What are good hashing functions (fast, good distribution, few collisions) for hashing 2d and 3d vectors composed of IEEE 32bit floats. I assume general 3d vectors, but algorithms assuming normals (always in [-1,1]) are also welcome. I also do not fear bit-manipulation as IEEE floats are alsways IEEE floats.

Another more general problem is hashing an Nd float-vector, where N is quite small (3-12) and constant but not known at compile time. At the moment I just take these floats as uints and XOR them together, which is probably not the best solution.

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    ...have you tested how well your hashes are being distributed using the plain XOR method? You might be surprised. – Matti Virkkunen May 8 '11 at 16:33
  • @Matti it seems the distribution at least for 3d vectors is not very bad (tested on Stanford bunny 35k verts against hash table of size 65537). I just thought somebody perhaps has a more specialized solution, as I searched the net some time ago and haven't found anything on the topic. – Christian Rau May 8 '11 at 17:31
  • 65537 sounds like one greater than the number you might want to be using (or is a typo) – Steven Lu Sep 13 '13 at 3:12
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    Related: Good way to hash a float vector? – legends2k Mar 27 '14 at 10:13
  • @StevenLu: absolutely not. ++ a power of two is a good safe way to almost always get a prime number. Which is necessary to avoid modulo correlations, and as such, makes awesome hash table sizing. – v.oddou Nov 20 '14 at 2:35

There's a spatial hash function described in Optimized Spatial Hashing for Collision Detection of Deformable Objects. They use the hash function

hash(x,y,z) = ( x p1 xor y p2 xor z p3) mod n

where p1, p2, p3 are large prime numbers, in our case 73856093, 19349663, 83492791, respectively. The value n is the hash table size.

In the paper, x, y, and z are the discretized coordinates; you could probably also use the binary values of your floats.

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    Note that 19349663 isn't prime (it's the product of 41 and 471943) – sehe Sep 5 '13 at 13:20
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    I found that using the prime numbers p1 and p3 for the two-dimensional case results in very good distributions. – axel22 Mar 6 '16 at 21:36
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    When they wrote x p1 xor y p2 xor z p3, did they mean (x*p1) xor (y*p2) xor (z*p3) or x * (p1 xor y) * (p2 xor z) * p3? – emlai Jun 25 '16 at 15:24
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    @tuple_cat I believe it's (x*p1) xor (y*p2) xor (z*p3) – celion Jun 26 '16 at 14:31
  • Very interesting! Is there any implementation around? I am trying to implement this with scipy/numpy. Thanks. – tuned Apr 23 '17 at 17:29

I have two suggestions.

If you don't do the quantization, it wont be sensitive to closeness(locality).

  • Locality Sensitive Hashing has been mentioned for hashing higher dimensional vectors. Why not use them for 3d or 2d vectors as well? A variant of LSH using adapted for Eucledian distance metric (which is what we need for 2d and 3d vectors) is called Locality Sensitive Hashing using p-stable distributions. A very readable tutorial is here.

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