In java,

There are integral types(char/short/int/long/byte)

There are floating types(float/double)

There is boolean type(boolean), not integral type, unlike C language.

Question 1)

Is there a generic rule for casting(as per JLS) that talks, which type can be converted to another type? Out of common sense, I know that, integral and floating types casting to boolean is not allowed

Question 2)

Please help me understand the reasons for below output:

         * Casting rules for primitive types
        double aDoubleValue = 30000000000000000000.123438934;
        int doubleToInt = (int)aDoubleValue; //stores max value 2147483647, makes sense!!
        byte doubleToByte = (byte)aDoubleValue; //stores -1, why not 127?
        short doubleToShort = (short)aDoubleValue; // stores -1, why not 32767?
        long doubleToLong = (long)aDoubleValue; // stores 9223372036854775807, makes sense!!
        float doubleToFloat = (float)aDoubleValue; // stores 3.0E19, 3.0 x 10^19  max value of float
        char doubleToChar = (char)aDoubleValue; // what does this store?
  • 4
    The rules for primitive types are actually stated explicitly: docs.oracle.com/javase/specs/jls/se7/html/jls-5.html#jls-5.1.2. for widening and docs.oracle.com/javase/specs/jls/se7/html/jls-5.html#jls-5.1.3 for narrowing.
    – dhke
    Jun 11 '15 at 9:14
  • @dhke why (byte)fmax and (short)fmax is -1 as per 5.1.3? any reason? Jun 11 '15 at 9:31
  • @overexchange - everything is explained there: "The results can be understood by examining the low order bits of the minimum and maximum int. The minimum int is, in hexadecimal, 0x80000000, and the maximum int is 0x7fffffff. This explains the short results, which are the low 16 bits of these values, namely, 0x0000 and 0xffff; it explains the char results, which also are the low 16 bits of these values, namely, '\u0000' and '\uffff'; and it explains the byte results, which are the low 8 bits of these values, namely, 0x00 and 0xff."
    – faramir
    Jul 15 '16 at 13:53

The JLS lists

19 specific conversions on primitive types are called the widening primitive conversions:

  • byte to short, int, long, float, or double
  • short to int, long, float, or double
  • char to int, long, float, or double
  • int to long, float, or double
  • long to float or double
  • float to double

Everything else needs an explicit cast. Narrowing is a little more complex:

  • double to float uses standard IEEE 754 rounding.
  • integer values have their most significant bits stripped to the available width of the target type. This may result in a sign bit appearing, e.g. (byte)0xfff == (byte)-1;
  • If the source type is floating point and the target type is long, the value is converted by rounding towards zero.
  • If the source type is floating point and the target type is integral but not long, the value is first converted to int by rounding towards zero. Then the resulting int is converted to the target type using integer conversion.


int doubleToInt = (int)aDoubleValue; 

yields Integer.MAX_VALUE as per rounding rules.

byte doubleToByte = (byte)aDoubleValue; 

first converts to int, yielding Integer.MAX_VALUE and then converts that to byte. Integer.MAX_VALUE is 0x7fffffff, hence the byte value 0xff which is -1.

short doubleToShort = (short)aDoubleValue;

same again: converts to int, yielding Integer.MAX_VALUE. 0x7fffffff to short yields 0xffff, i.e. -1.

The tricky thing is actually the to-char conversion. char is a single, 16-bit unicode character, hence char doubleToChar = (char)aDoubleValue gives you '\uffff' by the now familiar rules.

As can be seen there is a difference between floating point and integer narrowing operations. The floating point operations do actual rounding, while the integer operations perform bitwise clamping.

The integer semantics are probably inherited from C. At least the first step of the float-to-integral narrowing ops are also what you expected. The second narrowing steps, from double/float to short, byte and char may seem a little surprising, but if you really cast float to short, you should probably double check that you know what you are doing anyway.

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

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