I have heard mixed opinions over the amount of memory that a byte takes up in a java program.

I am aware you can store no more than +127 in a java byte, and the documentation says that a byte is only 8 bits but here I am told that it actually takes up the same amount of memory as an int, and therefore is just a Type that helps in code comprehension and not efficiency.

Can anyone clear this up, and would this be an implementation specific issue?

  • a single byte takes 4/8 bytes depending on the cpu architecture, a byte in byte[] takes exactly one byte + object header (+trailing align) – bestsss Feb 5 '11 at 9:58
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    "I am aware you can store no more than +127 in a java byte" -- Not true, in a sense. You can store 256 different values in a byte, therefore you can store way more than 127 in it: up to 255 if you start from 0. It all depends on how you handle those 8 bits. Just for the sake of pedantry :P – Unai Vivi Aug 8 '12 at 14:05

13 Answers 13

up vote 59 down vote accepted

Okay, there's been a lot of discussion and not a lot of code :)

Here's a quick benchmark. It's got the normal caveats when it comes to this kind of thing - testing memory has oddities due to JITting etc, but with suitably large numbers it's useful anyway. It has two types, each with 80 members - LotsOfBytes has 80 bytes, LotsOfInts has 80 ints. We build lots of them, make sure they're not GC'd, and check memory usage:

class LotsOfBytes
    byte a0, a1, a2, a3, a4, a5, a6, a7, a8, a9, aa, ab, ac, ad, ae, af;
    byte b0, b1, b2, b3, b4, b5, b6, b7, b8, b9, ba, bb, bc, bd, be, bf;
    byte c0, c1, c2, c3, c4, c5, c6, c7, c8, c9, ca, cb, cc, cd, ce, cf;
    byte d0, d1, d2, d3, d4, d5, d6, d7, d8, d9, da, db, dc, dd, de, df;
    byte e0, e1, e2, e3, e4, e5, e6, e7, e8, e9, ea, eb, ec, ed, ee, ef;

class LotsOfInts
    int a0, a1, a2, a3, a4, a5, a6, a7, a8, a9, aa, ab, ac, ad, ae, af;
    int b0, b1, b2, b3, b4, b5, b6, b7, b8, b9, ba, bb, bc, bd, be, bf;
    int c0, c1, c2, c3, c4, c5, c6, c7, c8, c9, ca, cb, cc, cd, ce, cf;
    int d0, d1, d2, d3, d4, d5, d6, d7, d8, d9, da, db, dc, dd, de, df;
    int e0, e1, e2, e3, e4, e5, e6, e7, e8, e9, ea, eb, ec, ed, ee, ef;

public class Test
    private static final int SIZE = 1000000;

    public static void main(String[] args) throws Exception
        LotsOfBytes[] first = new LotsOfBytes[SIZE];
        LotsOfInts[] second = new LotsOfInts[SIZE];

        long startMem = getMemory();

        for (int i=0; i < SIZE; i++)
            first[i] = new LotsOfBytes();

        long endMem = getMemory();

        System.out.println ("Size for LotsOfBytes: " + (endMem-startMem));
        System.out.println ("Average size: " + ((endMem-startMem) / ((double)SIZE)));

        startMem = getMemory();
        for (int i=0; i < SIZE; i++)
            second[i] = new LotsOfInts();
        endMem = getMemory();

        System.out.println ("Size for LotsOfInts: " + (endMem-startMem));
        System.out.println ("Average size: " + ((endMem-startMem) / ((double)SIZE)));

        // Make sure nothing gets collected
        long total = 0;
        for (int i=0; i < SIZE; i++)
            total += first[i].a0 + second[i].a0;

    private static long getMemory()
        Runtime runtime = Runtime.getRuntime();
        return runtime.totalMemory() - runtime.freeMemory();

Output on my box:

Size for LotsOfBytes: 88811688
Average size: 88.811688
Size for LotsOfInts: 327076360
Average size: 327.07636

So obviously there's some overhead - 8 bytes by the looks of it, although somehow only 7 for LotsOfInts (? like I said, there are oddities here) - but the point is that the byte fields appear to be packed in for LotsOfBytes such that it takes (after overhead removal) only a quarter as much memory as LotsOfInts.

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    it depends on the JVM. Sun aligns to 8 Byte boundaries – kohlerm Oct 27 '08 at 20:38
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    @kohlerm: That was with a Sun JVM. – Jon Skeet Dec 2 '08 at 19:07
  • @JonSkeet very clever – Zo72 Feb 16 '12 at 17:13
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    Nice test, but if you test with class LotsOfBytes { byte a0; } class LotsOfInts { int a0; } there won't be any significant difference – Ivan Balashov Jun 20 '12 at 13:11
  • Explain me MY output please: Size for LotsOfBytes: -914712 Average size: -914.712 Size for LotsOfInts: 336000 Average size: 336.0 0 – Bitterblue May 7 '13 at 7:20

Yes, a byte variable is in fact 4 bytes in memory. However this doesn't hold true for arrays. A byte array of 20 bytes is in fact only 20 bytes in memory. That is because the Java Bytecode Language only knows ints and longs as number types (so it must handle all numbers as either type of both, 4 bytes or 8 bytes), but it knows arrays with every possible number size (so short arrays are in fact two bytes per entry and byte arrays are in fact one byte per entry).

  • oh yeah, I forgot that not-so-little detail! – Steve McLeod Oct 23 '08 at 14:39
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    Don't forget that a byte array also has the normal overheads of being an object, and the length. Oh, and your variable is then a reference (4 or 8 bytes). So to actually have 20 bytes available and useful will require 36 bytes, assuming no aliasing. I'd stick to 20 byte fields :) – Jon Skeet Oct 23 '08 at 15:10
  • @Jon @Mecki Can you give more or less exact formula to compute the size of int[] array? Will it be 4[=length] + 4[=int_size]*length(array) + 8_byte_align? – dma_k Mar 8 '10 at 10:53
  • @dma_k: There is no formula because it solely depends on the virtual machine. An array is more or less an object in Java. An object might have 20 internal variables, necessary for VM management only, or it might have none of these. There is more than just Sun's VM on this planet (a lot more). An int[] array will for sure be at least "4 * length(array)" and has some static overhead. Overhead can be anything, from 4 byte to xxx byte; overhead does not depend on array size (int[1] has the same static overhead as int[10000000]); thus overhead is insignificant for big arrays. – Mecki Mar 8 '10 at 11:36
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    @Mecki I found this link in yet another thread; it satisfied my curiosity: kohlerm.blogspot.com/2008/12/… – dma_k Mar 8 '10 at 17:12

Java is never implementation or platform specific (at least as far as primitive type sizes are concerned). They primitive types are always guaranteed to stay the same no matter what platform you're on. This differs from (and was considered an improvement on) C and C++, where some of the primitive types were platform specific.

Since it's faster for the underlying operating system to address four (or eight, in a 64-bit system) bytes at a time, the JVM may allocate more bytes to store a primitive byte, but you can still only store values from -128 to 127 in it.

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    Even if it uses 4 bytes to store a byte, an array of bytes would probably be packed. I would be surprised if a byte[4] used 16 bytes instead of 4 bytes. – Kip Oct 23 '08 at 14:32
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    Probably. That would be implementation specific. I honestly don't know which method would be faster. – Bill the Lizard Oct 23 '08 at 14:36
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    the article is correct, but the comment is wrong. a single byte variable consumes 1 byte +aligment. 8 Byte variabels on a Sun JVM for example cost 8 bytes – kohlerm Oct 27 '08 at 20:40

A revealing exercise is to run javap on some code that does simple things with bytes and ints. You'll see bytecodes that expect int parameters operating on bytes, and bytecodes being inserted to co-erce from one to another.

Note though that arrays of bytes are not stored as arrays of 4-byte values, so a 1024-length byte array will use 1k of memory (Ignoring any overheads).

I did a test using http://code.google.com/p/memory-measurer/ Note that I am using 64-bit Oracle/Sun Java 6, without any compression of references etc.

Each object occupies some space, plus JVM needs to know address of that object, and "address" itself is 8 bytes.

With primitives, looks like primitives are casted to 64-bit for better performance (of course!):

byte: 16 bytes,
 int: 16 bytes,
long: 24 bytes.

With Arrays:

byte[1]: 24 bytes
 int[1]: 24 bytes
long[1]: 24 bytes

byte[2]: 24 bytes
 int[2]: 24 bytes
long[2]: 32 bytes

byte[4]: 24 bytes
 int[4]: 32 bytes
long[4]: 48 bytes

byte[8]: 24 bytes => 8 bytes, "start" address, "end" address => 8 + 8 + 8 bytes
 int[8]: 48 bytes => 8 integers (4 bytes each), "start" address, "end" address => 8*4 + 8 + 8 bytes
long[8]: 80 bytes => 8 longs (8 bytes each), "start" address, "end" address => 8x8 + 8 + 8 bytes

And now guess what...

    byte[8]: 24 bytes
 byte[1][8]: 48 bytes
   byte[64]: 80 bytes
 byte[8][8]: 240 bytes

P.S. Oracle Java 6, latest and greatest, 64-bit, 1.6.0_37, MacOS X

It depends on how the JVM applies padding etc. An array of bytes will (in any sane system) be packed into 1-byte-per-element, but a class with four byte fields could either be tightly packed or padded onto word boundaries - it's implementation dependent.

  • Does this mean that using a byte alone will not save memory, but if i were to use more than one byte variable (or an array of bytes) i could save significant memory. (I.e. A byte[10][10] <i>could/should</i> take less memory than a int[10][10]) – Ben Page Oct 23 '08 at 14:28
  • Potentially :) (Certainly I'd expect a byte array to take up less space than an int array - but four byte variables vs four int variables? Don't know.) – Jon Skeet Oct 23 '08 at 14:36
  • (See my other answer for evidence that at least some JVMs do packing.) – Jon Skeet Oct 23 '08 at 15:03

What you've been told is exactly right. The Java byte code specification only has 4-byte types and 8-byte types.

byte, char, int, short, boolean, float are all stored in 4 bytes each.

double and long are stored in 8 bytes.

However byte code is only half the story. There's also the JVM, which is implementation-specific. There's enough info in Java byte code to determine that a variable was declared as a byte. A JVM implementor may decide to use only a byte, although I think that is highly unlikely.

  • Hmm... that seems to go against java.sun.com/docs/books/jvms/second_edition/html/… : "The values of the integral types of the Java virtual machine are the same as those for the integral types of the Java programming language (§2.4.1)" (Looking for bytecode stuff now...) – Jon Skeet Oct 23 '08 at 14:24
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    Actually it also has arrays and byte arrays are in fact byte arrays and there every byte really is a byte – Mecki Oct 23 '08 at 14:33
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    Yes it does. But the Java stack is defined as a series of 4-byte slots. Pushing onto the stack always uses one (for 4-byte types) or two (for 8-byte types) elements. bipush will use one slot. – Steve McLeod Oct 23 '08 at 14:35
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    And the JVM certainly knows when a field is a byte field rather than an int field, doesn't it? It may choose not to pack them tightly, but surely that's an implementation decision. – Jon Skeet Oct 23 '08 at 14:35
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    Even if the Java stack is int-based, that doesn't mean its object layout has to be. I'm working up a benchmark... – Jon Skeet Oct 23 '08 at 14:48

You could always use longs and pack the data in yourself to increase efficiency. Then you can always gaurentee you'll be using all 4 bytes.

  • or even all 8 bytes, in a long :) – JeeBee Oct 23 '08 at 14:34
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    if you're actually considering this type of memory management, I think you should probably be using C++ or some other language that lets you do the memory management yourself. You'll lose far more in the overhead of the JVM than you'll save through tricks like this in Java. – rmeador Oct 23 '08 at 14:35
  • Ah. In C/C++ on 32bit systems int and long are both 32bit or 4 bytes; I forget that long is actually a long on other systems - always made me laugh when they added "longlong" to indicate an 8byte long... ah well. – Christopher Lightfoot Oct 24 '08 at 9:02
  • you can gain performance because you can with ints you can handle 4 bytes at once, not because you save memory (at lost usually) You don't need to pack byte[]'s. you need to avoid single byte fields in objects because alignment will increase the memory overhead – kohlerm Oct 27 '08 at 20:45

byte = 8bit = one byte defined by the Java Spec.

how much memory an byte array needs is not defined by the Spec, nor is defined how much a complex objects needs.

For the Sun JVM I documented the rules: https://www.sdn.sap.com/irj/sdn/weblogs?blog=/pub/wlg/5163

See my MonitoringTools at my site (www.csd.uoc.gr/~andreou)

class X {
   byte b1, b2, b3...;

long memoryUsed = MemoryMeasurer.measure(new X());

(It can be used for more complex objects/object graphs too)

In Sun's 1.6 JDK, it seems that a byte indeed takes a single byte (in older versions, int ~ byte in terms of memory). But note that even in older versions, byte[] were also packed to one byte per entry.

Anyway, the point is that there is no need for complex tests like Jon Skeet's above, that only give estimations. We can directly measure the size of an object!

  • Your link is broken – Pacerier Nov 3 '11 at 4:09
  • I guess it lives now here – magiconair Mar 1 '12 at 6:19

Reading through the above comments, it seems that my conclusion will come as a surprise to many (it is also a surprise to me), so it worths repeating:

  • The old size(int) == size(byte) for variables holds no more, at least in Sun's Java 6.

Instead, size(byte) == 1 byte (!!)

Just wanted to point out that the statement

you can store no more than +127 in a java byte

is not truly correct.

You can always store 256 different values in a byte, therefore you can easily have your 0..255 range as if it were an "unsigned" byte.

It all depends on how you handle those 8 bits.


byte B=(byte)200;//B contains 200
System.out.println((B+256)%256);//Prints 200
System.out.println(B&0xFF);//Prints 200

It appears that the answer is likely to depend on your JVM version and probably also the CPU architecture you're running on. The Intel line of CPUs do byte manipulation efficiently (due to its 8-bit CPU history). Some RISC chips require word (4 byte) alignment for many operations. And memory allocation can be different for variables on the stack, fields in a class, and in an array.

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