`(l >> 32) ^ l`

is a good hashcode in most cases; particularly when the long has a uniform distribution.

Since it was the accepted answer, I'm posting this to clarify some of my comments about when it's NOT a good hashcode for a long.

The example I gave was a Point class like this:

```
public class Point {
private final long coords; //x in high-bits, y in low
public int getX() {
return (int)(coords >> 32);
}
public int getY() {
return (int)coords;
}
public int hashCode() {
return (int)((coords >> 32) ^ (coords));
}
}
```

It may seem contrived, but occasionally you have multiple "fields" packed into a long.

So the `coords`

field represents 32 bits of x and 32 bits of y. So why is this a problem? Well, it's not if each of x and y are evenly distributed over their respective 32 bits. But that's unlikely in practice. What is more likely is that X and Y are bounded by some number. Let's say 1024 since it's 2^10. This means that at most the lower 10 bits of each X and Y are set:

```
00000000 00000000 000000XX XXXXXXXX 00000000 00000000 000000YY YYYYYYYY
```

There are 2^20 (1024*1024) possible combinations. But what's the operation hashCode is doing?

```
00000000 00000000 000000XX XXXXXXXX
^ 00000000 00000000 000000YY YYYYYYYY
-------------------------------------
= 00000000 00000000 000000?? ????????
```

There are at most 2^10 (1024) possible hashCode values since only the lower 10 bits can ever be anything other than zero. The ratio of hash values to real values is `1024:(1024*1024)`

or `1:1024`

. So right off the bat there is a 1/1024 probability that two numbers have the same hash.

Now let's calculate the probability of a collision by applying math from the birthday problem. Let p(n) be the probability that with n values there will be at least one collision. We know that p(1025+) = 1 since there are only 1024 values.

```
p(n) = 1 - (n! * (1024 choose n))/1024^n
```

This works out to the following:

```
n: p(n)
1: 0.00000
2: 0.00098
3: 0.00293
4: 0.00585
5: 0.00973
6: 0.01457
...
38: 0.50096
...
79: 0.95444
...
148: 0.99999
```

With just 38 items, there is probably a collision. With 148 items, there is a 99.999% chance of (at least one) collision. With 148 items, each item has a 7% chance of colliding with another item. With a proper hashing function, taking knowledge of the domain, these numbers could easily go down to 0.

In other words, knowing your domain and how things happen in practice are key to making a performant hash. Library functions try to do as good a job as possible knowing nothing about your domain, and to be performant typically rely on a distribution of data that won't occur in practice.

`int`

is enough:`int hashCode = (int) id`

.`Long.hashcode(long)`

doesn't create a new object on the stack`(this.longValue()^(this.longValue()>>>32))`

produces more evenly distributed hash codes than just keeping the lower 32 bits of the value.`Integer.MAX_VALUE`

or`MIN_VALUE`

respectively, would i would have expected the cast to actually be doing..