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Assuming that we have a set of elements and want to store them in a hash map (for example std::unoredered_set), and each element has a key of type uint64_t which value can vary from 0 to its max possible value, is it the best choice to use trivial hash function, where a hash value of a key is a key itself? Does it depend on container in use (i.e. Google's sparse hash vs unordered map from STL)? The probability of appearance of key values is unknown.

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up vote 11 down vote accepted

If all you have to hash is a uint64_t of any possible value with unknown probabilities, and your output must be a uint64_t, then you don't gain any advantage by changing the value. Just use the key itself.

If you knew something about the distribution of your values or your values were restricted to a smaller range (which is really the same thing as knowing about the distribution), then it could be beneficial to apply a transformation to the key, but this depends on the implementation of the container. You would only benefit by reducing collisions when the table transforms a hash into a bucket index, but that depends both on the table's algorithm and the current/average state of the table (how often each bucket is used).

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Thanks, Thomas. Can I extend my question? I am just trying to come up with an idea. Say, uint64_t is actually 8 ASCII characters (A-Za-z0-9). But we treat it as uint64_t. Can we do something smarter with that? – user405725 Feb 23 '11 at 1:49
    
@Vlad Lazarenko: Using all 8 bytes that way will be fairly distributed, and that's generally the case for which generic hash tables are tuned, so probably not. Look at how the specific container you're using is tuned, but this isn't more than a small micro-optimization. – Thomas Edleson Feb 23 '11 at 2:03
    
@Vlad: if you want bit-perfect randomness in your hash value, you want to remove the constant parts (e.g. the most-significant bit may be 0 in every character), pack the variable bits together, then consider whether any particular values, combinations or permutations in the A-Za-z0-9 set are more frequent than others. If they're equally likely, then you've got 62 values in that set and can combine the 8 characters ala a + 62 * b + 62 * 62 * c etc (assuming you normalise a, b, c into the range 0..61). (All that may waste more time than a few extra collisions.) – Tony D Feb 23 '11 at 2:04
1  
@Tony: Sorry, I meant when the hash function wasn't trivial and actually had some information to use. The degenerate case of identity hash cannot, of course, be improved, but neither can it exploit any implementation property of the table. FWIW, packing the values as you commented on earlier defeats "effectively random and independent values in every bit of the hash". – Thomas Edleson Feb 23 '11 at 2:56
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Well, we agree then :-). Re "effectively random" and packing - my statement was prefixed with "If [the 62 values] are equally likely". In that case, the packing achieved effectively random and independent values in every bit of a smaller-width hash value: we have almost 6 random bits in each of 8 characters, so the lower ~48 bits of the resultant key are "perfect" quality: it's no longer a 64-bit hash value. As illustrated with the 256-bucket example above, consolidating the randomness across each of the lower-significance bits is the (at least theoretical) goal. – Tony D Feb 23 '11 at 3:12

I would suggest a good 64-bit mixer of which there are many to choose from. The finalizer from MurmerHash3 is fairly quick and does a reasonable job in just five lines of code:

key ^= key >> 33;
key *= 0xff51afd7ed558ccd;
key ^= key >> 33;
key *= 0xc4ceb9fe1a85ec53;
key ^= key >> 33;

Numerical Recipes, 3rd Edition, recommends this:

public static UInt64 Next( UInt64 u )
  {
  UInt64 v = u * 3935559000370003845 + 2691343689449507681;

  v ^= v >> 21;
  v ^= v << 37;
  v ^= v >>  4;

  v *= 4768777513237032717;

  v ^= v << 20;
  v ^= v >> 41;
  v ^= v <<  5;

  return v;
  }
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