/*
* Copyright (c) 2009-2012 jMonkeyEngine
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are
* met:
*
* * Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
*
* * Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* * Neither the name of 'jMonkeyEngine' nor the names of its contributors
* may be used to endorse or promote products derived from this software
* without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
* "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
* TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
* PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR
* CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
* EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
* PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
* PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF
* LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING
* NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
package com.jme3.export.binary;
import com.jme3.export.InputCapsule;
import com.jme3.export.Savable;
import com.jme3.export.SavableClassUtil;
import com.jme3.util.BufferUtils;
import com.jme3.util.IntMap;
import java.io.IOException;
import java.io.UnsupportedEncodingException;
import java.nio.ByteBuffer;
import java.nio.FloatBuffer;
import java.nio.IntBuffer;
import java.nio.ShortBuffer;
import java.util.ArrayList;
import java.util.BitSet;
import java.util.HashMap;
import java.util.Map;
import java.util.logging.Level;
import java.util.logging.Logger;
/**
* @author Joshua Slack
*/
final class BinaryInputCapsule implements InputCapsule {
private static final Logger logger = Logger
.getLogger(BinaryInputCapsule.class.getName());
protected BinaryImporter importer;
protected BinaryClassObject cObj;
protected Savable savable;
protected HashMap<Byte, Object> fieldData;
protected int index = 0;
public BinaryInputCapsule(BinaryImporter importer, Savable savable, BinaryClassObject bco) {
this.importer = importer;
this.cObj = bco;
this.savable = savable;
}
public void setContent(byte[] content, int start, int limit) {
fieldData = new HashMap<Byte, Object>();
for (index = start; index < limit;) {
byte alias = content[index];
index++;
try {
byte type = cObj.aliasFields.get(alias).type;
Object value = null;
switch (type) {
case BinaryClassField.BITSET: {
value = readBitSet(content);
break;
}
case BinaryClassField.BOOLEAN: {
value = readBoolean(content);
break;
}
case BinaryClassField.BOOLEAN_1D: {
value = readBooleanArray(content);
break;
}
case BinaryClassField.BOOLEAN_2D: {
value = readBooleanArray2D(content);
break;
}
case BinaryClassField.BYTE: {
value = readByte(content);
break;
}
case BinaryClassField.BYTE_1D: {
value = readByteArray(content);
break;
}
case BinaryClassField.BYTE_2D: {
value = readByteArray2D(content);
break;
}
case BinaryClassField.BYTEBUFFER: {
value = readByteBuffer(content);
break;
}
case BinaryClassField.DOUBLE: {
value = readDouble(content);
break;
}
case BinaryClassField.DOUBLE_1D: {
value = readDoubleArray(content);
break;
}
case BinaryClassField.DOUBLE_2D: {
value = readDoubleArray2D(content);
break;
}
case BinaryClassField.FLOAT: {
value = readFloat(content);
break;
}
case BinaryClassField.FLOAT_1D: {
value = readFloatArray(content);
break;
}
case BinaryClassField.FLOAT_2D: {
value = readFloatArray2D(content);
break;
}
case BinaryClassField.FLOATBUFFER: {
value = readFloatBuffer(content);
break;
}
case BinaryClassField.FLOATBUFFER_ARRAYLIST: {
value = readFloatBufferArrayList(content);
break;
}
case BinaryClassField.BYTEBUFFER_ARRAYLIST: {
value = readByteBufferArrayList(content);
break;
}
case BinaryClassField.INT: {
value = readInt(content);
break;
}
case BinaryClassField.INT_1D: {
value = readIntArray(content);
break;
}
case BinaryClassField.INT_2D: {
value = readIntArray2D(content);
break;
}
case BinaryClassField.INTBUFFER: {
value = readIntBuffer(content);
break;
}
case BinaryClassField.LONG: {
value = readLong(content);
break;
}
case BinaryClassField.LONG_1D: {
value = readLongArray(content);
break;
}
case BinaryClassField.LONG_2D: {
value = readLongArray2D(content);
break;
}
case BinaryClassField.SAVABLE: {
value = readSavable(content);
break;
}
case BinaryClassField.SAVABLE_1D: {
value = readSavableArray(content);
break;
}
case BinaryClassField.SAVABLE_2D: {
value = readSavableArray2D(content);
break;
}
case BinaryClassField.SAVABLE_ARRAYLIST: {
value = readSavableArray(content);
break;
}
case BinaryClassField.SAVABLE_ARRAYLIST_1D: {
value = readSavableArray2D(content);
break;
}
case BinaryClassField.SAVABLE_ARRAYLIST_2D: {
value = readSavableArray3D(content);
break;
}
case BinaryClassField.SAVABLE_MAP: {
value = readSavableMap(content);
break;
}
case BinaryClassField.STRING_SAVABLE_MAP: {
value = readStringSavableMap(content);
break;
}
case BinaryClassField.INT_SAVABLE_MAP: {
value = readIntSavableMap(content);
break;
}
case BinaryClassField.SHORT: {
value = readShort(content);
break;
}
case BinaryClassField.SHORT_1D: {
value = readShortArray(content);
break;
}
case BinaryClassField.SHORT_2D: {
value = readShortArray2D(content);
break;
}
case BinaryClassField.SHORTBUFFER: {
value = readShortBuffer(content);
break;
}
case BinaryClassField.STRING: {
value = readString(content);
break;
}
case BinaryClassField.STRING_1D: {
value = readStringArray(content);
break;
}
case BinaryClassField.STRING_2D: {
value = readStringArray2D(content);
break;
}
default:
// skip put statement
continue;
}
fieldData.put(alias, value);
} catch (IOException e) {
logger.logp(Level.SEVERE, this.getClass().toString(),
"setContent(byte[] content)", "Exception", e);
}
}
}
public int getSavableVersion(Class<? extends Savable> desiredClass){
return SavableClassUtil.getSavedSavableVersion(savable, desiredClass,
cObj.classHierarchyVersions, importer.getFormatVersion());
}
public BitSet readBitSet(String name, BitSet defVal) throws IOException {
BinaryClassField field = cObj.nameFields.get(name);
if (field == null || !fieldData.containsKey(field.alias))
return defVal;
return (BitSet) fieldData.get(field.alias);
}
public boolean readBoolean(String name, boolean defVal) throws IOException {
BinaryClassField field = cObj.nameFields.get(name);
if (field == null || !fieldData.containsKey(field.alias))
return defVal;
return ((Boolean) fieldData.get(field.alias)).booleanValue();
}
public boolean[] readBooleanArray(String name, boolean[] defVal)
throws IOException {
BinaryClassField field = cObj.nameFields.get(name);
if (field == null || !fieldData.containsKey(field.alias))
return defVal;
return (boolean[]) fieldData.get(field.alias);
}
public boolean[][] readBooleanArray2D(String name, boolean[][] defVal)
throws IOException {
BinaryClassField field = cObj.nameFields.get(name);
if (field == null || !fieldData.containsKey(field.alias))
return defVal;
return (boolean[][]) fieldData.get(field.alias);
}
public byte readByte(String name, byte defVal) throws IOException {
BinaryClassField field = cObj.nameFields.get(name);
if (field == null || !fieldData.containsKey(field.alias))
return defVal;
return ((Byte) fieldData.get(field.alias)).byteValue();
}
public byte[] readByteArray(String name, byte[] defVal) throws IOException {
BinaryClassField field = cObj.nameFields.get(name);
if (field == null || !fieldData.containsKey(field.alias))
return defVal;
return (byte[]) fieldData.get(field.alias);
}
public byte[][] readByteArray2D(String name, byte[][] defVal)
throws IOException {
BinaryClassField field = cObj.nameFields.get(name);
if (field == null || !fieldData.containsKey(field.alias))
return defVal;
return (byte[][]) fieldData.get(field.alias);
}
public ByteBuffer readByteBuffer(String name, ByteBuffer defVal)
throws IOException {
BinaryClassField field = cObj.nameFields.get(name);
if (field == null || !fieldData.containsKey(field.alias))
return defVal;
return (ByteBuffer) fieldData.get(field.alias);
}
@SuppressWarnings("unchecked")
public ArrayList<ByteBuffer> readByteBufferArrayList(String name,
ArrayList<ByteBuffer> defVal) throws IOException {
BinaryClassField field = cObj.nameFields.get(name);
if (field == null || !fieldData.containsKey(field.alias))
return defVal;
return (ArrayList<ByteBuffer>) fieldData.get(field.alias);
}
public double readDouble(String name, double defVal) throws IOException {
BinaryClassField field = cObj.nameFields.get(name);
if (field == null || !fieldData.containsKey(field.alias))
return defVal;
return ((Double) fieldData.get(field.alias)).doubleValue();
}
public double[] readDoubleArray(String name, double[] defVal)
throws IOException {
BinaryClassField field = cObj.nameFields.get(name);
if (field == null || !fieldData.containsKey(field.alias))
return defVal;
return (double[]) fieldData.get(field.alias);
}
public double[][] readDoubleArray2D(String name, double[][] defVal)
throws IOException {
BinaryClassField field = cObj.nameFields.get(name);
if (field == null || !fieldData.containsKey(field.alias))
return defVal;
return (double[][]) fieldData.get(field.alias);
}
public float readFloat(String name, float defVal) throws IOException {
BinaryClassField field = cObj.nameFields.get(name);
if (field == null || !fieldData.containsKey(field.alias))
return defVal;
return ((Float) fieldData.get(field.alias)).floatValue();
}
public float[] readFloatArray(String name, float[] defVal)
throws IOException {
BinaryClassField field = cObj.nameFields.get(name);
if (field == null || !fieldData.containsKey(field.alias))
return defVal;
return (float[]) fieldData.get(field.alias);
}
public float[][] readFloatArray2D(String name, float[][] defVal)
throws IOException {
BinaryClassField field = cObj.nameFields.get(name);
if (field == null || !fieldData.containsKey(field.alias))
return defVal;
return (float[][]) fieldData.get(field.alias);
}
public FloatBuffer readFloatBuffer(String name, FloatBuffer defVal)
throws IOException {
BinaryClassField field = cObj.nameFields.get(name);
if (field == null || !fieldData.containsKey(field.alias))
return defVal;
return (FloatBuffer) fieldData.get(field.alias);
}
@SuppressWarnings("unchecked")
public ArrayList<FloatBuffer> readFloatBufferArrayList(String name,
ArrayList<FloatBuffer> defVal) throws IOException {
BinaryClassField field = cObj.nameFields.get(name);
if (field == null || !fieldData.containsKey(field.alias))
return defVal;
return (ArrayList<FloatBuffer>) fieldData.get(field.alias);
}
public int readInt(String name, int defVal) throws IOException {
BinaryClassField field = cObj.nameFields.get(name);
if (field == null || !fieldData.containsKey(field.alias))
return defVal;
return ((Integer) fieldData.get(field.alias)).intValue();
}
public int[] readIntArray(String name, int[] defVal) throws IOException {
BinaryClassField field = cObj.nameFields.get(name);
if (field == null || !fieldData.containsKey(field.alias))
return defVal;
return (int[]) fieldData.get(field.alias);
}
public int[][] readIntArray2D(String name, int[][] defVal)
throws IOException {
BinaryClassField field = cObj.nameFields.get(name);
if (field == null || !fieldData.containsKey(field.alias))
return defVal;
return (int[][]) fieldData.get(field.alias);
}
public IntBuffer readIntBuffer(String name, IntBuffer defVal)
throws IOException {
BinaryClassField field = cObj.nameFields.get(name);
if (field == null || !fieldData.containsKey(field.alias))
return defVal;
return (IntBuffer) fieldData.get(field.alias);
}
public long readLong(String name, long defVal) throws IOException {
BinaryClassField field = cObj.nameFields.get(name);
if (field == null || !fieldData.containsKey(field.alias))
return defVal;
return ((Long) fieldData.get(field.alias)).longValue();
}
public long[] readLongArray(String name, long[] defVal) throws IOException {
BinaryClassField field = cObj.nameFields.get(name);
if (field == null || !fieldData.containsKey(field.alias))
return defVal;
return (long[]) fieldData.get(field.alias);
}
public long[][] readLongArray2D(String name, long[][] defVal)
throws IOException {
BinaryClassField field = cObj.nameFields.get(name);
if (field == null || !fieldData.containsKey(field.alias))
return defVal;
return (long[][]) fieldData.get(field.alias);
}
public Savable readSavable(String name, Savable defVal) throws IOException {
BinaryClassField field = cObj.nameFields.get(name);
if (field == null || !fieldData.containsKey(field.alias))
return defVal;
Object value = fieldData.get(field.alias);
if (value == null)
return null;
else if (value instanceof ID) {
value = importer.readObject(((ID) value).id);
fieldData.put(field.alias, value);
return (Savable) value;
} else
return defVal;
}
public Savable[] readSavableArray(String name, Savable[] defVal)
throws IOException {
BinaryClassField field = cObj.nameFields.get(name);
if (field == null || !fieldData.containsKey(field.alias))
return defVal;
Object[] values = (Object[]) fieldData.get(field.alias);
if (values instanceof ID[]) {
values = resolveIDs(values);
fieldData.put(field.alias, values);
return (Savable[]) values;
} else
return defVal;
}
private Savable[] resolveIDs(Object[] values) {
if (values != null) {
Savable[] savables = new Savable[values.length];
for (int i = 0; i < values.length; i++) {
final ID id = (ID) values[i];
savables[i] = id != null ? importer.readObject(id.id) : null;
}
return savables;
} else {
return null;
}
}
public Savable[][] readSavableArray2D(String name, Savable[][] defVal)
throws IOException {
BinaryClassField field = cObj.nameFields.get(name);
if (field == null ||!fieldData.containsKey(field.alias))
return defVal;
Object[][] values = (Object[][]) fieldData.get(field.alias);
if (values instanceof ID[][]) {
Savable[][] savables = new Savable[values.length][];
for (int i = 0; i < values.length; i++) {
if (values[i] != null) {
savables[i] = resolveIDs(values[i]);
} else savables[i] = null;
}
values = savables;
fieldData.put(field.alias, values);
}
return (Savable[][]) values;
}
public Savable[][][] readSavableArray3D(String name, Savable[][][] defVal)
throws IOException {
BinaryClassField field = cObj.nameFields.get(name);
if (field == null || !fieldData.containsKey(field.alias))
return defVal;
Object[][][] values = (Object[][][]) fieldData.get(field.alias);
if (values instanceof ID[][][]) {
Savable[][][] savables = new Savable[values.length][][];
for (int i = 0; i < values.length; i++) {
if (values[i] != null) {
savables[i] = new Savable[values[i].length][];
for (int j = 0; j < values[i].length; j++) {
savables[i][j] = resolveIDs(values[i][j]);
}
} else savables[i] = null;
}
fieldData.put(field.alias, savables);
return savables;
} else
return defVal;
}
private ArrayList<Savable> savableArrayListFromArray(Savable[] savables) {
if(savables == null) {
return null;
}
ArrayList<Savable> arrayList = new ArrayList<Savable>(savables.length);
for (int x = 0; x < savables.length; x++) {
arrayList.add(savables[x]);
}
return arrayList;
}
// Assumes array of size 2 arrays where pos 0 is key and pos 1 is value.
private Map<Savable, Savable> savableMapFrom2DArray(Savable[][] savables) {
if(savables == null) {
return null;
}
Map<Savable, Savable> map = new HashMap<Savable, Savable>(savables.length);
for (int x = 0; x < savables.length; x++) {
map.put(savables[x][0], savables[x][1]);
}
return map;
}
private Map<String, Savable> stringSavableMapFromKV(String[] keys, Savable[] values) {
if(keys == null || values == null) {
return null;
}
Map<String, Savable> map = new HashMap<String, Savable>(keys.length);
for (int x = 0; x < keys.length; x++)
map.put(keys[x], values[x]);
return map;
}
private IntMap<Savable> intSavableMapFromKV(int[] keys, Savable[] values) {
if(keys == null || values == null) {
return null;
}
IntMap<Savable> map = new IntMap<Savable>(keys.length);
for (int x = 0; x < keys.length; x++)
map.put(keys[x], values[x]);
return map;
}
public ArrayList readSavableArrayList(String name, ArrayList defVal)
throws IOException {
BinaryClassField field = cObj.nameFields.get(name);
if (field == null || !fieldData.containsKey(field.alias))
return defVal;
Object value = fieldData.get(field.alias);
if (value instanceof ID[]) {
// read Savable array and convert to ArrayList
Savable[] savables = readSavableArray(name, null);
value = savableArrayListFromArray(savables);
fieldData.put(field.alias, value);
}
return (ArrayList) value;
}
public ArrayList[] readSavableArrayListArray(String name, ArrayList[] defVal)
throws IOException {
BinaryClassField field = cObj.nameFields.get(name);
if (field == null || !fieldData.containsKey(field.alias))
return defVal;
Object value = fieldData.get(field.alias);
if (value instanceof ID[][]) {
// read 2D Savable array and convert to ArrayList array
Savable[][] savables = readSavableArray2D(name, null);
if (savables != null) {
ArrayList[] arrayLists = new ArrayList[savables.length];
for (int i = 0; i < savables.length; i++) {
arrayLists[i] = savableArrayListFromArray(savables[i]);
}
value = arrayLists;
} else
value = defVal;
fieldData.put(field.alias, value);
}
return (ArrayList[]) value;
}
public ArrayList[][] readSavableArrayListArray2D(String name,
ArrayList[][] defVal) throws IOException {
BinaryClassField field = cObj.nameFields.get(name);
if (field == null || !fieldData.containsKey(field.alias))
return defVal;
Object value = fieldData.get(field.alias);
if (value instanceof ID[][][]) {
// read 3D Savable array and convert to 2D ArrayList array
Savable[][][] savables = readSavableArray3D(name, null);
if (savables != null && savables.length > 0) {
ArrayList[][] arrayLists = new ArrayList[savables.length][];
for (int i = 0; i < savables.length; i++) {
arrayLists[i] = new ArrayList[savables[i].length];
for (int j = 0; j < savables[i].length; j++) {
arrayLists[i][j] = savableArrayListFromArray(savables[i][j]);
}
}
value = arrayLists;
} else
value = defVal;
fieldData.put(field.alias, value);
}
return (ArrayList[][]) value;
}
@SuppressWarnings("unchecked")
public Map<? extends Savable, ? extends Savable> readSavableMap(String name, Map<? extends Savable, ? extends Savable> defVal)
throws IOException {
BinaryClassField field = cObj.nameFields.get(name);
if (field == null || !fieldData.containsKey(field.alias))
return defVal;
Object value = fieldData.get(field.alias);
if (value instanceof ID[][]) {
// read Savable array and convert to Map
Savable[][] savables = readSavableArray2D(name, null);
value = savableMapFrom2DArray(savables);
fieldData.put(field.alias, value);
}
return (Map<? extends Savable, ? extends Savable>) value;
}
@SuppressWarnings("unchecked")
public Map<String, ? extends Savable> readStringSavableMap(String name, Map<String, ? extends Savable> defVal)
throws IOException {
BinaryClassField field = cObj.nameFields.get(name);
if (field == null || !fieldData.containsKey(field.alias))
return defVal;
Object value = fieldData.get(field.alias);
if (value instanceof StringIDMap) {
// read Savable array and convert to Map values
StringIDMap in = (StringIDMap) value;
Savable[] values = resolveIDs(in.values);
value = stringSavableMapFromKV(in.keys, values);
fieldData.put(field.alias, value);
}
return (Map<String, Savable>) value;
}
@SuppressWarnings("unchecked")
public IntMap<? extends Savable> readIntSavableMap(String name, IntMap<? extends Savable> defVal)
throws IOException {
BinaryClassField field = cObj.nameFields.get(name);
if (field == null || !fieldData.containsKey(field.alias))
return defVal;
Object value = fieldData.get(field.alias);
if (value instanceof IntIDMap) {
// read Savable array and convert to Map values
IntIDMap in = (IntIDMap) value;
Savable[] values = resolveIDs(in.values);
value = intSavableMapFromKV(in.keys, values);
fieldData.put(field.alias, value);
}
return (IntMap<Savable>) value;
}
public short readShort(String name, short defVal) throws IOException {
BinaryClassField field = cObj.nameFields.get(name);
if (field == null || !fieldData.containsKey(field.alias))
return defVal;
return ((Short) fieldData.get(field.alias)).shortValue();
}
public short[] readShortArray(String name, short[] defVal)
throws IOException {
BinaryClassField field = cObj.nameFields.get(name);
if (field == null || !fieldData.containsKey(field.alias))
return defVal;
return (short[]) fieldData.get(field.alias);
}
public short[][] readShortArray2D(String name, short[][] defVal)
throws IOException {
BinaryClassField field = cObj.nameFields.get(name);
if (field == null || !fieldData.containsKey(field.alias))
return defVal;
return (short[][]) fieldData.get(field.alias);
}
public ShortBuffer readShortBuffer(String name, ShortBuffer defVal)
throws IOException {
BinaryClassField field = cObj.nameFields.get(name);
if (field == null || !fieldData.containsKey(field.alias))
return defVal;
return (ShortBuffer) fieldData.get(field.alias);
}
public String readString(String name, String defVal) throws IOException {
BinaryClassField field = cObj.nameFields.get(name);
if (field == null || !fieldData.containsKey(field.alias))
return defVal;
return (String) fieldData.get(field.alias);
}
public String[] readStringArray(String name, String[] defVal)
throws IOException {
BinaryClassField field = cObj.nameFields.get(name);
if (field == null || !fieldData.containsKey(field.alias))
return defVal;
return (String[]) fieldData.get(field.alias);
}
public String[][] readStringArray2D(String name, String[][] defVal)
throws IOException {
BinaryClassField field = cObj.nameFields.get(name);
if (field == null || !fieldData.containsKey(field.alias))
return defVal;
return (String[][]) fieldData.get(field.alias);
}
// byte primitive
protected byte readByte(byte[] content) throws IOException {
byte value = content[index];
index++;
return value;
}
protected byte readByteForBuffer(byte[] content) throws IOException {
byte value = content[index];
index++;
return value;
}
protected byte[] readByteArray(byte[] content) throws IOException {
int length = readInt(content);
if (length == BinaryOutputCapsule.NULL_OBJECT)
return null;
byte[] value = new byte[length];
for (int x = 0; x < length; x++)
value[x] = readByte(content);
return value;
}
protected byte[][] readByteArray2D(byte[] content) throws IOException {
int length = readInt(content);
if (length == BinaryOutputCapsule.NULL_OBJECT)
return null;
byte[][] value = new byte[length][];
for (int x = 0; x < length; x++)
value[x] = readByteArray(content);
return value;
}
// int primitive
protected int readIntForBuffer(byte[] content){
int number = ((content[index+3] & 0xFF) << 24)
+ ((content[index+2] & 0xFF) << 16)
+ ((content[index+1] & 0xFF) << 8)
+ (content[index] & 0xFF);
index += 4;
return number;
}
protected int readInt(byte[] content) throws IOException {
byte[] bytes = inflateFrom(content, index);
index += 1 + bytes.length;
bytes = ByteUtils.rightAlignBytes(bytes, 4);
int value = ByteUtils.convertIntFromBytes(bytes);
if (value == BinaryOutputCapsule.NULL_OBJECT
|| value == BinaryOutputCapsule.DEFAULT_OBJECT)
index -= 4;
return value;
}
protected int[] readIntArray(byte[] content) throws IOException {
int length = readInt(content);
if (length == BinaryOutputCapsule.NULL_OBJECT)
return null;
int[] value = new int[length];
for (int x = 0; x < length; x++)
value[x] = readInt(content);
return value;
}
protected int[][] readIntArray2D(byte[] content) throws IOException {
int length = readInt(content);
if (length == BinaryOutputCapsule.NULL_OBJECT)
return null;
int[][] value = new int[length][];
for (int x = 0; x < length; x++)
value[x] = readIntArray(content);
return value;
}
// float primitive
protected float readFloat(byte[] content) throws IOException {
float value = ByteUtils.convertFloatFromBytes(content, index);
index += 4;
return value;
}
protected float readFloatForBuffer(byte[] content) throws IOException {
int number = readIntForBuffer(content);
return Float.intBitsToFloat(number);
}
protected float[] readFloatArray(byte[] content) throws IOException {
int length = readInt(content);
if (length == BinaryOutputCapsule.NULL_OBJECT)
return null;
float[] value = new float[length];
for (int x = 0; x < length; x++)
value[x] = readFloat(content);
return value;
}
protected float[][] readFloatArray2D(byte[] content) throws IOException {
int length = readInt(content);
if (length == BinaryOutputCapsule.NULL_OBJECT)
return null;
float[][] value = new float[length][];
for (int x = 0; x < length; x++)
value[x] = readFloatArray(content);
return value;
}
// double primitive
protected double readDouble(byte[] content) throws IOException {
double value = ByteUtils.convertDoubleFromBytes(content, index);
index += 8;
return value;
}
protected double[] readDoubleArray(byte[] content) throws IOException {
int length = readInt(content);
if (length == BinaryOutputCapsule.NULL_OBJECT)
return null;
double[] value = new double[length];
for (int x = 0; x < length; x++)
value[x] = readDouble(content);
return value;
}
protected double[][] readDoubleArray2D(byte[] content) throws IOException {
int length = readInt(content);
if (length == BinaryOutputCapsule.NULL_OBJECT)
return null;
double[][] value = new double[length][];
for (int x = 0; x < length; x++)
value[x] = readDoubleArray(content);
return value;
}
// long primitive
protected long readLong(byte[] content) throws IOException {
byte[] bytes = inflateFrom(content, index);
index += 1 + bytes.length;
bytes = ByteUtils.rightAlignBytes(bytes, 8);
long value = ByteUtils.convertLongFromBytes(bytes);
return value;
}
protected long[] readLongArray(byte[] content) throws IOException {
int length = readInt(content);
if (length == BinaryOutputCapsule.NULL_OBJECT)
return null;
long[] value = new long[length];
for (int x = 0; x < length; x++)
value[x] = readLong(content);
return value;
}
protected long[][] readLongArray2D(byte[] content) throws IOException {
int length = readInt(content);
if (length == BinaryOutputCapsule.NULL_OBJECT)
return null;
long[][] value = new long[length][];
for (int x = 0; x < length; x++)
value[x] = readLongArray(content);
return value;
}
// short primitive
protected short readShort(byte[] content) throws IOException {
short value = ByteUtils.convertShortFromBytes(content, index);
index += 2;
return value;
}
protected short readShortForBuffer(byte[] content) throws IOException {
short number = (short) ((content[index+0] & 0xFF)
+ ((content[index+1] & 0xFF) << 8));
index += 2;
return number;
}
protected short[] readShortArray(byte[] content) throws IOException {
int length = readInt(content);
if (length == BinaryOutputCapsule.NULL_OBJECT)
return null;
short[] value = new short[length];
for (int x = 0; x < length; x++)
value[x] = readShort(content);
return value;
}
protected short[][] readShortArray2D(byte[] content) throws IOException {
int length = readInt(content);
if (length == BinaryOutputCapsule.NULL_OBJECT)
return null;
short[][] value = new short[length][];
for (int x = 0; x < length; x++)
value[x] = readShortArray(content);
return value;
}
// boolean primitive
protected boolean readBoolean(byte[] content) throws IOException {
boolean value = ByteUtils.convertBooleanFromBytes(content, index);
index += 1;
return value;
}
protected boolean[] readBooleanArray(byte[] content) throws IOException {
int length = readInt(content);
if (length == BinaryOutputCapsule.NULL_OBJECT)
return null;
boolean[] value = new boolean[length];
for (int x = 0; x < length; x++)
value[x] = readBoolean(content);
return value;
}
protected boolean[][] readBooleanArray2D(byte[] content) throws IOException {
int length = readInt(content);
if (length == BinaryOutputCapsule.NULL_OBJECT)
return null;
boolean[][] value = new boolean[length][];
for (int x = 0; x < length; x++)
value[x] = readBooleanArray(content);
return value;
}
/*
* UTF-8 crash course:
*
* UTF-8 codepoints map to UTF-16 codepoints and vv, which is what Java uses for it's Strings.
* (so a UTF-8 codepoint can contain all possible values for a Java char)
*
* A UTF-8 codepoint can be 1, 2 or 3 bytes long. How long a codepint is can be told by reading the first byte:
* b < 0x80, 1 byte
* (b & 0xC0) == 0xC0, 2 bytes
* (b & 0xE0) == 0xE0, 3 bytes
*
* However there is an additional restriction to UTF-8, to enable you to find the start of a UTF-8 codepoint,
* if you start reading at a random point in a UTF-8 byte stream. That's why UTF-8 requires for the second and third byte of
* a multibyte codepoint:
* (b & 0x80) == 0x80 (in other words, first bit must be 1)
*/
private final static int UTF8_START = 0; // next byte should be the start of a new
private final static int UTF8_2BYTE = 2; // next byte should be the second byte of a 2 byte codepoint
private final static int UTF8_3BYTE_1 = 3; // next byte should be the second byte of a 3 byte codepoint
private final static int UTF8_3BYTE_2 = 4; // next byte should be the third byte of a 3 byte codepoint
private final static int UTF8_ILLEGAL = 10; // not an UTF8 string
// String
protected String readString(byte[] content) throws IOException {
int length = readInt(content);
if (length == BinaryOutputCapsule.NULL_OBJECT)
return null;
/*
* @see ISSUE 276
*
* We'll transfer the bytes into a seperate byte array.
* While we do that we'll take the opportunity to check if the byte data is valid UTF-8.
*
* If it is not UTF-8 it is most likely saved with the BinaryOutputCapsule bug, that saves Strings using their native
* encoding. Unfortunatly there is no way to know what encoding was used, so we'll parse using the most common one in
* that case; latin-1 aka ISO8859_1
*
* Encoding of "low" ASCII codepoint (in plain speak: when no special characters are used) will usually look the same
* for UTF-8 and the other 1 byte codepoint encodings (espc true for numbers and regular letters of the alphabet). So these
* are valid UTF-8 and will give the same result (at most a few charakters will appear different, such as the euro sign).
*
* However, when "high" codepoints are used (any codepoint that over 0x7F, in other words where the first bit is a 1) it's
* a different matter and UTF-8 and the 1 byte encoding greatly will differ, as well as most 1 byte encodings relative to each
* other.
*
* It is impossible to detect which one-byte encoding is used. Since UTF8 and practically all 1-byte encodings share the most
* used characters (the "none-high" ones) parsing them will give the same result. However, not all byte sequences are legal in
* UTF-8 (see explantion above). If not UTF-8 encoded content is detected we therefor fallback on latin1. We also log a warning.
*
* By this method we detect all use of 1 byte encoding if they:
* - use a "high" codepoint after a "low" codepoint or a sequence of codepoints that is valid as UTF-8 bytes, that starts with 1000
* - use a "low" codepoint after a "high" codepoint
* - use a "low" codepoint after "high" codepoint, after a "high" codepoint that starts with 1110
*
* In practise this means that unless 2 or 3 "high" codepoints are used after each other in proper order, we'll detect the string
* was not originally UTF-8 encoded.
*
*/
byte[] bytes = new byte[length];
int utf8State = UTF8_START;
int b;
for (int x = 0; x < length; x++) {
bytes[x] = content[index++];
b = (int) bytes[x] & 0xFF; // unsign our byte
switch (utf8State) {
case UTF8_START:
if (b < 0x80) {
// good
}
else if ((b & 0xC0) == 0xC0) {
utf8State = UTF8_2BYTE;
}
else if ((b & 0xE0) == 0xE0) {
utf8State = UTF8_3BYTE_1;
}
else {
utf8State = UTF8_ILLEGAL;
}
break;
case UTF8_3BYTE_1:
case UTF8_3BYTE_2:
case UTF8_2BYTE:
if ((b & 0x80) == 0x80)
utf8State = utf8State == UTF8_3BYTE_1 ? UTF8_3BYTE_2 : UTF8_START;
else
utf8State = UTF8_ILLEGAL;
break;
}
}
try {
// even though so far the parsing might have been a legal UTF-8 sequence, only if a codepoint is fully given is it correct UTF-8
if (utf8State == UTF8_START) {
// Java misspells UTF-8 as UTF8 for official use in java.lang
return new String(bytes, "UTF8");
}
else {
logger.log(
Level.WARNING,
"Your export has been saved with an incorrect encoding for it's String fields which means it might not load correctly " +
"due to encoding issues. You should probably re-export your work. See ISSUE 276 in the jME issue tracker."
);
// We use ISO8859_1 to be consistent across platforms. We could default to native encoding, but this would lead to inconsistent
// behaviour across platforms!
// Developers that have previously saved their exports using the old exporter (wich uses native encoding), can temporarly
// remove the ""ISO8859_1" parameter, and change the above if statement to "if (false)".
// They should then import and re-export their models using the same enviroment they were orginally created in.
return new String(bytes, "ISO8859_1");
}
} catch (UnsupportedEncodingException uee) {
// as a last resort fall back to platform native.
// JavaDoc is vague about what happens when a decoding a String that contains un undecodable sequence
// it also doesn't specify which encodings have to be supported (though UTF-8 and ISO8859 have been in the SUN JRE since at least 1.1)
logger.log(
Level.SEVERE,
"Your export has been saved with an incorrect encoding or your version of Java is unable to decode the stored string. " +
"While your export may load correctly by falling back, using it on different platforms or java versions might lead to "+
"very strange inconsitenties. You should probably re-export your work. See ISSUE 276 in the jME issue tracker."
);
return new String(bytes);
}
}
protected String[] readStringArray(byte[] content) throws IOException {
int length = readInt(content);
if (length == BinaryOutputCapsule.NULL_OBJECT)
return null;
String[] value = new String[length];
for (int x = 0; x < length; x++)
value[x] = readString(content);
return value;
}
protected String[][] readStringArray2D(byte[] content) throws IOException {
int length = readInt(content);
if (length == BinaryOutputCapsule.NULL_OBJECT)
return null;
String[][] value = new String[length][];
for (int x = 0; x < length; x++)
value[x] = readStringArray(content);
return value;
}
// BitSet
protected BitSet readBitSet(byte[] content) throws IOException {
int length = readInt(content);
if (length == BinaryOutputCapsule.NULL_OBJECT)
return null;
BitSet value = new BitSet(length);
for (int x = 0; x < length; x++)
value.set(x, readBoolean(content));
return value;
}
// INFLATOR for int and long
protected static byte[] inflateFrom(byte[] contents, int index) {
byte firstByte = contents[index];
if (firstByte == BinaryOutputCapsule.NULL_OBJECT)
return ByteUtils.convertToBytes(BinaryOutputCapsule.NULL_OBJECT);
else if (firstByte == BinaryOutputCapsule.DEFAULT_OBJECT)
return ByteUtils.convertToBytes(BinaryOutputCapsule.DEFAULT_OBJECT);
else if (firstByte == 0)
return new byte[0];
else {
byte[] rVal = new byte[firstByte];
for (int x = 0; x < rVal.length; x++)
rVal[x] = contents[x + 1 + index];
return rVal;
}
}
// BinarySavable
protected ID readSavable(byte[] content) throws IOException {
int id = readInt(content);
if (id == BinaryOutputCapsule.NULL_OBJECT) {
return null;
}
return new ID(id);
}
// BinarySavable array
protected ID[] readSavableArray(byte[] content) throws IOException {
int elements = readInt(content);
if (elements == BinaryOutputCapsule.NULL_OBJECT)
return null;
ID[] rVal = new ID[elements];
for (int x = 0; x < elements; x++) {
rVal[x] = readSavable(content);
}
return rVal;
}
protected ID[][] readSavableArray2D(byte[] content) throws IOException {
int elements = readInt(content);
if (elements == BinaryOutputCapsule.NULL_OBJECT)
return null;
ID[][] rVal = new ID[elements][];
for (int x = 0; x < elements; x++) {
rVal[x] = readSavableArray(content);
}
return rVal;
}
protected ID[][][] readSavableArray3D(byte[] content) throws IOException {
int elements = readInt(content);
if (elements == BinaryOutputCapsule.NULL_OBJECT)
return null;
ID[][][] rVal = new ID[elements][][];
for (int x = 0; x < elements; x++) {
rVal[x] = readSavableArray2D(content);
}
return rVal;
}
// BinarySavable map
protected ID[][] readSavableMap(byte[] content) throws IOException {
int elements = readInt(content);
if (elements == BinaryOutputCapsule.NULL_OBJECT)
return null;
ID[][] rVal = new ID[elements][];
for (int x = 0; x < elements; x++) {
rVal[x] = readSavableArray(content);
}
return rVal;
}
protected StringIDMap readStringSavableMap(byte[] content) throws IOException {
int elements = readInt(content);
if (elements == BinaryOutputCapsule.NULL_OBJECT)
return null;
String[] keys = readStringArray(content);
ID[] values = readSavableArray(content);
StringIDMap rVal = new StringIDMap();
rVal.keys = keys;
rVal.values = values;
return rVal;
}
protected IntIDMap readIntSavableMap(byte[] content) throws IOException {
int elements = readInt(content);
if (elements == BinaryOutputCapsule.NULL_OBJECT)
return null;
int[] keys = readIntArray(content);
ID[] values = readSavableArray(content);
IntIDMap rVal = new IntIDMap();
rVal.keys = keys;
rVal.values = values;
return rVal;
}
// ArrayList<FloatBuffer>
protected ArrayList<FloatBuffer> readFloatBufferArrayList(byte[] content)
throws IOException {
int length = readInt(content);
if (length == BinaryOutputCapsule.NULL_OBJECT) {
return null;
}
ArrayList<FloatBuffer> rVal = new ArrayList<FloatBuffer>(length);
for (int x = 0; x < length; x++) {
rVal.add(readFloatBuffer(content));
}
return rVal;
}
// ArrayList<ByteBuffer>
protected ArrayList<ByteBuffer> readByteBufferArrayList(byte[] content)
throws IOException {
int length = readInt(content);
if (length == BinaryOutputCapsule.NULL_OBJECT) {
return null;
}
ArrayList<ByteBuffer> rVal = new ArrayList<ByteBuffer>(length);
for (int x = 0; x < length; x++) {
rVal.add(readByteBuffer(content));
}
return rVal;
}
// NIO BUFFERS
// float buffer
protected FloatBuffer readFloatBuffer(byte[] content) throws IOException {
int length = readInt(content);
if (length == BinaryOutputCapsule.NULL_OBJECT)
return null;
if (BinaryImporter.canUseFastBuffers()){
ByteBuffer value = BufferUtils.createByteBuffer(length * 4);
value.put(content, index, length * 4).rewind();
index += length * 4;
return value.asFloatBuffer();
}else{
FloatBuffer value = BufferUtils.createFloatBuffer(length);
for (int x = 0; x < length; x++) {
value.put(readFloatForBuffer(content));
}
value.rewind();
return value;
}
}
// int buffer
protected IntBuffer readIntBuffer(byte[] content) throws IOException {
int length = readInt(content);
if (length == BinaryOutputCapsule.NULL_OBJECT)
return null;
if (BinaryImporter.canUseFastBuffers()){
ByteBuffer value = BufferUtils.createByteBuffer(length * 4);
value.put(content, index, length * 4).rewind();
index += length * 4;
return value.asIntBuffer();
}else{
IntBuffer value = BufferUtils.createIntBuffer(length);
for (int x = 0; x < length; x++) {
value.put(readIntForBuffer(content));
}
value.rewind();
return value;
}
}
// byte buffer
protected ByteBuffer readByteBuffer(byte[] content) throws IOException {
int length = readInt(content);
if (length == BinaryOutputCapsule.NULL_OBJECT)
return null;
if (BinaryImporter.canUseFastBuffers()){
ByteBuffer value = BufferUtils.createByteBuffer(length);
value.put(content, index, length).rewind();
index += length;
return value;
}else{
ByteBuffer value = BufferUtils.createByteBuffer(length);
for (int x = 0; x < length; x++) {
value.put(readByteForBuffer(content));
}
value.rewind();
return value;
}
}
// short buffer
protected ShortBuffer readShortBuffer(byte[] content) throws IOException {
int length = readInt(content);
if (length == BinaryOutputCapsule.NULL_OBJECT)
return null;
if (BinaryImporter.canUseFastBuffers()){
ByteBuffer value = BufferUtils.createByteBuffer(length * 2);
value.put(content, index, length * 2).rewind();
index += length * 2;
return value.asShortBuffer();
}else{
ShortBuffer value = BufferUtils.createShortBuffer(length);
for (int x = 0; x < length; x++) {
value.put(readShortForBuffer(content));
}
value.rewind();
return value;
}
}
static private class ID {
public int id;
public ID(int id) {
this.id = id;
}
}
static private class StringIDMap {
public String[] keys;
public ID[] values;
}
static private class IntIDMap {
public int[] keys;
public ID[] values;
}
public <T extends Enum<T>> T readEnum(String name, Class<T> enumType, T defVal) throws IOException {
String eVal = readString(name, defVal != null ? defVal.name() : null);
if (eVal != null) {
return Enum.valueOf(enumType, eVal);
} else {
return null;
}
}
}