# Difference bloom filters and FM-sketches

What is the difference between bloom filters and hash sketches (also FM-sketches) and what is their use?

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## Hash sketches/Flajolet-Martin Sketches

Flajolet, P./Martin, G. (1985): Probabilistic counting algorithms for data base applications, in: Journal of Computer and System Sciences, Vol. 31, No. 2 (September 1985), pp. 182-209.

Durand, M./Flajolet, P. (2003): Loglog Counting of Large Cardinalities, in: Springer LNCS 2832, Algorithms ESA 2003, pp. 605–617.

Hash sketches are used to count the number of distinct elements in a set.

given:

• a bit array B[] of length l
• a (single) hash function h() that maps to [0,1,...2^l)
• a function r() that gives the position of the least-significant 1-bit in the binary representation of its input (e.g. 000101 returns 1, 001000 returns 4)

insertion of element x:

• pn := h(x) returns a pseudo-random number
• apply r(pn) to get the position of the bit array to set to 1 since output of h() is pseudo-random every bit i is set to 1 ~n/(2^(i+1)) times

number of distinct elements in the set:

• find the position p of the right-most 0 in the bit array
• p = log2(n), solve for n to get the number of distinct element in the set; the result might be up to 1.83 magnitudes off

usage:

• in Data Mining, P2P/distributed applications, estimation of the document frequency, etc.

## Bloom filters

Bloom, H. (1970): Space/time trade-offs in hash coding with allowable errors, in: Communications of the ACM, Vol. 13, No. 7 (July 1970), pp. 422-426.

Bloom filters are used to test whether an element is a member of a set.

given:

• a bit array B[] of length m
• k different hash functions h_k() that map to [0,...,m-1], i.e. to one of the position of the m-bit array

insertion of element x:

• apply h_k to x (h_k(x)), for all k, i.e. you get k values
• set the resulting bits in the array B to 1 (if already set to 1, don't change anything)

check if y is already in the set:

• get the positions p_k to check using all the hash functions h_k (h_k(y)), i.e. for each function h_k you get a position p_k
• if one of the positions p_k is set to 0 in the array B, the element y is definitively not in the set
• if all positions given by p_k are 1, the element y might (!) be in the set
• false positive rate is approximately (1 - e^(-kn/m))^k, no false negatives are possible!
• by increasing the number of hashing functions, the false positive rate can be decreased; however, at the same time your bloom filter gets slower; the optimal value of k is k = (m/n)ln(2)

usage:

• in the beginning used as a cheap filter in databases to filter out elements that do not match a query
• various applications today, e.g. in Google BigTable, but also in networking for IP lookups, etc.
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