConfigGetSerialFilter = null; MethodHandle handleConfigGetFilterFactory = null; Method methodConfigGetSerialFilter = null; Method methodConfigGetFilterFactory = null; // find ObjectInputFilter class; depending on jdk version try { Class clzFilter = null; Class clzFilterStatus = null; Class clzConfig = null; String sFilterMethod = null; Method methodGet = null; if ((clzFilter = getClass("java.io.ObjectInputFilter")) != null) { clzFilterInfo = Class.forName("java.io.ObjectInputFilter$FilterInfo"); clzFilterStatus = (Class) Class.forName("java.io.ObjectInputFilter$Status"); sFilterMethod = "getObjectInputFilter"; clzConfig = Class.forName("java.io.ObjectInputFilter$Config"); } else if ((clzFilter = getClass("sun.misc.ObjectInputFilter")) != null) { clzFilterInfo = Class.forName("sun.misc.ObjectInputFilter$FilterInfo"); clzFilterStatus = (Class) Class.forName("sun.misc.ObjectInputFilter$Status"); sFilterMethod = "getInternalObjectInputFilter"; clzConfig = Class.forName("sun.misc.ObjectInputFilter$Config"); } if (sFilterMethod != null) { Class clzObjectInputStream = ObjectInputStream.class; methodGet = clzObjectInputStream.getDeclaredMethod(sFilterMethod); methodGet.setAccessible(true); methodConfigGetSerialFilter = clzConfig.getDeclaredMethod("getSerialFilter"); methodConfigGetSerialFilter.setAccessible(true); try { methodConfigGetFilterFactory = clzConfig.getDeclaredMethod("getSerialFilterFactory"); } catch (NoSuchMethodException e) { // ignore when not defined in java version less than 17 } catch (Throwable t) { CacheFactory.log("Failed to find method ObjectInputFilter$Config.getSerialFilterFactory() in java version " + System.getProperty("java.version") + " due to: " + t.getMessage(), Base.LOG_INFO); } MethodType mtCheckInput = MethodType.methodType(clzFilterStatus, clzFilterInfo); MethodHandles.Lookup lookup = MethodHandles.lookup(); handleGetFilter = lookup.unreflect(methodGet); handleCheckInput = lookup.findVirtual(clzFilter, "checkInput", mtCheckInput); handleConfigGetSerialFilter = lookup.unreflect(methodConfigGetSerialFilter); handleConfigGetFilterFactory = methodConfigGetFilterFactory == null ? null : lookup.unreflect(methodConfigGetFilterFactory); } } catch (ClassNotFoundException | NoSuchMethodException | SecurityException | IllegalAccessException e) { CacheFactory.log("ObjectInputFilter will not be honored due to: " + e.getMessage() + '\n' + Base.printStackTrace(e), Base.LOG_INFO); } s_clzFilterInfo = clzFilterInfo; HANDLE_GET_FILTER = handleGetFilter; HANDLE_CHECKINPUT = handleCheckInput; HANDLE_CONFIG_GET_FILTER = handleConfigGetSerialFilter; HANDLE_CONFIG_GET_FILTER_FACTORY = handleConfigGetFilterFactory; } // ----- data members --------------------------------------------------- /** * A threshold used to decide whether to perform deserialization using a chunking * algorithm; default is greater than 128MB. */ public static final int CHUNK_THRESHOLD = 0x7FFFFFF; /** * When using the chunking algorithm each chunk is constrained to 64MB by default. */ public static final int CHUNK_SIZE = 0x3FFFFFF; /** * An array of Stats objects, indexed by the modulo of a swizzled class * hashcode. */ private static final Stats[] s_astats = new Stats[6451]; /** * WeakHashMap of Serializers, keyed by ClassLoader. */ private static final Map s_mapSerializerByClassLoader = Collections.synchronizedMap(new WeakHashMap<>()); /** * Enable tracing of {@link ExternalizableHelper#checkObjectInputFilter(Class, DataInput) ExternalizableLite serial filtering}. * Log level must by FINE or higher to get detailed tracing. */ private static final boolean SERIAL_FILTER_LOGGING = Config.getBoolean("coherence.serialfilter.logging", false); /** * Cache of JVM-wide serial filter. */ private static Object m_oFilterSerial; /** * Cache of JVM-wide serial filter factory. */ private static BinaryOperator m_serialFilterFactory; }





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