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I have a large collection (~thousands) of sequences of integers. Each sequence has the following properties:

  1. it is of length 12;
  2. the order of the sequence elements does not matter;
  3. no element appears twice in the same sequence;
  4. all elements are smaller than about 300.

Note that the properties 2. and 3. imply that the sequences are actually sets, but they are stored as C arrays in order to maximise access speed.

I'm looking for a good C++ algorithm to check if a new sequence is already present in the collection. If not, the new sequence is added to the collection. I thought about using a hash table (note however that I cannot use any C++11 constructs or external libraries, e.g. Boost). Hashing the sequences and storing the values in a std::set is also an option, since collisions can be just neglected if they are sufficiently rare. Any other suggestion is also welcome.


I need a commutative hash function, i.e. a function that does not depend on the order of the elements in the sequence. I thought about first reducing the sequences to some canonical form (e.g. sorting) and then using standard hash functions (see refs. below), but I would prefer to avoid the overhead associated with copying (I can't modify the original sequences) and sorting. As far as I can tell, none of the functions referenced below are commutative. Ideally, the hash function should also take advantage of the fact that elements never repeat. Speed is crucial.

Any suggestions?

share|improve this question
Sort the sequence and use boost::hash_combine on the individual hashes. – Kerrek SB Oct 11 '12 at 13:45
Why do Huffman codes suddenly spring to my head? Total compression-lib flashback. – WhozCraig Oct 11 '12 at 13:45
@KerrekSB, I can't use any external libraries or C++11 constructs. – Arek' Fu Oct 11 '12 at 13:48
What are the properties of the integers? I'm just wondering if they are spread out relatively evenly whether a quick and dirty option would be to just bitwise-xor the numbers all together to create another int that can be compared. SHould keep collisions to a minimum and not require sorting but if all your numbers are 1 to 100 or something then you're likely to get a lot of collisions... – Chris Oct 11 '12 at 13:48
@Arek'Fu: Look at the code. boost::hash_combine is five lines long. Just copy it. – Kerrek SB Oct 11 '12 at 13:49
up vote 3 down vote accepted

Sort the elements of your sequences numerically and then store the sequences in a trie. Each level of the trie is a data structure in which you search for the element at that level ... you can use different data structures depending on how many elements are in it ... e.g., a linked list, a binary search tree, or a sorted vector.

If you want to use a hash table rather than a trie, then you can still sort the elements numerically and then apply one of those non-commutative hash functions. You need to sort the elements in order to compare the sequences, which you must do because you will have hash table collisions. If you didn't need to sort, then you could multiply each element by a constant factor that would smear them across the bits of an int (there's theory for finding such a factor, but you can find it experimentally), and then XOR the results. Or you could look up your ~300 values in a table, mapping them to unique values that mix well via XOR (each one could be a random value chosen so that it has an equal number of 0 and 1 bits -- each XOR flips a random half of the bits, which is optimal).

share|improve this answer
I've spent some time trying to implement your second suggestion today, and I think it is the most promising so far. I've constructed 300 random 64-bit strings, with an equal number of 0 and 1 bits each. I tried to mix the mapped values using XOR and using sum -- both strategies give very similar (and very good) performances and collision rates. – Arek' Fu Oct 12 '12 at 17:16
I Googled here and there a bit and I'm left with the impression that a trie would be an overkill given the number of sequences that I need to handle. AFAIU, tries outperform hash tables for large sets. The number of my sequences varies a lot -- sometimes it's as few as 10, but it can occasionally go up to 10^6. Can you could suggest an existing simple C++ trie implementation? If I can get something simple running, that would give me an idea of the possible performance gain. – Arek' Fu Oct 12 '12 at 17:24
Surprisingly (for me), using 32-bit integers yields very similar collision rates and slightly poorer (!) performance. – Arek' Fu Oct 12 '12 at 17:31
@Arek'Fu You're probably right that a trie is overkill for a relatively small number of sequences, when the hash table collision rate is low. I can't suggest an implementation beyond what google yields, e.g., – Jim Balter Oct 12 '12 at 18:32
I decided to accept this answer because it came the closest to the algorithm that I ended up with, which is posted as a separate answer. – Arek' Fu Oct 15 '12 at 16:53

Here's a basic idea; feel free to modify it at will.

  1. Hashing an integer is just the identity.

  2. We use the formula from boost::hash_combine to get combine hashes.

  3. We sort the array to get a unique representative.


#include <algorithm>

std::size_t array_hash(int (&array)[12])
    int a[12];
    std::copy(array, array + 12, a);
    std::sort(a, a + 12);

    std::size_t result = 0;

    for (int * p = a; p != a + 12; ++p)
        std::size_t const h = *p; // the "identity hash"

        result ^= h + 0x9e3779b9 + (result << 6) + (result >> 2);

    return result;

Update: scratch that. You just edited the question to be something completely different.

If every number is at most 300, then you can squeeze the sorted array into 9 bits each, i.e. 108 bits. The "unordered" property only saves you an extra 12!, which is about 29 bits, so it doesn't really make a difference.

You can either look for a 128 bit unsigned integral type and store the sorted, packed set of integers in that directly. Or you can split that range up into two 64-bit integers and compute the hash as above:

uint64_t hash = lower_part + 0x9e3779b9 + (upper_part << 6) + (upper_part >> 2);

(Or maybe use 0x9E3779B97F4A7C15 as the magic number, which is the 64-bit version.)

share|improve this answer
Sounds interesting. But will this algorithm yield few collisions? Wouldn't it be better to have similar integers hashed to different sequences? – Arek' Fu Oct 11 '12 at 13:57
@Arek'Fu: I'm afraid I don't understand your question. Twelve 32-bit integers have 2^384 possible values, divided by 12! = 479001600. That still leaves about 2^355 possible distinct sequences of integers. Good luck finding a collision-free mapping to a single 32-bit integer. – Kerrek SB Oct 11 '12 at 14:00
All the integers are smaller than about 300 (see edited question) and I only have a few thousand sequences anyway. The number of available hashes is definitely sufficient for that. I'm rather afraid that my sequences will be mapped to a small subset of the available hashes, since the entropy of the sequences is rather low (all elements are small, no permutations allowed...). – Arek' Fu Oct 11 '12 at 14:06
Oooh, elegant (the second part). Have an upboat. – Konrad Rudolph Oct 11 '12 at 14:13
@KerrekSB: You might be right about the not sorting being a silly requirement but from an academic point of view there are hash functions that would work here. So far all those suggested so far have all been fairly poor in terms of avoiding collisions but that would be how you tell if two unordered sequences are equivalent. I'm just wondering if there are any better ones than we've come up with so far. :) – Chris Oct 11 '12 at 14:24

I would just use the sum function as the hash and see how far you come with that. This doesn’t take advantage of the non-repeating property of the data, nor of the fact that they are all < 300. On the other hand, it’s blazingly fast.

std::size_t hash(int (&arr)[12]) {
    return std::accumulate(arr, arr + 12, 0);

Since the function needs to be unaware of ordering, I don’t see a smart way of taking advantage of the limited range of the input values without first sorting them. If this is absolutely required, collision-wise, I’d hard-code a sorting network (i.e. a number of ifelse statements) to sort the 12 values in-place (but I have no idea how a sorting network for 12 values would look like or even if it’s practical).

EDIT After the discussion in the comments, here’s a very nice way of reducing collisions: raise every value in the array to some integer power before summing. The easiest way of doing this is via transform. This does generate a copy but that’s probably still very fast:

struct pow2 {
    int operator ()(int n) const { return n * n; }

std::size_t hash(int (&arr)[12]) {
    int raised[12];
    std::transform(arr, arr + 12, raised, pow2());
    return std::accumulate(raised, raised + 12, 0);
share|improve this answer
assuming the numbers are randomly distributed between 0 and 300 I would have thought simple addition would run the risk of having a lot of collisions (or at least proportionally high) around the expected sum (ie 150*12=1800ish). – Chris Oct 11 '12 at 14:10
You can reduce collisions via "spreading out" the hashes a bit. Multiply each value by itself once, twice or even three times to utilize more of the 32-bit range. – Deestan Oct 11 '12 at 14:15
@Chris Multiplication is no good since 0 is an allowed value (i.e. this method would lead to tons of collisions at 0). – Konrad Rudolph Oct 11 '12 at 14:18
They key thing is that with basic addition then increasing one number by one and reducing another by one will give the same hash. If you are squaring the numbers then this is no longer true. – Chris Oct 11 '12 at 14:33
If computations are vectorized, this should be fast enough. If not, probably it is worth to substitute squaring with table lookup (and pre-compute a 300-values table of squares/cubes/pseudo-random values). – Evgeny Kluev Oct 11 '12 at 18:17

You could toggle bits, corresponding to each of the 12 integers, in the bitset of size 300. Then use formula from boost::hash_combine to combine ten 32-bit integers, implementing this bitset.

This gives commutative hash function, does not use sorting, and takes advantage of the fact that elements never repeat.

This approach may be generalized if we choose arbitrary bitset size and if we set or toggle arbitrary number of bits for each of the 12 integers (which bits to set/toggle for each of the 300 values is determined either by a hash function or using a pre-computed lookup table). Which results in a Bloom filter or related structures.

We can choose Bloom filter of size 32 or 64 bits. In this case, there is no need to combine pieces of large bit vector into a single hash value. In case of classical implementation of Bloom filter with size 32, optimal number of hash functions (or non-zero bits for each value of the lookup table) is 2.

If, instead of "or" operation of classical Bloom filter, we choose "xor" and use half non-zero bits for each value of the lookup table, we get a solution, mentioned by Jim Balter.

If, instead of "or" operation, we choose "+" and use approximately half non-zero bits for each value of the lookup table, we get a solution, similar to one, suggested by Konrad Rudolph.

share|improve this answer
I'm not sure I understand the second part of your answer. Are you suggesting to use a 32-bit Bloom filter per sequence, and combine them using hash_combine? – Arek' Fu Oct 12 '12 at 17:28
@Arek'Fu: No, after using 32-bit Bloom filter per sequence there is nothing to combine, we already have a single 32-bit hash value. And I'm not suggesting any particular scheme. I just enumerate several possibilities to construct a hash function, satisfying your requirements (bitset of size 32 .. 300, different ways to set/toggle its bits, and using hash_combine only if bitset is larger than required hash size). As for which variant to choose, 64-bit or 32-bit bitset seems to be the fastest and "xor", "+" variants are, probably, better, than "or". – Evgeny Kluev Oct 12 '12 at 17:43

I accepted Jim Balter's answer because he's the one who came closest to what I eventually coded, but all of the answers got my +1 for their helpfulness.

Here is the algorithm I ended up with. I wrote a small Python script that generates 300 64-bit integers such that their binary representation contains exactly 32 true and 32 false bits. The positions of the true bits are randomly distributed.

import itertools
import random
import sys

def random_combination(iterable, r):
    "Random selection from itertools.combinations(iterable, r)"
    pool = tuple(iterable)
    n = len(pool)
    indices = sorted(random.sample(xrange(n), r))
    return tuple(pool[i] for i in indices)

mask_size = 64
mask_size_over_2 = mask_size/2

nmasks = 300


print 'HashType mask[' + str(nmasks) + '] = {'
for i in range(nmasks):
    combo = random_combination(xrange(mask_size),mask_size_over_2)
    mask = 0;
    for j in combo:
        mask |= (1<<j);
        print '\t' + str(mask) + suffix + ','
        print '\t' + str(mask) + suffix + ' };'

The C++ array generated by the script is used as follows:

typedef int_least64_t HashType;

const int maxTableSize = 300;

HashType mask[maxTableSize] = {
  // generated array goes here

inline HashType xorrer(HashType const &l, HashType const &r) {
  return l^mask[r];

HashType hashConfig(HashType *sequence, int n) {
  return std::accumulate(sequence, sequence+n, (HashType)0, xorrer);

This algorithm is by far the fastest of those that I have tried (this, this with cubes and this with a bitset of size 300). For my "typical" sequences of integers, collision rates are smaller than 1E-7, which is completely acceptable for my purpose.

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