# What integer hash function are good that accepts an integer hash key?

What integer hash function are good that accepts an integer hash key?

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–  locster Nov 23 '12 at 13:46

Knuth's multiplicative method:

``````hash(i)=i*2654435761 mod 2^32
``````

In general, you should pick a multiplier that is in the order of your hash size (`2^32` in the example) and has no common factors with it. This way the hash function covers all your hash space uniformly.

Edit: The biggest disadvantage of this hash function is that it preserves divisibility, so if your integers are all divisible by 2 or by 4 (which is not uncommon), their hashes will be too. This is a problem in hash tables - you can end up with only 1/2 or 1/4 of the buckets being used.

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It's a really bad hash function, albeit attached to a famous name. –  Seun Osewa Aug 16 '10 at 16:00
It's not a bad hash function at all if used with prime table sizes. Also, it is meant for closed hashing. If hash values are not uniformly distributed, multiplicative hashing ensures that collisions from one value are unlikely to "disturb" items with other hash values. –  Paolo Bonzini Jun 3 '11 at 7:28
For the curious, this constant is chosen to be the hash size (2^32) divided by Phi –  Martin Källman May 31 '12 at 11:50
Paolo: Knuth's method is "bad" in the sense that it does not avalanche on the upper bits –  Martin Källman May 31 '12 at 11:51
On closer inspection, it turns out 2654435761 is actually a prime number. So that's probably why it was chosen rather than 2654435769. –  karadoc Dec 5 '13 at 12:13
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Depends on how your data is distributed. For a simple counter, the simplest function

``````f(i) = i
``````

will be good (I suspect optimal, but I can't prove it).

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Proof by contradiction. Assume that bucket b has more than one key: k1 and k2 where k1 != k2. Then f(k1) = k1 = b and f(k2) = k2 = b, by transitivity k1 = k2. QED. Although this function means that the size of your hash table is the size of your input set which completely defeats the point of a hash –  Tyler McHenry Mar 19 '09 at 21:05
@Tyler: The hash container will use f(i) % size to decide which bucket to put the value in. However, only f(i) is the hash function, the modulo operation belongs to the hash table. The object (integer) can't know which hash table it will be put in. –  erikkallen Mar 20 '09 at 16:35
The problem with this is that it's common to have large sets of integers that are divisible by a common factor (word-aligned memory adresses etc.). Now if your hash table happens to be divisible by the same factor, you end up with only half (or 1/4, 1/8, etc.) buckets used. –  Rafał Dowgird Mar 20 '09 at 16:56
@Rafal: That's why the response says "for a simple counter" and "Depends on how your data is distributed" –  erikkallen Mar 21 '09 at 12:17
That's actually the implementation by Sun of the method hashCode() in java.lang.Integer grepcode.com/file/repository.grepcode.com/java/root/jdk/openjdk/… –  Juande Carrion Oct 4 '12 at 16:56
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I found the following algorithm provides a very good statistical distribution. Each input bit affects each output bit with about 50% probability. There are no collisions (each input results in a different output). The algorithm is fast except if the CPU doesn't have a built-in integer multiplication unit. C code, assuming `int` is 32 bit (for Java, replace `>>` with `>>>` and remove `unsigned`):

``````unsigned int hash(unsigned int x) {
x = ((x >> 16) ^ x) * 0x45d9f3b;
x = ((x >> 16) ^ x) * 0x45d9f3b;
x = ((x >> 16) ^ x);
return x;
}
``````
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the first two lines are exactly the same! is there a typo here? –  Kshitij Banerjee Nov 23 '12 at 9:39
No this is not a typo, the second line further mixes the bits. Using just one multiplication isn't as good. –  Thomas Mueller Nov 23 '12 at 9:54
yeah but the 'h' before was making it redundant .I figured it out though.. thanks for the edit. It is decently fast completing in 19 machine cycles on my machine. BTW, why'd you change the magic number? does better? –  Kshitij Banerjee Nov 23 '12 at 10:09
I just tested. on my machine 0x3335b369 works better. –  Kshitij Banerjee Nov 23 '12 at 10:17
I believe in that case a larger factor would be better, but you would need to run some tests. Or (this is what I do) first use `x = ((x >> 32) ^ x)` and then use the 32 bit multiplications above. I'm not sure what's better. You may also want to look at the 64-bit finalizer for Murmur3 –  Thomas Mueller Nov 30 '12 at 10:12
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This page lists some simple hash functions that tend to decently in general, but any simple hash has pathological cases where it doesn't work well.

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Update: Added improved Sidestep function

For the sake of completeness, here is fairly inexpensive 32-bit hash with decent avalanche properties:

``````k *= 357913941;
k ^= k << 24;
k += ~357913941;
k ^= k >> 31;
k ^= k << 31;
``````

Avalanche diagrams

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This requires a 64-bit accumulator, i.e. operates on 64-bits internally –  Martin Källman Jul 19 '12 at 3:11
is k an int that has to be widened to a long? is the >> operation unsigned or signed? –  Andy Nuss Sep 17 '12 at 4:58
Is there difference in properties depending whether input is signed or not ? 3rd line will act differently. –  ruslan Jan 16 '13 at 21:22
• 32-bits multiplicative method (very fast) see @rafal

``````#define hash32(x) ((x)*2654435761)
#define H_BITS 24 // Hashtable size
#define H_SHIFT (32-H_BITS)
unsigned hashtab[1<<H_BITS]
....
unsigned slot = hash32(x) >> H_SHIFT
``````
• 32-bits and 64-bits (good distribution) at : MurmurHash

• Integer Hash Function
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agreed ... was the fastest that i could see. –  Kshitij Banerjee Nov 24 '12 at 20:15

There's a nice overview over some hash algorithms at Eternally Confuzzled. I'd recommend Bob Jenkins' one-at-a-time hash which quickly reaches avalanche and therefore can be used for efficient hash table lookup.

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That is a good article, but it is focused on hashing string keys, not integers. –  Adrian Mouat Jun 17 '10 at 10:52
Just to be clear, although the methods in the article would work for integers (or could be adapted to), I assume there are more efficient algorithms for integers. –  Adrian Mouat Jun 17 '10 at 11:06

The answer depends on a lot of things like:

• Where do you intend to employ it?
• What are you trying to do with the hash?
• Do you need a crytographically secure hash function?

I suggest that you take a look at the Merkle-Damgard family of hash functions like SHA-1 etc

Thanks mmeyers! For some reason, since the past few days, I: