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I was writing my own implementation of the power function and I discovered some weird results that occur at around Integer.MAX_VALUE, which I'm not sure why they occur. This is my implementation:

public static long power(long x, long y) {
    int result = 1;
    while (y > 0) {
        if ((y & 1) == 0) {
            x *= x;
            y >>>= 1;
        } else {
            result *= x;
            y--;
        }
    }
    return result;
}

The the following code is run,

System.out.println(fastPower(2, 31));
System.out.println(Math.pow(2, 31);
System.out.println((long)Math.pow(2, 31));
System.out.println((int)Math.pow(2, 31));

The results as follows, which I do not understand.

-2147483648
2.147483648E9
2147483648
2147483647

This further confuses me when shorts are used:

System.out.println(fastPower(2, 15));
System.out.println(Math.pow(2, 15));
System.out.println((int)Math.pow(2, 15));
System.out.println((short)Math.pow(2,15));

32768
32768.0
32768
-32768

These are the answers that I would expect, but they seem inconsistent with the results from ints.

3
  • @Carcigenicate I think OP understands that an overflow is happening. What they does not understand is why the last short is behaving differently.
    – Sweeper
    Jun 9, 2018 at 15:26
  • @Carcigenicate "Shouldn't System.out.println((int)Math.pow(2, 31)); print -2147483648 as well?" is possibly what the OP is asking.
    – Sweeper
    Jun 9, 2018 at 15:31
  • 1
    @Carcigenicate I think I found the answer in the language spec. It's about how doubles are converted to integer types
    – Sweeper
    Jun 9, 2018 at 16:16

2 Answers 2

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The first three outputs from both int and short are easy to explain:

-2147483648 // your method returns an int, so overflows
2.147483648E9 // Math.pow returns a double, so formatted like this
2147483648 // double casted to a long, 2147483648 inside the possible range for long

32768 // your method returns an int, 32768 is inside the possible range for int
32768.0 // Math.pow returns a double, so formatted like this
32768 // double casted to an int, 32768 is inside the possible range for int

The hard to explain bit is the fourth result. Shouldn't System.out.println((int)Math.pow(2, 31)); print -2147483648 as well?

The trick here is how Java does a conversion from double to int. According to the spec, this is known as a narrowing primitive conversion (§5.1.3):

22 specific conversions on primitive types are called the narrowing primitive conversions:

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

This is how a double to int conversion is carried out (bolded by me):

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, as follows:

  • If the floating-point number is NaN(§4.2.3), the result of the first step of the conversion is an int or long 0.
  • Otherwise, 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). Then there are two cases:

a. If T is long, and this integer value can be represented as a long, then the result of the first step is the long value V. b. Otherwise, if this integer value can be represented as an int, then the result of the first step is the int value V.

  • Otherwise, one of the following two cases must be true: a. The value must be too small (a negative value of large magnitude or negative infinity), and the result of the first step is the smallest representable value of type int or long. b. The value must be too large (a positive value of large magnitude or positive infinity), and the result of the first step is the largest representable value of type int or long.

    1. In the second step:
  • If T is int or long, the result of the conversion is the result of the first step.

  • 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.

The first step changes the double to the largest representable value of int - 2147483647. This is why in the int case, 2147483647 is printed. In the short case, the second step changes the int value of 2147483647 to a short, like this:

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.

This is why the short overflew, but the int did not!

0

Assuming power() and fastPower() are the same, fastPower(2, 31) returns -2147483648 because result variable is int, even though parameters and return type are all long.

Math.pow() returns a double, so casting of result to integral type (long, int, short, byte, char) follows the rules of JLS 5.1.3. Narrowing Primitive Conversion, quoted below.

Math.pow(2, 31) is 2147483648.0. When cast to long, it's the same value, i.e. 2147483648. When cast to int however, the value is too large so result is Integer.MAX_VALUE, i.e. 2147483647, as highlighted in the quote below.

Math.pow(2, 15) is 32768.0. When cast to int, it's the same value, i.e. 32768. When cast to short however, the value is first narrowed to int, then narrowed to short by discarding higher bits (see second quote below), resulting in numeric overflow to -32768.

A narrowing conversion of a floating-point number to an integral type T takes two steps:

  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, as follows:

    • If the floating-point number is NaN (§4.2.3), the result of the first step of the conversion is an int or long 0.

    • Otherwise, 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). Then there are two cases:

      1. If T is long, and this integer value can be represented as a long, then the result of the first step is the long value V.

      2. Otherwise, if this integer value can be represented as an int, then the result of the first step is the int value V.

    • Otherwise, one of the following two cases must be true:

      1. The value must be too small (a negative value of large magnitude or negative infinity), and the result of the first step is the smallest representable value of type int or long.

      2. The value must be too large (a positive value of large magnitude or positive infinity), and the result of the first step is the largest representable value of type int or long.

  2. In the second step:

    • If T is int or long, the result of the conversion is the result of the first step.

    • 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.

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.

1
  • Wow, we answered at nearly the same time!
    – Sweeper
    Jun 9, 2018 at 16:18

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