Starting with the following code...

byte foo = 1;
byte fooFoo = foo + foo;

When I try compiling this code I will get the following error...

Error:(5, 27) java: incompatible types: possible lossy conversion from int to byte

... but if foo is final...

final byte foo = 1;
final byte fooFoo = foo + foo;

the file will compile successfully.

Moving on to the following code...

final byte[] fooArray = new byte[1];
fooArray[0] = 1;

final byte foo = fooArray[0];
fooArray[0] = 127;

System.out.println("foo is: " + foo);

... will print

foo is: 1

... which is fine. The value is copied to a final variable and it can not be changed any more. Playing with the value in the array does not change the value of the foo (as expected...).

Why does the following require a cast?

final byte[] fooArray = new byte[1];
fooArray[0] = 1;
final byte foo = fooArray[0];
final byte fooFoo = foo + foo;

How is this different than the second example in this question? Why is the compiler giving me the following error?

Error:(5, 27) java: incompatible types: possible lossy conversion from int to byte

How can this happen?

  • 2
    Just a note about your second example, where you initialize foo from the array and test that it doesn't change. Its value won't change even if foo isn't final. The assignment (initialization in this case) copies the value at the moment that it happens (1) and that's it. The consequent change of fooArray[0] to 127 will not be automatically propagated to foo regardless of if is it final or not.
    – ivant
    Mar 29, 2017 at 15:34

4 Answers 4


The JLS (§5.2) has special rules for assignment conversion with constant expressions:

In addition, if the expression is a constant expression (§15.28) of type byte, short, char, or int:

  • A narrowing primitive conversion may be used if the type of the variable is byte, short, or char, and the value of the constant expression is representable in the type of the variable.

If we follow the link above, we see these in the definition of constant expression:

  • Literals of primitive type and literals of type String
  • The additive operators + and -
  • Simple names (§ that refer to constant variables (§4.12.4).

If we follow the second link above, we see that

A variable of primitive type or type String, that is final and initialized with a compile-time constant expression (§15.28), is called a constant variable.

It follows that foo + foo can only be assigned to fooFoo if foo is a constant variable. To apply that to your cases:

  • byte foo = 1; does not define a constant variable because it's not final.

  • final byte foo = 1; does define a constant variable, because it's final and initialized with a constant expression (a primitive literal).

  • final byte foo = fooArray[0]; does not define a constant variable because it's not initialized with a constant expression.

Note that whether fooFoo is itself final doesn't matter.

  • But how about the last question: "How can this happen?" (where this = possible lossy conversion from int to byte) Mar 27, 2017 at 5:32
  • @KorayTugay Practically speaking, it can't happen in your example. But the compiler doesn't know that; the spec doesn't allow it to make that deduction.
    – shmosel
    Mar 27, 2017 at 5:39

The value 1 fits nicely into a byte; so does 1+1; and when the variable is final, the compiler can do constant folding. (in other words: the compiler doesn't use foo when doing that + operation; but the "raw" 1 values)

But when the variable is not final, then all the interesting rules about conversions and promotions kick in (see here; you want to read section 5.12 about widening primitive conversions).

For the second part: making an array final still allows you to change any of its fields; so again; no constant folding possible; so that "widening" operation is kicking in again.


It is indeed what compiler do in constant folding when used with final, as we can see from byte code:

    byte f = 1;
    // because compiler still use variable 'f', so `f + f` will 
    // be promoted to int, so we need cast
    byte ff = (byte) (f + f);
    final byte s = 3;
    // here compiler will directly compute the result and it know
    // 3 + 3 = 6 is a byte, so no need cast
    byte ss = s + s;
    ICONST_1 // set variable to 1
    ISTORE 1 // store variable 'f'
    ILOAD 1 // use variable 'f'
    ILOAD 1
    ISTORE 2 // store 'ff'

    ICONST_3 // set variable to 3
    ISTORE 3 // store 's'
    BIPUSH 6 // compiler just compute the result '6' and set directly
    ISTORE 4 // store 'ss'

And if you change your final byte to 127, it will also complain:

    final byte s = 127;
    byte ss = s + s;

in which cases, the compiler compute the result and know it out of limit, so it will still complain they are incompatible.


And here is another question about constant folding with string:

  • I only had my mobile to answer, so I skipped the bytecode part. Glad you volunteered to do :-)
    – GhostCat
    Mar 26, 2017 at 15:01
  • 2
    Also demonstrates the motive: when compiling to bytecode, the byte variables get widened to int in order to store them and do computations with them, unless the operands on the right-hand side are final constants, in which case the computation can happen statically at compile time.
    – Davislor
    Mar 26, 2017 at 17:14

This occurs because of

byte foo = 1;
byte fooFoo = foo + foo;

foo + foo = 2 will be answered but 2 is not byte type because of java has default data type to integer variables it's type is int. So you need to tell the compiler by force that answer must be a byte type explicitly.

class Example{
    public static void main(String args[]){

        byte b1 = 10;
        byte b2 = 20;
        byte b1b2 = (byte)(b1 + b2); 

        //~ b1 += 100;  // (+=) operator automaticaly type casting that means narrow conversion

        int tot = b1 + b2;

        //~ this bellow statement prints the type of the variable
        System.out.println(((Object)(b1 + b2)).getClass());  //this solve your problem

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