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This is not a real-life question, it is just theory-crafting.

I have a big array which consists of elements like [1,140,245,123443], all integer or floats with low selectivity, and the number of unique values is ten times less than the size of the array. B*tree indexing is not good in this case.

I also tried to implement bitmap indexing, but in Ruby, binary operations are not so fast.

Are there any good algorithms for searching two-dimensional arrays of fixed size vectors?

And, the main question is, how do I convert the vector in value, where the conversion function has to be monotonic, so I can apply range queries such as:

(v[0]<10, v[2]>100, v[3]=32, 0.67*10^-8<v[4]<1.2154241410*10^-6)

the only idea i have is to create separate sorted indexes for each component of vector...binary search then and merge...but it is a bad idea because in the worst case scenario it will require O(N*N) operations...

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Oh, you want to find a row who's elements match a series of criteria? Is that it? –  Mooing Duck May 23 '12 at 23:44
    
yep, and i want to do that on ruby) –  Yuri Barbashov May 23 '12 at 23:45
    
You can always add some C to your Ruby :) –  Sergio Tulentsev May 24 '12 at 6:57
    
Have you looked at R-trees ? –  Frederick Cheung Jul 1 '12 at 16:09

2 Answers 2

Assuming that each "column" is vaguely evenly distributed in a known range, you could keep track of a series of buckets for each column, and a list of rows that satisfy the bucket. The number of buckets for each column can be the same, or different, it's totally arbitrary. More buckets is faster, but takes slightly more memory.

my table:
range:    {1to10} {1to4m}    {-2mto2m}
row1:     {7      3427438335 420645075}
row2:     {5      3862506151 -1555396554}
row3:     {1      2793453667 -1743457796}

buckets for column 1:
bucket{1-3} : row3
bucket{4-6} : row2
bucket{7-10} : row1

buckets for column 2:
bucket{1-2m} : 
bucket{2m-4m} : row1, row2, row4

buckets for column 3:
bucket{-2m--1m} : row2, row3
bucket{-1m-0} : 
bucket{0-1m} : 
bucket{1m-2m} : row1

Then, given a series of criteria: {v[0]<=5, v[2]>3*10^10}, we pull out the buckets that match that criteria:

 column 1:
v[0]<=5 matches buckets {1-3} and {4-6}, which is rows 2 and 3.
 column 2:
v[2]>3*10^10} matches buckets {2m-4m} and {4-6}, which is rows 1, 2 and 3.
 column 3:
"" matches all , which is rows 1, 2 and 3.

Now we know that the row(s) we're looking for meet all three criteria, so we list all the rows that are in the buckets that matched all the criteria, in this case, rows 2 and 3. At this point, the number of rows remaining will be small even for massive amounts of data, depending on the granularity of your buckets. You simply check each of the rows that is left at this point to see if they match. In this sample we see that row 2 matches, but row 3 doesn't.

This algorithm is technically O(n), but in practice, if you have large numbers of small buckets, this algorithm can be very fast.

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I don't think that it is a O(N) alg. For example how many operations do u need then u have find common elements in 2 Nsize arrays(worst case scenario max range queries) i think N*N... –  Yuri Barbashov May 24 '12 at 9:42
    
I dont understand what your saying. When I say it's O(N),, I meant N is the number of rows, and I'm ignoring the number of columns. If M is the number of columns, the algorithm is O(N*M), either way, it's the same algorithmic complexity as a linear search. –  Mooing Duck May 24 '12 at 14:26
    
You said that "Now we know that the row(s) we're looking for meet all three criteria"...sot we have 3 arrays of rows ids and we have to find their intersection. Intersection of 2 unordered arrays required size_of_first_array * size_of_first_array operations, so in the worst case scenario it will require N*N operations...And i don't think that buckets is good idea, it is better to use uniq values as keys and row ids as value. –  Yuri Barbashov May 24 '12 at 23:18
    
@YuriBarbashov: oh, right, good observation. Finding the intersection is O(N^M), but because of the buckets, it's O((N/P)^M) (where N is the number of rows, P the number of buckets, and M the number of columns. I'm not sure what you said about buckets. Each "bucket" is merely a vector of row pointers, and so doesn't take much space. –  Mooing Duck May 24 '12 at 23:39
    
Finding the intersection is O(M*N^2). I think it is better to store indexes like {1 => [1,434,55], 3 => [234,555,6643] ...123 => [34,533]} for queries like v[0] == 1, and not bad for range queries also –  Yuri Barbashov May 24 '12 at 23:52

Using an index :)

The basic idea is to turn the 2 dimensional array into a 1 dimensional sorted array(while keeping the original position) and apply binary search on the later.

This method works for any n dimensional array and is used widely by databases which can be seen as a n dimensional array with variable lengths.

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binary search only works when the array is sorted –  Luiggi Mendoza May 23 '12 at 23:18
    
yes, and as i said, the index array is a 1 dimensional sorted array :) –  Samy Arous May 23 '12 at 23:19
    
then, how can you index that kind of data? –  Luiggi Mendoza May 23 '12 at 23:20
    
simple data structure: value => list of positions in the original array, can be even a map. –  Samy Arous May 23 '12 at 23:22
    
the question is more about conversion of vector into value...because i need to find all array elements by range query, for example 0.67 * 10^-8 < v[4] < 1.2154241410*10^-6 –  Yuri Barbashov May 23 '12 at 23:32

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