I am having some difficulty with these two functions: byteArrayToInt and intToByteArray.

The problem is that if I use one to get to another and that result to get to the former, the results are different, as you can see from my examples below.

I cannot find the bug in the code. Any ideas are very welcome. Thanks.

public static void main(String[] args)
{
    int a = 123;
    byte[] aBytes = intToByteArray(a);
    int a2 = byteArrayToInt(aBytes);

    System.out.println(a);         // prints '123'
    System.out.println(aBytes);    // prints '[B@459189e1'
    System.out.println(a2);        // prints '2063597568
            System.out.println(intToByteArray(a2));  // prints '[B@459189e1'
}

public static int byteArrayToInt(byte[] b) 
{
    int value = 0;
    for (int i = 0; i < 4; i++) {
        int shift = (4 - 1 - i) * 8;
        value += (b[i] & 0x000000FF) << shift;
    }
    return value;
}

public static byte[] intToByteArray(int a)
{
    byte[] ret = new byte[4];
    ret[0] = (byte) (a & 0xFF);   
    ret[1] = (byte) ((a >> 8) & 0xFF);   
    ret[2] = (byte) ((a >> 16) & 0xFF);   
    ret[3] = (byte) ((a >> 24) & 0xFF);
    return ret;
}
  • Try removing the loop in byteArrayToInt. – Kevin Evans Mar 23 '11 at 1:18

10 Answers 10

up vote 38 down vote accepted

You're swapping endianness between your two methods. You have intToByteArray(int a) assigning the low-order bits into ret[0], but then byteArrayToInt(byte[] b) assigns b[0] to the high-order bits of the result. You need to invert one or the other, like:

public static byte[] intToByteArray(int a)
{
    byte[] ret = new byte[4];
    ret[3] = (byte) (a & 0xFF);   
    ret[2] = (byte) ((a >> 8) & 0xFF);   
    ret[1] = (byte) ((a >> 16) & 0xFF);   
    ret[0] = (byte) ((a >> 24) & 0xFF);
    return ret;
}
  • 5
    +1 good point about the byte ordering – Yanick Rochon Mar 23 '11 at 2:00
  • 4
    Take a look at the ByteBuffer class, I've created an example around it. – Maarten Bodewes Jul 30 '12 at 0:30

Your methods should be (something like)

public static int byteArrayToInt(byte[] b) 
{
    return   b[3] & 0xFF |
            (b[2] & 0xFF) << 8 |
            (b[1] & 0xFF) << 16 |
            (b[0] & 0xFF) << 24;
}

public static byte[] intToByteArray(int a)
{
    return new byte[] {
        (byte) ((a >> 24) & 0xFF),
        (byte) ((a >> 16) & 0xFF),   
        (byte) ((a >> 8) & 0xFF),   
        (byte) (a & 0xFF)
    };
}

These methods were tested with the following code :

Random rand = new Random(System.currentTimeMillis());
byte[] b;
int a, v;
for (int i=0; i<10000000; i++) {
    a = rand.nextInt();
    b = intToByteArray(a);
    v = byteArrayToInt(b);
    if (a != v) {
        System.out.println("ERR! " + a + " != " + Arrays.toString(b) + " != " + v);
    }
}
System.out.println("Done!");
  • @owlstead, yes, your code would work best to convert a byte[] into int[], however for isolated conversion of byte to int, using direct bit manipulation (especially when you know and expect the defined data to be properly formed) is a way lot faster than creating an instance of a class to do the exact same thing for each call. Even if you cache an instance of ByteBuffer, you'd still have to copy the passing bytes to the buffer's array, thus gives you some overhead in any case. – Yanick Rochon Jul 30 '12 at 17:25
  • 1
    @owlstead, perhaps, but if you can optimize a method from the start, and it is a really simple one, why would you settle for less? You don't need a reusable pattern here.. and, besides, the accumulation of "small price to pay" can escalate quite fast in a big project. Think about it. – Yanick Rochon Jul 30 '12 at 17:37
  • yes, this answer is a tidy old. I don't know why I used a for block for the first method... – Yanick Rochon Jul 30 '12 at 19:24
  • 2
    I'm a bit confused. In the intToByteArray method, why do you have to AND 0xFF to each byte before converting it back to a byte? 0xFF would include all 8 bits. And a byte is only 8 bits. So the code ` & 0xFF` seems pointless. – Kayla Feb 27 '14 at 20:57
  • 2
    @WaffleStealer654: That's needed because Java bytes are signed, so if the top bit is on it's a negative number with one bits in all the high-order bits when converted to an int. (The fact that Java bytes are signed is, well, to be polite, non-optimal in my opinion, but that's the way they are.) – RenniePet Feb 24 '15 at 14:39

That's a lot of work for:

public static int byteArrayToLeInt(byte[] b) {
    final ByteBuffer bb = ByteBuffer.wrap(b);
    bb.order(ByteOrder.LITTLE_ENDIAN);
    return bb.getInt();
}

public static byte[] leIntToByteArray(int i) {
    final ByteBuffer bb = ByteBuffer.allocate(Integer.SIZE / Byte.SIZE);
    bb.order(ByteOrder.LITTLE_ENDIAN);
    bb.putInt(i);
    return bb.array();
}

This method uses the Java ByteBuffer and ByteOrder functionality in the java.nio package. This code should be preferred where readability is required. It should also be very easy to remember.

I've shown Little Endian byte order here. To create a Big Endian version you can simply leave out the call to order(ByteOrder).


In code where performance is higher priority than readability (about 10x as fast):

public static int byteArrayToLeInt(byte[] encodedValue) {
    int value = (encodedValue[3] << (Byte.SIZE * 3));
    value |= (encodedValue[2] & 0xFF) << (Byte.SIZE * 2);
    value |= (encodedValue[1] & 0xFF) << (Byte.SIZE * 1);
    value |= (encodedValue[0] & 0xFF);
    return value;
}

public static byte[] leIntToByteArray(int value) {
    byte[] encodedValue = new byte[Integer.SIZE / Byte.SIZE];
    encodedValue[3] = (byte) (value >> Byte.SIZE * 3);
    encodedValue[2] = (byte) (value >> Byte.SIZE * 2);   
    encodedValue[1] = (byte) (value >> Byte.SIZE);   
    encodedValue[0] = (byte) value;
    return encodedValue;
}

Just reverse the byte array index to count from zero to three to create a Big Endian version of this code.


Notes:

  • In Java 8 you can also make use of the Integer.BYTES constant, which is more succinct than Integer.SIZE / Byte.SIZE.
  • 1
    One liner: byte[] result = ByteBuffer.allocate(Integer.SIZE / Byte.SIZE).order(ByteOrder.LITTLE_ENDIAN).putInt(i).array(); – Maarten Bodewes Jul 10 '12 at 18:57
  • OK, so there was an interesting discussion with Yanick about performance, so I've added a performance enhanced version, using Yanick's answer (upvoted) as base. The most important change is the removal of the for loop of course, as branching is slow on current CPU's. It's therefore at least twice as fast. – Maarten Bodewes Jul 30 '12 at 18:07
  • First of all, sorry for being asking something like this here, but is your ByteBuffer class available for the public? :) – user1130159 Nov 17 '12 at 23:03
  • 1
    @RaphaelC. It's in the standard JRE, in java.nio package... – Maarten Bodewes Nov 18 '12 at 0:46
  • Oh, I see.. Thanks – user1130159 Nov 19 '12 at 15:09

You can also use BigInteger for variable length bytes. You can convert it to Long, Integer or Short, whichever suits your needs.

new BigInteger(bytes).intValue();

or to denote polarity:

new BigInteger(1, bytes).intValue();

To get bytes back just:

new BigInteger(bytes).toByteArray()
  • 2
    Great, simple, flexible answer. Thanks! – Duffmaster33 Sep 17 '15 at 16:23
  • @Duffmaster33 Simple, but slow... and too much garbage collection pressure. But +1 anyway :) – St.Antario Oct 30 '17 at 15:06
  • @St.Antario Thanks for the comment, would you mind elaborating? I'm curious – Duffmaster33 Oct 31 '17 at 14:30
  • 1
    @Duffmaster33 This can be seen if we run simple JMH-benchmark. I ran it with -prof gc and saw that with default parameters on a single fork 5 warmup and 5 iterations I got 16 Minor GC with allocation rate 500 MB/sec. On my machine it's about 10 times slower. – St.Antario Oct 31 '17 at 14:51
  • @Duffmaster33 I just decompiled the version with bitwise operations and noticed that all these movsbl 0x13(%r11),%r10d movsbl 0x11(%r11),%eax movsbl 0x12(%r11),%r8d movzbl 0x10(%r11),%r9d And these all or-ed. – St.Antario Oct 31 '17 at 14:59

I like owlstead's original answer, and if you don't like the idea of creating a ByteBuffer on every method call then you can reuse the ByteBuffer by calling it's .clear() and .flip() methods:

ByteBuffer _intShifter = ByteBuffer.allocate(Integer.SIZE / Byte.SIZE)
                                   .order(ByteOrder.LITTLE_ENDIAN);

public byte[] intToByte(int value) {
    _intShifter.clear();
    _intShifter.putInt(value);      
    return _intShifter.array();
}

public int byteToInt(byte[] data)
{
    _intShifter.clear();
    _intShifter.put(data, 0, Integer.SIZE / Byte.SIZE);
    _intShifter.flip();
    return _intShifter.getInt();
}
  • 1
    Yup, just don't re-use the buffer in multi-threaded code, that would get you in trouble. – Maarten Bodewes Feb 1 '15 at 22:22

I found a simple way in com.google.common.primitives which is in the [Maven:com.google.guava:guava:12.0.1]

long newLong = Longs.fromByteArray(oldLongByteArray);
int newInt = Ints.fromByteArray(oldIntByteArray);

Have a nice try :)

I took a long look at many questions like this, and found this post... I didn't like the fact that the conversion code is duplicated for each type, so I've made a generic method to perform the task:

public static byte[] toByteArray(long value, int n)
{
    byte[] ret = new byte[n];
    ret[n-1] = (byte) ((value >> (0*8) & 0xFF);   
    ret[n-2] = (byte) ((value >> (1*8) & 0xFF);   
    ...
    ret[1] = (byte) ((value >> ((n-2)*8) & 0xFF);   
    ret[0] = (byte) ((value >> ((n-1)*8) & 0xFF);   
    return ret;
}

See full post.

  • Obviously it loops... not hand made :) – TacB0sS Jun 3 '12 at 13:46

/*sorry this is the correct */

     public byte[] IntArrayToByteArray(int[] iarray , int sizeofintarray)
     {
       final ByteBuffer bb ;
       bb = ByteBuffer.allocate( sizeofintarray * 4);
       for(int k = 0; k < sizeofintarray ; k++)
       bb.putInt(k * 4, iar[k]);
       return bb.array();
     }
  • Welcome to SO. An explanation would improve this answer. – user3717023 Mar 14 '16 at 2:50

Instead of allocating space, et al, an approach using ByteBuffer from java.nio....

byte[] arr = { 0x01, 0x00, 0x00, 0x00, 0x48, 0x01};

// say we want to consider indices 1, 2, 3, 4 {0x00, 0x00, 0x00, 0x48};
ByteBuffer bf = ByteBuffer.wrap(arr, 1, 4); // big endian by default
int num = bf.getInt();    // 72

Now, to go the other way.

ByteBuffer newBuf = ByteBuffer.allocate(4);
newBuf.putInt(num);
byte[] bytes = newBuf.array();  // [0, 0, 0, 72] {0x48 = 72}

here is my implementation

public static byte[] intToByteArray(int a) {
    return BigInteger.valueOf(a).toByteArray();
}

public static int byteArrayToInt(byte[] b) {
    return new BigInteger(b).intValue();
}
  • 1
    -1, this will return a different result than asked (it returns the minimum number of bytes instead of 4 bytes). Furthermore, using BigInteger is a bit heavy for this kind of purpose. – Maarten Bodewes Jul 10 '12 at 18:48
  • Not as bad as I expected though, only 20x slower than an optimized version :), mine was not that much faster I must admit. – Maarten Bodewes Jul 30 '12 at 18:31

Your Answer

By clicking "Post Your Answer", you acknowledge that you have read our updated terms of service, privacy policy and cookie policy, and that your continued use of the website is subject to these policies.

Not the answer you're looking for? Browse other questions tagged or ask your own question.