Here is my program.

public class Foo
    public static void main(String[] args)
        System.out.println((int) 2147483648l);
        System.out.println((int) 2147483648f);

Here is the output.


Why isn't 2147483648l and 2147483648f type cast to the same integer? Can you explain what is going on here or what concept in Java I need to understand to predict the output of type casts like these?


These are examples of the Narrowing Primitive Conversion operation.

In your first example, long to int:

A narrowing conversion of a signed integer to an integral type T simply discards all but the n lowest order bits, where n is the number of bits used to represent type T. In addition to a possible loss of information about the magnitude of the numeric value, this may cause the sign of the resulting value to differ from the sign of the input value.

So your (int) 2147483648l is taking the 64 bits of the long:

00000000 00000000 00000000 00000000 10000000 00000000 00000000 00000000

...and dropping the top 32 bits entirely:

10000000 00000000 00000000 00000000

...and taking the remaining 32 bits as an int. Since the leftmost of those is now a sign bit (long and int are stored as two's complement), and since it happens to be set in your 2147483648l value, you end up with a negative number. Since no other bits are set, in two's complement, that means you have the lowest negative number int can represent: -2147483648.

The float to int example follows a more complex rule. The relevant parts for your value are:

...if the floating-point number is not an infinity, the floating-point value is rounded to an integer value V, rounding toward zero using IEEE 754 round-toward-zero mode (§4.2.3).

...[if] the value [is] too large (a positive value of large magnitude or positive infinity), [then] the result of the first step is the largest representable value of type int or long.

(But see the part of the spec linked above for the details.)

So since 2147483648f rounds to 2147483648, and 2147483648 is too large to fit in int, the largest value for int (2147483647) is used instead.

So in the long to int, it's bit fiddling; in the float to int, it's more mathematical.

In a comment you've asked:

Do you know why both (short) 32768 and (short) 32768f evaluate to -32768? I was exepecting the latter to evaluate to 32767.

Excellent question, and that's where my "see the part of the spec linked above for the details" above comes in. :-) (short) 32768f does, in effect, (short)(int)32768f:

In the spec section linked above, under "A narrowing conversion of a floating-point number to an integral type T takes two steps:", it says

  1. In the first step, the floating-point number is converted either to a long, if T is long, or to an int, if T is byte, short, char, or int...

and then later in Step 2's second bullet:

  1. * If T is byte, char, or short, the result of the conversion is the result of a narrowing conversion to type T (§5.1.3) of the result of the first step.

So in step one, 32768f becomes 32768 (an int value), and then of course (short)32768 does the bit-chopping we saw in long => int above, giving us a short value of -32768.

  • 2
    A wonderful answer. Upvoted - we don't want the OP to be tempted to accept mine. – Bathsheba Mar 21 '17 at 10:23
  • @Bathsheba: Why don't we want that? It's simple and clear. :-) – T.J. Crowder Mar 21 '17 at 10:26
  • 2
    Does this apply to other languages? c#? – Mario Garcia Mar 21 '17 at 14:32
  • @T.J.Crowder Do you know why both (short) 32768 and (short) 32768f evaluate to -32768? I was exepecting the latter to evaluate to 32767. – Lone Learner Mar 21 '17 at 15:25
  • 2
    @MarioGarcia: No. Each language defines its own semantics around this. In C#, both of the casts in the question result in -2147483648 (and both require an unchecked wrapper). – T.J. Crowder Mar 21 '17 at 23:41

Nice! It's wonderful to see the effects of design decisions presented in the way that you have.

2147483648l is a long type and the rule for converting a long that's too big for the int is to apply the wrap-around rule into the destination type. (Under the hood, the significant bits from the source type are simply discarded.)

2147483648f is a float type and the rule for converting a float that's too big for the destination type is to take the largest possible for the destination type. Reference Are Java integer-type primitive casts "capped" at the MAX_INT of the casting type?

The good thing about standards is that there are so many to choose from.

  • 10
    At least the behaviour is fully defined in the language spec and not left to the implementations. – biziclop Mar 21 '17 at 10:30
  • 3
    @biziclop: which personally I see as a shortcoming - you probably have to burn the living daylights out of the CPU of an "exotic" architecture so it conforms to this. – Bathsheba Mar 21 '17 at 10:32
  • 7
    @Bathsheba Depends on where you're coming from. For me it's infinitely better than getting a different result, because I don't care much how difficult it is to create the VM. But if your job is exactly that, I can see how the strict specification is a bit of a pain. Though not necessarily in this area, as this is a vanishingly rare scenario, more in the "everything has to be big endian" rule. – biziclop Mar 21 '17 at 10:35
  • @Bathsheba: A better approach IMHO would be to have a wider range of types defined in the language, many of which would typically be aliases for a smaller number of types, but with the exact set of types varying depending upon the implementation. Have some types whose behavior is rigidly specified in implementation-independent fashion, and some others whose behavior could vary according to what an implementation finds convenient. Code needing a specific behavior could use types which are guaranteed to provide it, while code with looser requirements could give implementations more freedom. – supercat Mar 21 '17 at 20:48
  • @supercat of course, having a large range of types with lots of small semantic differences is just asking for trouble... remember developers are the same people who regularly fail to write for loops correctly. As such even better approach would be to leave the very small portion of performance critical code running on exotic infrastructure to an entirely different language suited for such peculiarities and connect to it via some sort of Native Interface ;) – NPSF3000 Mar 22 '17 at 1:16

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