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Given a large (~100 million) list of unsigned 32-bit integers, an unsigned 32-bit integer input value, and a maximum Hamming Distance, return all list members that are within the specified Hamming Distance of the input value.

Actual data structure to hold the list is open, performance requirements dictate an in-memory solution, cost to build the data structure is secondary, low cost to query the data structure is critical.


For a maximum Hamming Distance of 1 (values typically will be quite small)

And input: 

The values:

should match because there is only 1 position in which the bits are different.


should not match because 3 bit positions are different.

My thoughts so far:

For the degenerate case of a Hamming Distance of 0, just use a sorted list and do a binary search for the specific input value.

If the Hamming Distance would only ever be 1, I could flip each bit in the original input and repeat the above 32 times.

How can I efficiently (without scanning the entire list) discover list members with a Hamming Distance > 1.

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How about mutating the criteria by the expected hamming distance, a recurrent function can do that. Next step will be to get the union of the two list?. – XecP277 Jun 17 '11 at 18:45
Here's a recent paper on this problem: Large scale Hamming distance query processing. – hammar Jun 17 '11 at 18:51
up vote 59 down vote accepted

Question: What do we know about the Hamming distance d(x,y)?


  1. It is non-negative: d(x,y) ≥ 0
  2. It is only zero for identical inputs: d(x,y) = 0 ⇔ x = y
  3. It is symmetric: d(x,y) = d(y,x)
  4. It obeys the triangle inequality, d(x,z) ≤ d(x,y) + d(y,z)

Question: Why do we care?

Answer: Because it means that the Hamming distance is a metric for a metric space. There are algorithms for indexing metric spaces.

You can also look up algorithms for "spatial indexing" in general, armed with the knowledge that your space is not Euclidean but it is a metric space. Many books on this subject cover string indexing using a metric such as the Hamming distance.

Footnote: If you are comparing the Hamming distance of fixed width strings, you may be able to get a significant performance improvement by using assembly or processor intrinsics. For example, with GCC (manual) you do this:

static inline int distance(unsigned x, unsigned y)
    return __builtin_popcount(x^y);

If you then inform GCC that you are compiling for a computer with SSE4a, then I believe that should reduce to just a couple opcodes.

Edit: According to a number of sources, this is sometimes/often slower than the usual mask/shift/add code. Benchmarking shows that on my system, a C version outperform's GCC's __builtin_popcount by about 160%.

Addendum: I was curious about the problem myself, so I profiled three implementations: linear search, BK tree, and VP tree. Note that VP and BK trees are very similar. The children of a node in a BK tree are "shells" of trees containing points that are each a fixed distance from the tree's center. A node in a VP tree has two children, one containing all the points within a sphere centered on the node's center and the other child containing all the points outside. So you can think of a VP node as a BK node with two very thick "shells" instead of many finer ones.

The results were captured on my 3.2 GHz PC, and the algorithms do not attempt to utilize multiple cores (which should be easy). I chose a database size of 100M pseudorandom integers. Results are the average of 1000 queries for distance 1..5, and 100 queries for 6..10 and the linear search.

  • Database: 100M pseudorandom integers
  • Number of tests: 1000 for distance 1..5, 100 for distance 6..10 and linear
  • Results: Average # of query hits (very approximate)
  • Speed: Number of queries per second
  • Coverage: Average percentage of database examined per query
                -- BK Tree --   -- VP Tree --   -- Linear --
Dist    Results Speed   Cov     Speed   Cov     Speed   Cov
1          0.90 3800     0.048% 4200     0.048%
2         11     300     0.68%   330     0.65%
3        130      56     3.8%     63     3.4%
4        970      18    12%       22    10%
5       5700       8.5  26%       10    22%
6       2.6e4      5.2  42%        6.0  37%
7       1.1e5      3.7  60%        4.1  54%
8       3.5e5      3.0  74%        3.2  70%
9       1.0e6      2.6  85%        2.7  82%
10      2.5e6      2.3  91%        2.4  90%
any                                             2.2     100%

In your comment, you mentioned:

I think BK-trees could be improved by generating a bunch of BK-trees with different root nodes, and spreading them out.

I think this is exactly the reason why the VP tree performs (slightly) better than the BK tree. Being "deeper" rather than "shallower", it compares against more points rather than using finer-grained comparisons against fewer points. I suspect that the differences are more extreme in higher dimensional spaces.

A final tip: leaf nodes in the tree should just be flat arrays of integers for a linear scan. For small sets (maybe 1000 points or fewer) this will be faster and more memory efficient.

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Hooray! My 10k rep is here ;-) – Dietrich Epp Jun 17 '11 at 19:15
I considered the metric space, but I dismissed it when I realized how close everything is together. Clearly, BK-tree is just brute force, and so it won't be an optimization. M-tree and VP-tree won't be an optimization either because of how close everything is together. (A hamming distance of 4 corresponds to a distance of two, whereas a hamming distance of 2 corresponds to a distance of root two.) – Neil G Jun 17 '11 at 19:28
I don't think cover tree will help either because of the 2^i distance requirement. It's a nice idea, but I don't think it helps with this problem. – Neil G Jun 17 '11 at 20:32
Hamming distance for fixed-size integers is identical to the L1 norm, if you consider integers to be strings of bits. Otherwise, the "standard" L1 norm between two strings is the sum of positive distances between the elements. – Mokosha Mar 31 '14 at 22:08
@portforwardpodcast: Sure thing! – Dietrich Epp Oct 3 '14 at 5:19

How about sorting the list and then doing a binary search in that sorted list on the different possible values within you Hamming Distance?

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For a hamming distance of 1, that is reasonable since there are 32 permutations of the original input (flip each bit in the original input once). For a hamming distance of 2, there are many more permuted input values that would have to be searched for. – Eric J. Jun 17 '11 at 18:48
1024+32+1 searches is not a terribly large number of binary searches. Even 32^3 searches is not that many. – τεκ Jun 17 '11 at 19:05
@EricJ - There are, however, 100m pieces of data. It's still reasonable - given that the poster states "cost to build data structure is secondary" - for a reasonable hamming distance. – borrible Jun 17 '11 at 19:06
See bit-string-nearest-neighbour-searching, which uses various sorts, then binary search. – denis Jan 25 at 10:35

You could pre-compute every possible variation of your original list within the specified hamming distance, and store it in a bloom filter. This gives you a fast "NO" but not necessarily a clear answer about "YES."

For YES, store a list of all the original values associated with each position in the bloom filter, and go through them one at a time. Optimize the size of your bloom filter for speed / memory trade-offs.

Not sure if it all works exactly, but seems like a good approach if you've got runtime RAM to burn and are willing to spend a very long time in pre-computation.

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Isn't no going to be very unlikely? 2 percent of the entries are present. – Neil G Jun 17 '11 at 19:03

One possible approach to solve this problem is using a Disjoint-set data structure. The idea is merge list members with Hamming distance <= k in the same set. Here is the outline of the algorithm:

  • For each list member calculate every possible value with Hamming distance <= k. For k=1, there are 32 values (for 32-bit values). For k=2, 32 + 32*31/2 values.

    • For each calculated value, test if it is in the original input. You can use an array with size 2^32 or a hash map to do this check.

    • If the value is in the original input, do a "union" operation with the list member.

    • Keep the number of union operations executed in a variable.

You start the algorithm with N disjoint sets (where N is the number of elements in the input). Each time you execute an union operation, you decrease by 1 the number of disjoint sets. When the algorithm terminates, the disjoint-set data structure will have all the values with Hamming distance <= k grouped in disjoint sets. This disjoint-set data structure can be calculated in almost linear time.

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