This code is inspired by @Daniel Nuriyev's answer. But, instead of using nano-time, a counter (or discriminator as I've seen it called) is used when collisions occur in the same millisecond:
private static long previousTimeMillis = System.currentTimeMillis();
private static long counter = 0L;
public static synchronized long nextID() {
long currentTimeMillis = System.currentTimeMillis();
counter = (currentTimeMillis == previousTimeMillis) ? (counter + 1L) & 1048575L : 0L;
previousTimeMillis = currentTimeMillis;
long timeComponent = (currentTimeMillis & 8796093022207L) << 20;
return timeComponent | counter;
}
This method generates a semi-unique ID by packing a millisecond timestamp-component together with a counter-component. The algorithm allows for roughly a million (or 1048575 to be exact) unique IDs to be generated in the same millisecond before collisions start to occur. Unique IDs are generated until the year 2248 at which point it will wrap around and start at 0 again.
The ID-generation is done as follows:
Milliseconds since epoch:
|0|000000000000000000000010110111101111100110001001111100101011111|
Bitwise AND with (8796093022207L):
|0|000000000000000000001111111111111111111111111111111111111111111|
to give you the 43 least significant bits as the time-component.
Then shift this to the left by 20 bits to give you:
|0|0010110111101111100110001001111100101011111|00000000000000000000|
Bitwise OR with 20 bits of counter (e.g. if counter is 3) to give you:
|0|0010110111101111100110001001111100101011111|00000000000000000101|
Only 43 bits (and not 44) are used for the time-component as we do not want to allow the most significant bit (which is the sign of the number) to be changed. This results in only positive IDs to be generated.