How come this happens:

char a = '\uffff'; //Highest value that char can take - 65535
byte b = (byte)a; //Casting a 16-bit value into 8-bit data type...! Isn't data lost here?
char c = (char)b; //Let's get the value back
int d = (int)c;
System.out.println(d); //65535... how?

Basically, I saw that a char is 16-bit. Therefore, if you cast it into a byte, how come no data is lost? (Value is the same after casting into an int)

Thanks in advance for answering this little ignorant question of mine. :P

EDIT: Woah, found out that my original output actually did as expected, but I just updated the code above. Basically, a character is cast into a byte and then cast back into a char, and its original, 2-byte value is retained. How does this happen?

  • 1
    Yeah, just realized that it does so on mine as well. I updated the code above, though, and now, basically, a character is cast into a byte and then cast back into a char, and its original, 2-byte value is retained. How does this happen?
    – wakachamo
    Feb 10, 2011 at 15:59

4 Answers 4


As trojanfoe states, your confusion on the results of your code is partly due to sign-extension. I'll try to add a more detailed explanation that may help with your confusion.

char a = '\uffff';
byte b = (byte)a;  // b = 0xFF

As you noted, this DOES result in the loss of information. This is considered a narrowing conversion. Converting a char to a byte "simply discards all but the n lowest order bits".
The result is: 0xFFFF -> 0xFF

char c = (char)b;  // c = 0xFFFF

Converting a byte to a char is considered a special conversion. It actually performs TWO conversions. First, the byte is SIGN-extended (the new high order bits are copied from the old sign bit) to an int (a normal widening conversion). Second, the int is converted to a char with a narrowing conversion.
The result is: 0xFF -> 0xFFFFFFFF -> 0xFFFF

int d = (int)c;  // d = 0x0000FFFF

Converting a char to an int is considered a widening conversion. When a char type is widened to an integral type, it is ZERO-extended (the new high order bits are set to 0).
The result is: 0xFFFF -> 0x0000FFFF. When printed, this will give you 65535.

The three links I provided are the official Java Language Specification details on primitive type conversions. I HIGHLY recommend you take a look. They are not terribly verbose (and in this case relatively straightforward). It details exactly what java will do behind the scenes with type conversions. This is a common area of misunderstanding for many developers. Post a comment if you are still confused with any step.


It's sign extension. Try \u1234 instead of \uffff and see what happens.


java byte is signed. it's counter intuitive. in almost all situations where a byte is used, programmers would want an unsigned byte instead. it's extremely likely a bug if a byte is cast to int directly.

This does the intended conversion correctly in almost all programs:

int c = 0xff & b ;

Empirically, the choice of signed byte is a mistake.


Some rather strange stuff going on your machine. Take a look at Java language specification, chapter 4.2.1:

The values of the integral types are integers in the following ranges:

For byte, from -128 to 127, inclusive

... snip others...

If your JVM is standards compliant, then your output should be -1.

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