The only difference between signed an unsigned math in C and on the JVM comes up with the right-shift operator. For unsigned math, you use logical shift (since you don't want sign extension), whereas for signed math you do an arithmetic shift (which preserves the sign). This is one of the beauties of Two's complement arithmetic.
Based on that, all you have to do is change the Java/Scala
>> operator for the
>>> operator, and you'll get the same answer, bit-by-bit. However, depending on what you're doing it might still be problematic when you try to do something with the result, e.g. if you want to print it as an unsigned integer.
Let's say you want to do some math with "unsigned" longs in Scala and print the result at the end. Just use a normal long, use the
>>> (logical shift) operator in place of
>>, and then convert it to something else at the end that can represent the unsigned value. You could use a library like suggested in @rightfold's answer, or you can just do something simple like this:
val x = Long.MaxValue // declare my "unsigned" long
// do some math with it ...
val y = x + 10
// Convert it to the equivalent Scala BigInt
def asUnsigned(unsignedLong: Long) =
(BigInt(unsignedLong >>> 1) << 1) + (unsignedLong & 1)
// Long = 9223372036854775807
// res1: scala.math.BigInt = 9223372036854775817
If you're just using
Ints, then you don't even have to convert to
BigInt at the end since a
Long can hold the answer. Just use the method that @BrianRoach suggests in his comment above to convert an
Int's "unsigned" value to the equivalent
Long by masking-off the higher-order bytes. However, again, you shouldn't do the conversion until you absolutely have to. Even when using a 64-bit JVM on a 64-bit processor, the integer multiply and divide operations will be slower for a
Long (64-bit) than for an
Int (32-bit). (See this question for more details: Are 64 bit integers less efficient than 32 bit integers in the JVM?).