Line 294 of java.util.Random source says
if ((n & n) == n) // i.e., n is a power of 2
// rest of the code
Why is this?
Line 294 of java.util.Random source says
Why is this? 

The description is not entirely accurate because
If n is a power of two, then n in binary is a single 1 followed by zeros. n in two's complement is the inverse + 1 so the bits lines up thus
To see why this work, consider two's complement as inverse + 1,
since you carry the one all the way through when adding one to get the two's complement. If n were anything other than a power of two† then the result would be missing a bit because the two's complement would not have the highest bit set due to that carry. †  or zero or a negative of a power of two ... as explained at the top. 


Because in 2's complement, If The converse is also true because 0 and negative numbers were ruled out by the previous line in that Java source. If



In two's complement representation, the unique thing about powers of two, is that they consist of all 0 bits, except for the kth bit, where n = 2^k:
To get a negative value in two's complement, you flip all the bits and add one. For powers of two, that means you get a bunch of 1s on the left up to and including the 1 bit that was in the positive value, and then a bunch of 0s on the right:
You can easily see that the result of column 2 & 4 is going to be the same as column 2. If you look at the other values missing from this chart, you can see why this doesn't hold for anything but the powers of two:
n&n will (for n > 0) only ever have 1 bit set, and that bit will be the least significant set bit in n. For all numbers that are powers of two, the least significant set bit is the only set bit. For all other numbers, there is more than one bit set, of which only the least significant will be set in the result. 


Simply, if n is a power of 2 that means only one bit is set to 1 and the others are 0's:
and because



It's property of powers of 2 and their two's complement. For example, take 8:
Calculating the two's complement:
For powers of 2, only one bit will be set so adding will cause the n^{th} bit of 2^{n} to be set (the one keeps carrying to the n^{th} bit). Then when you For numbers that aren't powers of 2, other bits will not get flipped so the 


You need to look at the values as bitmaps to see why this is true:
So only if both fields are 1 will a 1 come out. Now n does a 2's complement. It changes all the
However
Only for powers of 2 will 


Shown through example: 8 in hex = 0x000008 8 in hex = 0xFFFFF8 8 & 8 = 0x000008 


(n & (n  1)) == 0
also works (it removes the lowest order bit, if there are no bits left then there was at most 1 bit set in the first place). – harold Sep 13 '11 at 16:54