king1600/Buffer.java

## Buffer.java
package com.protto.erlpack;

import java.nio.charset.Charset;
import java.util.Arrays;

public class Buffer {
    private byte[] buf;
    private int length;
    private int alloc_size;

    public Buffer(final long size) {
        length = 0;
        alloc_size = (int)size;
        buf = new byte[alloc_size];
    }

    public final int size() {
        return length;
    }

    public byte[] buffer() {
        return buf;
    }

    public void append(final byte[] bytes) {
        append(bytes, 0, bytes.length);
    }

    public void append(final byte[] bytes, final int size) {
        append(bytes, 0, size);
    }

    public void append(final byte[] bytes, final int start, final int size) {
        if (length + size > alloc_size) {
            // Grow buffer 2x to avoid excessive re-allocations.
            alloc_size = (length + size) * 2;
            buf = Arrays.copyOf(buf, alloc_size);
        }
        System.arraycopy(bytes, start, buf, length, size);
        length += size;
    }

    public void appendVersion() {
        append(new byte[]{ Erlpack.FORMAT_VERSION });
    }

    public void appendNull() {
        append(new byte[]{Erlpack.SMALL_ATOM_EXT, 3, 'n', 'i', 'l'});
    }

    public void appendTrue() {
        append(new byte[]{Erlpack.SMALL_ATOM_EXT, 4, 't', 'r', 'u', 'e'});
    }

    public void appendFalse() {
        append(new byte[]{Erlpack.SMALL_ATOM_EXT, 5, 'f', 'a', 'l', 's', 'e'});
    }

    public void appendByte(final byte i) {
        append(new byte[]{Erlpack.SMALL_INTEGER_EXT, i});
    }

    public void appendInt(final int i) {
        append(new byte[]{Erlpack.INTEGER_EXT,
                (byte)((i >> 24) & 0xFF),
                (byte)((i >> 16) & 0xFF),
                (byte)((i >> 8) & 0xFF),
                (byte)(i & 0xFF)
        });
    }

    public void appendLong(final long i) {
        byte[] b = new byte[1 + 2 + Long.BYTES];
        b[0] = Erlpack.SMALL_BIG_EXT;
        b[2] = (byte)(i < 0 ? 1 : 0);
        long ulong = i < 0 ? -i : Erlpack.toULong(i);
        byte bytes_enc = 0;
        while (ulong > 0) {
            b[3 + (bytes_enc++)] = (byte)(ulong & 0xFF);
            ulong >>= 8;
        }
        b[1] = bytes_enc;
        append(b, 1 + 2 + bytes_enc);
    }

    public void appendDouble(double i) {
        byte[] b = new byte[1 + Long.BYTES];
        b[0] = Erlpack.NEW_FLOAT_EXT;
        final long d = Double.doubleToLongBits(i);
        System.arraycopy(Erlpack.toBytes(d, Double.BYTES), 0, b, 1, Double.BYTES);
        append(b);
    }

    public void appendAtom(final String str) {
        final byte[] bytes = str.getBytes(Charset.defaultCharset());
        if (bytes.length < 0xFF - 1)
            append(new byte[]{Erlpack.SMALL_ATOM_EXT, (byte)bytes.length});
        else
            append(new byte[]{Erlpack.ATOM_EXT, (byte)((bytes.length >> 8) & 0xFF), (byte)(bytes.length & 0xFF)});
        append(bytes, 0, bytes.length);
    }

    public void appendBinary(final byte[] bytes, final int size) {
        appendBinary(bytes, 0, size);
    }

    public void appendBinary(final byte[] bytes, final int start, final int size) {
        append(new byte[] {
                Erlpack.BINARY_EXT,
                (byte)((size >> 24) & 0xFF),
                (byte)((size >> 16) & 0xFF),
                (byte)((size >> 8) & 0xFF),
                (byte)(size & 0xFF)
        });
        append(bytes, start, size);
    }

    public void appendString(final String str) {
        appendString(str, Charset.defaultCharset());
    }

    public void appendString(final String str, final Charset charset) {
        final byte[] bytes = str.getBytes(charset);
        append(new byte[]{Erlpack.STRING_EXT, (byte)((bytes.length >> 8) & 0xFF), (byte)(bytes.length & 0xFF)});
        append(bytes);
    }

    public void appendTupleHeader(final long size) {
        if (size < 0xFF)
            append(new byte[]{Erlpack.SMALL_TUPLE_EXT, (byte)size});
        else
            append(new byte[]{Erlpack.LARGE_TUPLE_EXT,
                    (byte)((size >> 24) & 0xFF),
                    (byte)((size >> 16) & 0xFF),
                    (byte)((size >> 8) & 0xFF),
                    (byte)(size & 0xFF)
            });
    }

    public void appendNulExt() {
        append(new byte[]{Erlpack.NIL_EXT});
    }

    public void appendListHeader(final long size) {
        append(new byte[]{Erlpack.LIST_EXT,
                (byte)((size >> 24) & 0xFF),
                (byte)((size >> 16) & 0xFF),
                (byte)((size >> 8) & 0xFF),
                (byte)(size & 0xFF)
        });
    }

    public void appendMapHeader(final long size) {
        append(new byte[]{Erlpack.MAP_EXT,
                (byte)((size >> 24) & 0xFF),
                (byte)((size >> 16) & 0xFF),
                (byte)((size >> 8) & 0xFF),
                (byte)(size & 0xFF)
        });
    }
}

## Decoder.java
package com.protto.erlpack;

import java.util.Map;
import java.util.HashMap;
import java.util.zip.Inflater;
import java.lang.reflect.Field;
import java.nio.charset.Charset;

public class Decoder {

    private int offset;
    private final int size;
    private final byte[] data;

    public Decoder(final byte[] stream) throws Exception {
        this(stream, 0, stream.length, false);
    }

    public Decoder(final byte[] stream, final int length) throws Exception {
        this(stream, 0, length, false);
    }

    public Decoder(final byte[] stream, final int offset, final int length) throws Exception {
        this(stream, offset, length, false);
    }

    public Decoder(final byte[] stream, final int offset, final int length, final boolean skipVersion) throws Exception {
        data = stream;
        size = length;
        this.offset = offset;
        if (!skipVersion)
            if (read8() != Erlpack.FORMAT_VERSION)
                throw new Exception("Bad version number");
    }

    private static void overflow(final int bytesOver) throws Exception {
        throw new Exception("Reading " + bytesOver + " bytes passes the end of the buffer.");
    }

    byte read8() throws Exception {
        if (offset + Byte.BYTES > size)
            overflow(1);
        return data[offset++];
    }

    short read16() throws Exception {
        if (offset + Short.BYTES > size)
            overflow(2);
        short value = (short)Erlpack.fromBytes(data, offset, Short.BYTES);
        offset += Short.BYTES;
        return value;
    }

    int read32() throws Exception {
        if (offset + Integer.BYTES > size)
            overflow(2);
        int value = (int)Erlpack.fromBytes(data, offset, Integer.BYTES);
        offset += Integer.BYTES;
        return value;
    }

    long read64() throws Exception {
        if (offset + Long.BYTES > size)
            overflow(2);
        long value = (long)Erlpack.fromBytes(data, offset, Long.BYTES);
        offset += Long.BYTES;
        return value;
    }

    Byte decodeByte() throws Exception {
        return read8();
    }

    Integer decodeInteger() throws Exception {
        return read32();
    }

    Object[] decodeArray(final int size) throws Exception {
        Object[] array = new Object[size];
        for (int i = 0; i < size; i++)
            array[i] = unpack();
        return array;
    }

    Object[] decodeList() throws Exception {
        final int length = read32();
        Object[] array = decodeArray(length);
        final byte tailMarker = read8();
        if (tailMarker != Erlpack.NIL_EXT)
            throw new Exception("List doesn't end with a tail marker, but it must!");
        return array;
    }

    Object[] decodeTuple(final int length) throws Exception {
        return decodeArray(length);
    }

    Object[] decodeNil() throws Exception {
        return new Object[]{};
    }

    Map<String, Object> decodeMap() throws Exception {
        final int length = read32();
        Map<String, Object> map = new HashMap<>();
        for (int i = 0; i < length; i++)
            map.put(unpack().toString(), unpack());
        return map;
    }

    String readString(final int length) throws Exception {
        if (offset + length > size)
            throw new Exception("Reading sequence past the end of the buffer");
        String result = new String(data, offset, length);
        offset += length;
        return result;
    }

    Object processAtom(final String atom, final int length) throws Exception {
        if (atom == null)
            return null;

        if (length >= 3 && length <= 5) {
            if (length == 3 && atom.equals("nil"))
                return null;
            else if (length == 4 && atom.equals("null"))
                return null;
            else if (length == 4 && atom.equals("true"))
                return true;
            else if (length == 5 && atom.equals("false"))
                return false;
        }

        return atom;
    }

    Object decodeAtom() throws Exception {
        final int length = read16();
        final String atom = readString(length);
        return processAtom(atom, length);
    }

    Object decodeSmallAtom() throws Exception {
        final int length = read8();
        final String atom = readString(length);
        return processAtom(atom, length);
    }

    Float decodeFloat() throws Exception {
        final int FLOAT_LENGTH = 31;
        final String floatStr = readString(FLOAT_LENGTH);
        if (floatStr == null)
            return null;

        return Float.parseFloat(floatStr);
    }

    Double decodeNewFloat() throws Exception {
        return Double.longBitsToDouble(read64());
    }

    long decodeBig(int bytes) throws Exception {
        final byte sign = read8();
        if (bytes > 8)
            throw new Exception("Unable to decode big ints larger than 8 bytes");

        long value = 0;
        for (int i = 0; i < bytes; i++) {
            value <<= 8;
            value |= (data[offset + (bytes - i - 1)] & 0xFF);
        }
        offset += bytes;

        if (bytes <= 4) {
            if (sign == 0)
                return value;
            final boolean signBitsAvailable = (value & (1 << 31)) == 0;
            if (signBitsAvailable)
                return -value;
        }

        return value;
    }

    Long decodeSmallBig() throws Exception {
        return decodeBig(read8());
    }

    Long decodeLargeBig() throws Exception {
        return decodeBig(read32());
    }

    byte[] decodeBinaryAsString() throws Exception {
        final int length = read32();
        if (offset + length > size)
            throw new Exception("Reading sequence past the end of the buffer");

        byte[] value = new byte[length];
        System.arraycopy(data, offset, value, 0, length);
        offset += length;
        return value;
    }

    String decodeStringAsList() throws Exception {
        final int length = read16();
        if (offset + length > size)
            throw new Exception("Reading sequence past the end of the buffer.");
        byte[] array = new byte[length];
        for (int i = 0; i < length; i++)
            array[i] = decodeByte();
        return new String(array, Charset.defaultCharset());
    }

    Object[] decodeSmallTuple() throws Exception {
        return decodeTuple(read8());
    }

    Object[] decodeLargeTuple() throws Exception {
        return decodeTuple(read32());
    }

    Object decodeCompressed() throws Exception {
        final int uncompressedSize = read32();
        byte[] output = new byte[uncompressedSize];

        Inflater decompresser = new Inflater();
        decompresser.setInput(data, offset, size - offset);
        final int sourceSize = decompresser.inflate(output);
        decompresser.end();

        Decoder children = new Decoder(output, uncompressedSize);
        return children.unpack();
    }

    Map<String, Object> decodeReference() throws Exception {
        Map<String, Object> ref = new HashMap<>();
        ref.put("node", unpack());
        ref.put("id", new int[] { read32() });
        ref.put("creation", read8());
        return ref;
    }

    Map<String, Object> decodeNewReference() throws Exception {
        Map<String, Object> ref = new HashMap<>();

        final int len = read16();
        ref.put("node", unpack());
        ref.put("creation", read8());

        int[] ids = new int[len];
        for (int i = 0; i < len; i++)
            ids[i] = read32();
        ref.put("id", ids);

        return ref;
    }

    Map<String, Object> decodePort() throws Exception {
        Map<String, Object> port = new HashMap<>();
        port.put("node", unpack());
        port.put("id", read32());
        port.put("creation", read8());
        return port;
    }

    Map<String, Object> decodePID() throws Exception {
        Map<String, Object> pid = new HashMap<>();
        pid.put("node", unpack());
        pid.put("id", read32());
        pid.put("serial", read32());
        pid.put("creation", read8());
        return pid;
    }

    Map<String, Object> decodeExport() throws Exception {
        Map<String, Object> export = new HashMap<>();
        export.put("mod", unpack());
        export.put("fun", unpack());
        export.put("arity", unpack());
        return export;
    }

    public Object unpack() throws Exception {
        if (offset >= size)
            throw new Exception("Unpacking beyond the end of the buffer");

        final byte type = read8();
        switch (type) {
            case Erlpack.SMALL_INTEGER_EXT:
                return decodeByte();
            case Erlpack.INTEGER_EXT:
                return decodeInteger();
            case Erlpack.FLOAT_EXT:
                return decodeFloat();
            case Erlpack.NEW_FLOAT_EXT:
                return decodeNewFloat();
            case Erlpack.ATOM_EXT:
                return decodeAtom();
            case Erlpack.SMALL_ATOM_EXT:
                return decodeSmallAtom();
            case Erlpack.SMALL_TUPLE_EXT:
                return decodeSmallTuple();
            case Erlpack.LARGE_TUPLE_EXT:
                return decodeLargeTuple();
            case Erlpack.NIL_EXT:
                return decodeNil();
            case Erlpack.STRING_EXT:
                return decodeStringAsList();
            case Erlpack.LIST_EXT:
                return decodeList();
            case Erlpack.MAP_EXT:
                return decodeMap();
            case Erlpack.BINARY_EXT:
                return decodeBinaryAsString();
            case Erlpack.SMALL_BIG_EXT:
                return decodeSmallBig();
            case Erlpack.LARGE_BIG_EXT:
                return decodeLargeBig();
            case Erlpack.REFERENCE_EXT:
                return decodeReference();
            case Erlpack.NEW_REFERENCE_EXT:
                return decodeNewReference();
            case Erlpack.PORT_EXT:
                return decodePort();
            case Erlpack.PID_EXT:
                return decodePID();
            case Erlpack.EXPORT_EXT:
                return decodeExport();
            case Erlpack.COMPRESSED:
                return decodeCompressed();
            default:
                throw new Exception("Unsupported erlang term type identifier found");
        }
    }

    public static<T> T toObject(final Map<String, Object> map, T instance) throws Exception {
        for (Map.Entry<String, Object> entry : map.entrySet())
            setAttribute(instance, entry.getKey(), entry.getValue());
        return instance;
    }

    public static<T> void setAttribute(final T instance, final String key, final Object value) throws Exception {
        Field field;
        Class<?> klass = instance.getClass();
        while (klass != null) {
            try {
                field = klass.getDeclaredField(key);
                field.setAccessible(true);
                if (value instanceof Map)
                    field.set(instance, toObject((Map)value, field.get(instance)));
                else
                    field.set(instance, value);
                return;
            } catch (NoSuchFieldException ex) {
                klass = klass.getSuperclass();
            } catch (Exception ex) {
                throw new IllegalStateException(ex);
            }
        }
    }
}

## Encoder.java
package com.protto.erlpack;

import java.util.Map;
import java.util.List;
import java.util.Arrays;
import java.util.ArrayList;
import java.lang.reflect.Field;

public class Encoder {

    private static final long DEFAULT_RECURSE_LIMIT = 0xFF;
    private static final long INITIAL_BUFFER_SIZE = 1024 * 1024;

    private Buffer buf;

    public Encoder() {
        buf = new Buffer(INITIAL_BUFFER_SIZE);
        buf.appendVersion();
    }

    public byte[] compile() {
        byte[] output = Arrays.copyOf(buf.buffer(), buf.size());
        buf = null;
        return output;
    }

    public <T> Encoder pack(final T value) throws Exception {
        return pack(value, DEFAULT_RECURSE_LIMIT);
    }

    public <T> Encoder pack(final T value, final long nestLimit) throws Exception {
        if (nestLimit < 0)
            throw new Exception("Reached recursion limit");

        if (value == null) {
            buf.appendNull();

        } else if (value instanceof Long) {
            buf.appendLong((Long)value);

        } else if (value instanceof Integer || value instanceof Byte) {
            int num = (Integer)value;
            if (num >= 0 && num <= 255)
                buf.appendByte((byte)(num & 0xFF));
            else
                buf.appendInt(num);

        } else if (value instanceof Double) {
            buf.appendDouble((Double)value);

        } else if (value instanceof Boolean) {
            if ((Boolean)value)
                buf.appendTrue();
            else
                buf.appendFalse();


        } else if (value instanceof String) {
            buf.appendString((String) value);

        } else if (value instanceof byte[]) {
            byte[] data = (byte[])value;
            buf.appendBinary(data, data.length);

        } else if (value.getClass().isArray()) {
            final T[] items = (T[]) value;
            final int length = items.length;
            if (length == 0) {
                buf.appendNulExt();
            } else {
                if (length > Integer.MAX_VALUE - 1)
                    throw new Exception("List is too large");
                buf.appendListHeader(length);
                for (int i = 0; i < length; i++)
                    pack(items[i], nestLimit - 1);
                buf.appendNulExt();
            }

        } else if (value instanceof Map) {
            Map<?, ?> map = (Map)value;
            long length = map.entrySet().size();
            if (length > Integer.MAX_VALUE - 1)
                throw new Exception("Object has too many properties");

            buf.appendMapHeader(length);
            for (Map.Entry<?, ?> property : map.entrySet()) {
                pack(property.getKey(), nestLimit - 1);
                pack(property.getValue(), nestLimit - 1);
            }

        } else {
            final Field[] properties = getAttributes(value);
            final int length = properties.length;
            if (length > Integer.MAX_VALUE - 1)
                throw new Exception("Object has too many properties");

            buf.appendMapHeader(length);
            for (int i = 0; i < length; i++) {
                properties[i].setAccessible(true);
                pack(properties[i].getName(), nestLimit - 1); // key
                pack(properties[i].get(value), nestLimit - 1); // value
            }
        }

        return this;
    }

    private static <T> Field[] getAttributes(final T instance) {
        final List<Field> attributes = new ArrayList<>();
        getAttrs(attributes, instance.getClass());
        return attributes.toArray(new Field[]{});
    }

    private static <T> void getAttrs(final List<Field> fields, final Class<?> klass) {
        if (klass == null)
            return;
        for (Field field : klass.getDeclaredFields())
            fields.add(field);
        getAttrs(fields, klass.getSuperclass());
    }
}

## Erlpack.java
package com.protto.erlpack;

import java.math.BigInteger;

public abstract class Erlpack {

    private static final BigInteger u64 = BigInteger.ONE.shiftLeft(64);

    protected static long toULong(final long l) {
        BigInteger b = BigInteger.valueOf(l);
        if (b.signum() < 0)
            b = b.add(u64);
        return b.longValue();
    }

    protected static byte[] toBytes(long l, final int bytes) {
        byte[] b = new byte[bytes];
        for (int i = bytes - 1; i >= 0; i--) {
            b[i] = (byte)(l & 0xFF);
            l >>= 8;
        }
        return b;
    }

    protected static long fromBytes(final byte[] data, int offset, final int bytes) {
        long b = 0;
        for (int i = 0; i < bytes; i++) {
            b <<= 8;
            b |= (data[offset + i] & 0xFF);
        }
        return b;
    }

    protected static final byte
        FORMAT_VERSION = (byte)131,
        NEW_FLOAT_EXT = 'F',       // 70  [Float64:IEEE float]
        BIT_BINARY_EXT = 'M',      // 77  [UInt32:Len, UInt8:Bits, Len:Data]
        SMALL_INTEGER_EXT = 'a',   // 97  [UInt8:Int]
        INTEGER_EXT = 'b',         // 98  [Int32:Int]
        FLOAT_EXT = 'c',           // 99  [31:Float String] Float in string format (formatted "%.20e", sscanf "%lf"). Superseded by NEW_FLOAT_EXT
        ATOM_EXT = 'd',            // 100 [UInt16:Len, Len:AtomName] max Len is 255
        REFERENCE_EXT = 'e',       // 101 [atom:Node, UInt32:ID, UInt8:Creation]
        PORT_EXT = 'f',            // 102 [atom:Node, UInt32:ID, UInt8:Creation]
        PID_EXT = 'g',             // 103 [atom:Node, UInt32:ID, UInt32:Serial, UInt8:Creation]
        SMALL_TUPLE_EXT = 'h',     // 104 [UInt8:Arity, N:Elements]
        LARGE_TUPLE_EXT = 'i',     // 105 [UInt32:Arity, N:Elements]
        NIL_EXT = 'j',             // 106 empty list
        STRING_EXT = 'k',          // 107 [UInt16:Len, Len:Characters]
        LIST_EXT = 'l',            // 108 [UInt32:Len, Elements, Tail]
        BINARY_EXT = 'm',          // 109 [UInt32:Len, Len:Data]
        SMALL_BIG_EXT = 'n',       // 110 [UInt8:n, UInt8:Sign, n:nums]
        LARGE_BIG_EXT = 'o',       // 111 [UInt32:n, UInt8:Sign, n:nums]
        NEW_FUN_EXT = 'p',         // 112 [UInt32:Size, UInt8:Arity, 16*Uint6-MD5:Uniq, UInt32:Index, UInt32:NumFree, atom:Module, int:OldIndex, int:OldUniq, pid:Pid, NunFree*ext:FreeVars]
        EXPORT_EXT = 'q',          // 113 [atom:Module, atom:Function, smallint:Arity]
        NEW_REFERENCE_EXT = 'r',   // 114 [UInt16:Len, atom:Node, UInt8:Creation, Len*UInt32:ID]
        SMALL_ATOM_EXT = 's',      // 115 [UInt8:Len, Len:AtomName]
        MAP_EXT = 't',             // 116 [UInt32:Airty, N:Pairs]
        FUN_EXT = 'u',             // 117 [UInt4:NumFree, pid:Pid, atom:Module, int:Index, int:Uniq, NumFree*ext:FreeVars]
        COMPRESSED = 'P';          // 80  [UInt4:UncompressedSize, N:ZlibCompressedData]

    public static<T> byte[] pack(final T value) throws Exception {
        return new Encoder().pack(value).compile();
    }

    public static<T> T unpack(final byte[] stream) throws Exception {
        return unpack(stream, 0, stream.length);
    }

    public static<T> T unpack(final byte[] stream, final int length) throws Exception {
        return unpack(stream, 0, length);
    }

    public static<T> T unpack(final byte[] stream, final int offset, final int length) throws Exception {
        return (T)(new Decoder(stream, offset, length, false).unpack());
    }
}
	package com.protto.erlpack;

	import java.nio.charset.Charset;
	import java.util.Arrays;

	public class Buffer {
	private byte[] buf;
	private int length;
	private int alloc_size;

	public Buffer(final long size) {
	length = 0;
	alloc_size = (int)size;
	buf = new byte[alloc_size];
	}

	public final int size() {
	return length;
	}

	public byte[] buffer() {
	return buf;
	}

	public void append(final byte[] bytes) {
	append(bytes, 0, bytes.length);
	}

	public void append(final byte[] bytes, final int size) {
	append(bytes, 0, size);
	}

	public void append(final byte[] bytes, final int start, final int size) {
	if (length + size > alloc_size) {
	// Grow buffer 2x to avoid excessive re-allocations.
	alloc_size = (length + size) * 2;
	buf = Arrays.copyOf(buf, alloc_size);
	}
	System.arraycopy(bytes, start, buf, length, size);
	length += size;
	}

	public void appendVersion() {
	append(new byte[]{ Erlpack.FORMAT_VERSION });
	}

	public void appendNull() {
	append(new byte[]{Erlpack.SMALL_ATOM_EXT, 3, 'n', 'i', 'l'});
	}

	public void appendTrue() {
	append(new byte[]{Erlpack.SMALL_ATOM_EXT, 4, 't', 'r', 'u', 'e'});
	}

	public void appendFalse() {
	append(new byte[]{Erlpack.SMALL_ATOM_EXT, 5, 'f', 'a', 'l', 's', 'e'});
	}

	public void appendByte(final byte i) {
	append(new byte[]{Erlpack.SMALL_INTEGER_EXT, i});
	}

	public void appendInt(final int i) {
	append(new byte[]{Erlpack.INTEGER_EXT,
	(byte)((i >> 24) & 0xFF),
	(byte)((i >> 16) & 0xFF),
	(byte)((i >> 8) & 0xFF),
	(byte)(i & 0xFF)
	});
	}

	public void appendLong(final long i) {
	byte[] b = new byte[1 + 2 + Long.BYTES];
	b[0] = Erlpack.SMALL_BIG_EXT;
	b[2] = (byte)(i < 0 ? 1 : 0);
	long ulong = i < 0 ? -i : Erlpack.toULong(i);
	byte bytes_enc = 0;
	while (ulong > 0) {
	b[3 + (bytes_enc++)] = (byte)(ulong & 0xFF);
	ulong >>= 8;
	}
	b[1] = bytes_enc;
	append(b, 1 + 2 + bytes_enc);
	}

	public void appendDouble(double i) {
	byte[] b = new byte[1 + Long.BYTES];
	b[0] = Erlpack.NEW_FLOAT_EXT;
	final long d = Double.doubleToLongBits(i);
	System.arraycopy(Erlpack.toBytes(d, Double.BYTES), 0, b, 1, Double.BYTES);
	append(b);
	}

	public void appendAtom(final String str) {
	final byte[] bytes = str.getBytes(Charset.defaultCharset());
	if (bytes.length < 0xFF - 1)
	append(new byte[]{Erlpack.SMALL_ATOM_EXT, (byte)bytes.length});
	else
	append(new byte[]{Erlpack.ATOM_EXT, (byte)((bytes.length >> 8) & 0xFF), (byte)(bytes.length & 0xFF)});
	append(bytes, 0, bytes.length);
	}

	public void appendBinary(final byte[] bytes, final int size) {
	appendBinary(bytes, 0, size);
	}

	public void appendBinary(final byte[] bytes, final int start, final int size) {
	append(new byte[] {
	Erlpack.BINARY_EXT,
	(byte)((size >> 24) & 0xFF),
	(byte)((size >> 16) & 0xFF),
	(byte)((size >> 8) & 0xFF),
	(byte)(size & 0xFF)
	});
	append(bytes, start, size);
	}

	public void appendString(final String str) {
	appendString(str, Charset.defaultCharset());
	}

	public void appendString(final String str, final Charset charset) {
	final byte[] bytes = str.getBytes(charset);
	append(new byte[]{Erlpack.STRING_EXT, (byte)((bytes.length >> 8) & 0xFF), (byte)(bytes.length & 0xFF)});
	append(bytes);
	}

	public void appendTupleHeader(final long size) {
	if (size < 0xFF)
	append(new byte[]{Erlpack.SMALL_TUPLE_EXT, (byte)size});
	else
	append(new byte[]{Erlpack.LARGE_TUPLE_EXT,
	(byte)((size >> 24) & 0xFF),
	(byte)((size >> 16) & 0xFF),
	(byte)((size >> 8) & 0xFF),
	(byte)(size & 0xFF)
	});
	}

	public void appendNulExt() {
	append(new byte[]{Erlpack.NIL_EXT});
	}

	public void appendListHeader(final long size) {
	append(new byte[]{Erlpack.LIST_EXT,
	(byte)((size >> 24) & 0xFF),
	(byte)((size >> 16) & 0xFF),
	(byte)((size >> 8) & 0xFF),
	(byte)(size & 0xFF)
	});
	}

	public void appendMapHeader(final long size) {
	append(new byte[]{Erlpack.MAP_EXT,
	(byte)((size >> 24) & 0xFF),
	(byte)((size >> 16) & 0xFF),
	(byte)((size >> 8) & 0xFF),
	(byte)(size & 0xFF)
	});
	}
	}
	package com.protto.erlpack;

	import java.util.Map;
	import java.util.HashMap;
	import java.util.zip.Inflater;
	import java.lang.reflect.Field;
	import java.nio.charset.Charset;

	public class Decoder {

	private int offset;
	private final int size;
	private final byte[] data;

	public Decoder(final byte[] stream) throws Exception {
	this(stream, 0, stream.length, false);
	}

	public Decoder(final byte[] stream, final int length) throws Exception {
	this(stream, 0, length, false);
	}

	public Decoder(final byte[] stream, final int offset, final int length) throws Exception {
	this(stream, offset, length, false);
	}

	public Decoder(final byte[] stream, final int offset, final int length, final boolean skipVersion) throws Exception {
	data = stream;
	size = length;
	this.offset = offset;
	if (!skipVersion)
	if (read8() != Erlpack.FORMAT_VERSION)
	throw new Exception("Bad version number");
	}

	private static void overflow(final int bytesOver) throws Exception {
	throw new Exception("Reading " + bytesOver + " bytes passes the end of the buffer.");
	}

	byte read8() throws Exception {
	if (offset + Byte.BYTES > size)
	overflow(1);
	return data[offset++];
	}

	short read16() throws Exception {
	if (offset + Short.BYTES > size)
	overflow(2);
	short value = (short)Erlpack.fromBytes(data, offset, Short.BYTES);
	offset += Short.BYTES;
	return value;
	}

	int read32() throws Exception {
	if (offset + Integer.BYTES > size)
	overflow(2);
	int value = (int)Erlpack.fromBytes(data, offset, Integer.BYTES);
	offset += Integer.BYTES;
	return value;
	}

	long read64() throws Exception {
	if (offset + Long.BYTES > size)
	overflow(2);
	long value = (long)Erlpack.fromBytes(data, offset, Long.BYTES);
	offset += Long.BYTES;
	return value;
	}

	Byte decodeByte() throws Exception {
	return read8();
	}

	Integer decodeInteger() throws Exception {
	return read32();
	}

	Object[] decodeArray(final int size) throws Exception {
	Object[] array = new Object[size];
	for (int i = 0; i < size; i++)
	array[i] = unpack();
	return array;
	}

	Object[] decodeList() throws Exception {
	final int length = read32();
	Object[] array = decodeArray(length);
	final byte tailMarker = read8();
	if (tailMarker != Erlpack.NIL_EXT)
	throw new Exception("List doesn't end with a tail marker, but it must!");
	return array;
	}

	Object[] decodeTuple(final int length) throws Exception {
	return decodeArray(length);
	}

	Object[] decodeNil() throws Exception {
	return new Object[]{};
	}

	Map<String, Object> decodeMap() throws Exception {
	final int length = read32();
	Map<String, Object> map = new HashMap<>();
	for (int i = 0; i < length; i++)
	map.put(unpack().toString(), unpack());
	return map;
	}

	String readString(final int length) throws Exception {
	if (offset + length > size)
	throw new Exception("Reading sequence past the end of the buffer");
	String result = new String(data, offset, length);
	offset += length;
	return result;
	}

	Object processAtom(final String atom, final int length) throws Exception {
	if (atom == null)
	return null;

	if (length >= 3 && length <= 5) {
	if (length == 3 && atom.equals("nil"))
	return null;
	else if (length == 4 && atom.equals("null"))
	return null;
	else if (length == 4 && atom.equals("true"))
	return true;
	else if (length == 5 && atom.equals("false"))
	return false;
	}

	return atom;
	}

	Object decodeAtom() throws Exception {
	final int length = read16();
	final String atom = readString(length);
	return processAtom(atom, length);
	}

	Object decodeSmallAtom() throws Exception {
	final int length = read8();
	final String atom = readString(length);
	return processAtom(atom, length);
	}

	Float decodeFloat() throws Exception {
	final int FLOAT_LENGTH = 31;
	final String floatStr = readString(FLOAT_LENGTH);
	if (floatStr == null)
	return null;

	return Float.parseFloat(floatStr);
	}

	Double decodeNewFloat() throws Exception {
	return Double.longBitsToDouble(read64());
	}

	long decodeBig(int bytes) throws Exception {
	final byte sign = read8();
	if (bytes > 8)
	throw new Exception("Unable to decode big ints larger than 8 bytes");

	long value = 0;
	for (int i = 0; i < bytes; i++) {
	value <<= 8;
	value \|= (data[offset + (bytes - i - 1)] & 0xFF);
	}
	offset += bytes;

	if (bytes <= 4) {
	if (sign == 0)
	return value;
	final boolean signBitsAvailable = (value & (1 << 31)) == 0;
	if (signBitsAvailable)
	return -value;
	}

	return value;
	}

	Long decodeSmallBig() throws Exception {
	return decodeBig(read8());
	}

	Long decodeLargeBig() throws Exception {
	return decodeBig(read32());
	}

	byte[] decodeBinaryAsString() throws Exception {
	final int length = read32();
	if (offset + length > size)
	throw new Exception("Reading sequence past the end of the buffer");

	byte[] value = new byte[length];
	System.arraycopy(data, offset, value, 0, length);
	offset += length;
	return value;
	}

	String decodeStringAsList() throws Exception {
	final int length = read16();
	if (offset + length > size)
	throw new Exception("Reading sequence past the end of the buffer.");
	byte[] array = new byte[length];
	for (int i = 0; i < length; i++)
	array[i] = decodeByte();
	return new String(array, Charset.defaultCharset());
	}

	Object[] decodeSmallTuple() throws Exception {
	return decodeTuple(read8());
	}

	Object[] decodeLargeTuple() throws Exception {
	return decodeTuple(read32());
	}

	Object decodeCompressed() throws Exception {
	final int uncompressedSize = read32();
	byte[] output = new byte[uncompressedSize];

	Inflater decompresser = new Inflater();
	decompresser.setInput(data, offset, size - offset);
	final int sourceSize = decompresser.inflate(output);
	decompresser.end();

	Decoder children = new Decoder(output, uncompressedSize);
	return children.unpack();
	}

	Map<String, Object> decodeReference() throws Exception {
	Map<String, Object> ref = new HashMap<>();
	ref.put("node", unpack());
	ref.put("id", new int[] { read32() });
	ref.put("creation", read8());
	return ref;
	}

	Map<String, Object> decodeNewReference() throws Exception {
	Map<String, Object> ref = new HashMap<>();

	final int len = read16();
	ref.put("node", unpack());
	ref.put("creation", read8());

	int[] ids = new int[len];
	for (int i = 0; i < len; i++)
	ids[i] = read32();
	ref.put("id", ids);

	return ref;
	}

	Map<String, Object> decodePort() throws Exception {
	Map<String, Object> port = new HashMap<>();
	port.put("node", unpack());
	port.put("id", read32());
	port.put("creation", read8());
	return port;
	}

	Map<String, Object> decodePID() throws Exception {
	Map<String, Object> pid = new HashMap<>();
	pid.put("node", unpack());
	pid.put("id", read32());
	pid.put("serial", read32());
	pid.put("creation", read8());
	return pid;
	}

	Map<String, Object> decodeExport() throws Exception {
	Map<String, Object> export = new HashMap<>();
	export.put("mod", unpack());
	export.put("fun", unpack());
	export.put("arity", unpack());
	return export;
	}

	public Object unpack() throws Exception {
	if (offset >= size)
	throw new Exception("Unpacking beyond the end of the buffer");

	final byte type = read8();
	switch (type) {
	case Erlpack.SMALL_INTEGER_EXT:
	return decodeByte();
	case Erlpack.INTEGER_EXT:
	return decodeInteger();
	case Erlpack.FLOAT_EXT:
	return decodeFloat();
	case Erlpack.NEW_FLOAT_EXT:
	return decodeNewFloat();
	case Erlpack.ATOM_EXT:
	return decodeAtom();
	case Erlpack.SMALL_ATOM_EXT:
	return decodeSmallAtom();
	case Erlpack.SMALL_TUPLE_EXT:
	return decodeSmallTuple();
	case Erlpack.LARGE_TUPLE_EXT:
	return decodeLargeTuple();
	case Erlpack.NIL_EXT:
	return decodeNil();
	case Erlpack.STRING_EXT:
	return decodeStringAsList();
	case Erlpack.LIST_EXT:
	return decodeList();
	case Erlpack.MAP_EXT:
	return decodeMap();
	case Erlpack.BINARY_EXT:
	return decodeBinaryAsString();
	case Erlpack.SMALL_BIG_EXT:
	return decodeSmallBig();
	case Erlpack.LARGE_BIG_EXT:
	return decodeLargeBig();
	case Erlpack.REFERENCE_EXT:
	return decodeReference();
	case Erlpack.NEW_REFERENCE_EXT:
	return decodeNewReference();
	case Erlpack.PORT_EXT:
	return decodePort();
	case Erlpack.PID_EXT:
	return decodePID();
	case Erlpack.EXPORT_EXT:
	return decodeExport();
	case Erlpack.COMPRESSED:
	return decodeCompressed();
	default:
	throw new Exception("Unsupported erlang term type identifier found");
	}
	}

	public static<T> T toObject(final Map<String, Object> map, T instance) throws Exception {
	for (Map.Entry<String, Object> entry : map.entrySet())
	setAttribute(instance, entry.getKey(), entry.getValue());
	return instance;
	}

	public static<T> void setAttribute(final T instance, final String key, final Object value) throws Exception {
	Field field;
	Class<?> klass = instance.getClass();
	while (klass != null) {
	try {
	field = klass.getDeclaredField(key);
	field.setAccessible(true);
	if (value instanceof Map)
	field.set(instance, toObject((Map)value, field.get(instance)));
	else
	field.set(instance, value);
	return;
	} catch (NoSuchFieldException ex) {
	klass = klass.getSuperclass();
	} catch (Exception ex) {
	throw new IllegalStateException(ex);
	}
	}
	}
	}
	package com.protto.erlpack;

	import java.util.Map;
	import java.util.List;
	import java.util.Arrays;
	import java.util.ArrayList;
	import java.lang.reflect.Field;

	public class Encoder {

	private static final long DEFAULT_RECURSE_LIMIT = 0xFF;
	private static final long INITIAL_BUFFER_SIZE = 1024 * 1024;

	private Buffer buf;

	public Encoder() {
	buf = new Buffer(INITIAL_BUFFER_SIZE);
	buf.appendVersion();
	}

	public byte[] compile() {
	byte[] output = Arrays.copyOf(buf.buffer(), buf.size());
	buf = null;
	return output;
	}

	public <T> Encoder pack(final T value) throws Exception {
	return pack(value, DEFAULT_RECURSE_LIMIT);
	}

	public <T> Encoder pack(final T value, final long nestLimit) throws Exception {
	if (nestLimit < 0)
	throw new Exception("Reached recursion limit");

	if (value == null) {
	buf.appendNull();

	} else if (value instanceof Long) {
	buf.appendLong((Long)value);

	} else if (value instanceof Integer \|\| value instanceof Byte) {
	int num = (Integer)value;
	if (num >= 0 && num <= 255)
	buf.appendByte((byte)(num & 0xFF));
	else
	buf.appendInt(num);

	} else if (value instanceof Double) {
	buf.appendDouble((Double)value);

	} else if (value instanceof Boolean) {
	if ((Boolean)value)
	buf.appendTrue();
	else
	buf.appendFalse();


	} else if (value instanceof String) {
	buf.appendString((String) value);

	} else if (value instanceof byte[]) {
	byte[] data = (byte[])value;
	buf.appendBinary(data, data.length);

	} else if (value.getClass().isArray()) {
	final T[] items = (T[]) value;
	final int length = items.length;
	if (length == 0) {
	buf.appendNulExt();
	} else {
	if (length > Integer.MAX_VALUE - 1)
	throw new Exception("List is too large");
	buf.appendListHeader(length);
	for (int i = 0; i < length; i++)
	pack(items[i], nestLimit - 1);
	buf.appendNulExt();
	}

	} else if (value instanceof Map) {
	Map<?, ?> map = (Map)value;
	long length = map.entrySet().size();
	if (length > Integer.MAX_VALUE - 1)
	throw new Exception("Object has too many properties");

	buf.appendMapHeader(length);
	for (Map.Entry<?, ?> property : map.entrySet()) {
	pack(property.getKey(), nestLimit - 1);
	pack(property.getValue(), nestLimit - 1);
	}

	} else {
	final Field[] properties = getAttributes(value);
	final int length = properties.length;
	if (length > Integer.MAX_VALUE - 1)
	throw new Exception("Object has too many properties");

	buf.appendMapHeader(length);
	for (int i = 0; i < length; i++) {
	properties[i].setAccessible(true);
	pack(properties[i].getName(), nestLimit - 1); // key
	pack(properties[i].get(value), nestLimit - 1); // value
	}
	}

	return this;
	}

	private static <T> Field[] getAttributes(final T instance) {
	final List<Field> attributes = new ArrayList<>();
	getAttrs(attributes, instance.getClass());
	return attributes.toArray(new Field[]{});
	}

	private static <T> void getAttrs(final List<Field> fields, final Class<?> klass) {
	if (klass == null)
	return;
	for (Field field : klass.getDeclaredFields())
	fields.add(field);
	getAttrs(fields, klass.getSuperclass());
	}
	}
	package com.protto.erlpack;

	import java.math.BigInteger;

	public abstract class Erlpack {

	private static final BigInteger u64 = BigInteger.ONE.shiftLeft(64);

	protected static long toULong(final long l) {
	BigInteger b = BigInteger.valueOf(l);
	if (b.signum() < 0)
	b = b.add(u64);
	return b.longValue();
	}

	protected static byte[] toBytes(long l, final int bytes) {
	byte[] b = new byte[bytes];
	for (int i = bytes - 1; i >= 0; i--) {
	b[i] = (byte)(l & 0xFF);
	l >>= 8;
	}
	return b;
	}

	protected static long fromBytes(final byte[] data, int offset, final int bytes) {
	long b = 0;
	for (int i = 0; i < bytes; i++) {
	b <<= 8;
	b \|= (data[offset + i] & 0xFF);
	}
	return b;
	}

	protected static final byte
	FORMAT_VERSION = (byte)131,
	NEW_FLOAT_EXT = 'F', // 70 [Float64:IEEE float]
	BIT_BINARY_EXT = 'M', // 77 [UInt32:Len, UInt8:Bits, Len:Data]
	SMALL_INTEGER_EXT = 'a', // 97 [UInt8:Int]
	INTEGER_EXT = 'b', // 98 [Int32:Int]
	FLOAT_EXT = 'c', // 99 [31:Float String] Float in string format (formatted "%.20e", sscanf "%lf"). Superseded by NEW_FLOAT_EXT
	ATOM_EXT = 'd', // 100 [UInt16:Len, Len:AtomName] max Len is 255
	REFERENCE_EXT = 'e', // 101 [atom:Node, UInt32:ID, UInt8:Creation]
	PORT_EXT = 'f', // 102 [atom:Node, UInt32:ID, UInt8:Creation]
	PID_EXT = 'g', // 103 [atom:Node, UInt32:ID, UInt32:Serial, UInt8:Creation]
	SMALL_TUPLE_EXT = 'h', // 104 [UInt8:Arity, N:Elements]
	LARGE_TUPLE_EXT = 'i', // 105 [UInt32:Arity, N:Elements]
	NIL_EXT = 'j', // 106 empty list
	STRING_EXT = 'k', // 107 [UInt16:Len, Len:Characters]
	LIST_EXT = 'l', // 108 [UInt32:Len, Elements, Tail]
	BINARY_EXT = 'm', // 109 [UInt32:Len, Len:Data]
	SMALL_BIG_EXT = 'n', // 110 [UInt8:n, UInt8:Sign, n:nums]
	LARGE_BIG_EXT = 'o', // 111 [UInt32:n, UInt8:Sign, n:nums]
	NEW_FUN_EXT = 'p', // 112 [UInt32:Size, UInt8:Arity, 16Uint6-MD5:Uniq, UInt32:Index, UInt32:NumFree, atom:Module, int:OldIndex, int:OldUniq, pid:Pid, NunFreeext:FreeVars]
	EXPORT_EXT = 'q', // 113 [atom:Module, atom:Function, smallint:Arity]
	NEW_REFERENCE_EXT = 'r', // 114 [UInt16:Len, atom:Node, UInt8:Creation, Len*UInt32:ID]
	SMALL_ATOM_EXT = 's', // 115 [UInt8:Len, Len:AtomName]
	MAP_EXT = 't', // 116 [UInt32:Airty, N:Pairs]
	FUN_EXT = 'u', // 117 [UInt4:NumFree, pid:Pid, atom:Module, int:Index, int:Uniq, NumFree*ext:FreeVars]
	COMPRESSED = 'P'; // 80 [UInt4:UncompressedSize, N:ZlibCompressedData]

	public static<T> byte[] pack(final T value) throws Exception {
	return new Encoder().pack(value).compile();
	}

	public static<T> T unpack(final byte[] stream) throws Exception {
	return unpack(stream, 0, stream.length);
	}

	public static<T> T unpack(final byte[] stream, final int length) throws Exception {
	return unpack(stream, 0, length);
	}

	public static<T> T unpack(final byte[] stream, final int offset, final int length) throws Exception {
	return (T)(new Decoder(stream, offset, length, false).unpack());
	}
	}