# How many hash functions are required in a minhash algorithm

I am keen to try and implement minhashing to find near duplicate content. http://blog.cluster-text.com/tag/minhash/ has a nice write up, but there the question of just how many hashing algorithms you need to run across the shingles in a document to get reasonable results.

The blog post above mentioned something like 200 hashing algorithms. http://blogs.msdn.com/b/spt/archive/2008/06/10/set-similarity-and-min-hash.aspx lists 100 as a default.

Obviously there is an increase in the accuracy as the number of hashes increases, but how many hash functions is reasonable?

To quote from the blog

It is tough to get the error bar on our similarity estimate much smaller than [7%] because of the way error bars on statistically sampled values scale — to cut the error bar in half we would need four times as many samples.

Does this mean that mean that decreasing the number of hashes to something like 12 (200 / 4 / 4) would result in an error rate of 28% (7 * 2 * 2)?

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Pretty much.. but 28% would be the "error estimate", meaning reported measurements would frequently be inaccurate by +/- 28%.

That means that a reported measurement of 78% could easily come from only 50% similarity.. Or that 50% similarity could easily be reported as 22%. Doesn't sound accurate enough for business expectations, to me.

Mathematically, if you're reporting two digits the second should be meaningful.

Why do you want to reduce the number of hash functions to 12? What "200 hash functions" really means is, calculate a decent-quality hashcode for each shingle/string once -- then apply 200 cheap & fast transformations, to emphasise certain factors/ bring certain bits to the front.

I recommend combining bitwise rotations (or shuffling) and an XOR operation. Each hash function can combined rotation by some number of bits, then XORing by a randomly generated integer.

This both "spreads" the selectivity of the min() function around the bits, and as to what value min() ends up selecting for.

The rationale for rotation, is that "min(Int)" will, 255 times out of 256, select only within the 8 most-significant bits. Only if all top bits are the same, do lower bits have any effect in the comparison.. so spreading can be useful to avoid undue emphasis on just one or two characters in the shingle.

The rationale for XOR is that, on it's own, bitwise rotation (ROTR) can 50% of the time (when 0 bits are shifted in from the left) converge towards zero, and that would cause "separate" hash functions to display an undesirable tendency to coincide towards zero together -- thus an excessive tendency for them to end up selecting the same shingle, not independent shingles.

There's a very interesting "bitwise" quirk of signed integers, where the MSB is negative but all following bits are positive, that renders the tendency of rotations to converge much less visible for signed integers -- where it would be obvious for unsigned. XOR must still be used in these circumstances, anyway.

Java has 32-bit hashcodes builtin. And if you use Google Guava libraries, there are 64-bit hashcodes available.

Thanks to @BillDimm for his input & persistence in pointing out that XOR was necessary.

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Ok, that makes sense. Thanks. –  Phyxx Oct 31 '13 at 8:29
Following what Bill said below, I'd like to suggest supplementing 'rotation' with 'XOR' to both change which bits are 'most selective' and randomize which values the 'min' function is selecting for. Thanks @BillDimm! –  Thomas W Nov 2 '13 at 0:43
@BillDimm and I have investigated actual behaviour of hash functions in my Java example code -- turns out that ROTATE should always be combined with XOR. ROTATE on it's own can produce excessive collisions, since 50% of single-bit rotations converge towards zero and "minimum" may tend to select the same shingles. Thanks Bill for your assistance in pointing this out! –  Thomas W Nov 3 '13 at 21:56