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How can I convert a short (2 bytes) to a byte array in Java, e.g.

short x = 233;
byte[] ret = new byte[2];


it should be something like this. But not sure.

((0xFF << 8) & x) >> 0;


Also you can use:


To discover to get whether the native bit order is big or small. In addition the following code is taken from java.io.Bits which does:

  • byte (array/offset) to boolean
  • byte array to char
  • byte array to short
  • byte array to int
  • byte array to float
  • byte array to long
  • byte array to double

And visa versa.

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6 Answers 6

up vote 37 down vote accepted
ret[0] = (byte)(x & 0xff);
ret[1] = (byte)((x >> 8) & 0xff);
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Ah thanks. I have posted a method too. –  Hugh Feb 2 '10 at 23:58
That's little endian, though. Network byte-order is big endian: 'byte[] arr=new byte[]{(byte)((x>>8)&0xFF),(byte)(x&0xFF)}; –  Lawrence Dol Feb 3 '10 at 1:31
This could work too byte[] arr=new byte[]{(byte)(x>>>8),(byte)(x&0xFF)} –  Javier Mar 27 '12 at 22:57
can I ask here, why is the masking needed if casting a short or int to byte will only ever take the LSB anyway?Thanks –  Lintford Pickle Aug 29 '13 at 19:45
The masking is superflous. The cast to byte truncates away the upper bits anyway, so masking them out is completly pointless. –  Durandal Oct 2 '14 at 18:34

A cleaner, albeit far less efficient solution is:

ByteBuffer buffer = ByteBuffer.allocate(2);
return buffer.array();

Keep this in mind when you have to do more complex byte transformations in the future. ByteBuffers are very powerful.

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Is buffer flip necessary? If yes, what is it good for? –  abimelex Nov 17 '13 at 15:39
@abimelex, yes it is necessary. Initially you write 2 bytes at position 0, 1. If you don't buffer.flip() then buffer.array() will read byte[] starting at position 2. buffer.flip() sets the position to 0 and the limit to 2 so you end up with an array of size 2 starting at the right position. Take a look at the Javadoc: docs.oracle.com/javase/7/docs/api/java/nio/Buffer.html#flip() –  Gili Nov 18 '13 at 16:30
@Gili No, the flip() is not necessary. buffer.array() simply returns the backing byte[] array. So if you're simply going to get the byte representation using the array, there is no need to flip(). However, if you are going to read the byte representation using the ByteBuffer directly, you should flip(). –  jvmk Oct 2 '14 at 18:04
@jvmk, on second glance. You're right. I've corrected the answer. –  Gili Oct 2 '14 at 18:13
How much less efficient are we talking? –  Barodapride Oct 3 '14 at 22:43

An alternative that is more efficient:

    // Big Endian
    ret[0] = (byte) x;
    ret[1] = (byte) (x >> 8);

    // Little Endian
    ret[0] = (byte) (x >> 8);
    ret[1] = (byte) x;
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Figure it out its.

public static byte[] toBytes(short s) {
        return new byte[]{(byte)(s & 0x00FF),(byte)((s & 0xFF00)>>8)};
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It depends how you want to represent it:

  • big endian or little endian? That will determine which order you put the bytes in.

  • Do you want to use 2's complement or some other way of representing a negative number? You should use a scheme that has the same range as the short in java to have a 1-to-1 mapping.

For big endian, the transformation should be along the lines of: ret[0] = x/256; ret[1] = x%256;

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public short bytesToShort(byte[] bytes) {
     return ByteBuffer.wrap(bytes).order(ByteOrder.LITTLE_ENDIAN).getShort();

public byte[] shortToBytes(short value) {
    byte[] returnByteArray = new byte[2];
    returnByteArray[0] = (byte) (value & 0xff);
    returnByteArray[1] = (byte) ((value >>> 8) & 0xff);
    return returnByteArray;
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