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I have a large, strictly increasing array (10 million integers) of offsets for another, larger, data array. No element in data is greater than 50. For example,

unsigned char data[70*1000*1000] = {0,2,1,1,0,2,1,4,2, ...};
unsigned int offsets[10*1000*1000] = {0,1,2,4,6,7,8, ...};

Then I would like to find the count of each element in a series of ranges that are not known until runtime, including only elements whose offsets are included in the offsets array. The endpoints of each range refer to indices of the data array, not to the offsets. For example, the data for the range [1,4] would be:

1 zero
1 one
1 two

The results include only one "one" because, while both data[3] and data[2] are equal to one, 3 is not included in offsets.

I need to compute these binned counts for several hundred ranges, some of which span the entire array. I considered iterating through the data array to store a cumulative sum for each bin and element, but the memory requirements would have been prohibitive. Here is a simple version of my implementation:

for(int i=0; i<range_count; i++){
    unsigned int j=0;
    while(j<range_starts[i]) pi++;
    while(j < 10000000 and data[j]<=range_ends[i]) bins[i][data[offsets[j++]]]++;
}

Is there any more efficient way to compute these counts?

share|improve this question
    
For one thing, if no value is above 50, you should be using unsigned char or unsigned short for this. int is typically 4-8 bytes, while short and char hover around 1-2 – Linuxios Nov 17 '12 at 21:14
    
Does offsets change at runtime? – Jørgen Fogh Nov 17 '12 at 23:38
    
Yes, both offsets and data are generated at runtime. – Andrew Buss Nov 18 '12 at 0:46
up vote 2 down vote accepted

While Ruben's answer did improve the time of the counts by about half, it remained too slow for my application. I include my solution here for the curious.

First, I optimized by setting elements in the data array not indexed by offsets to an unused value (51, for example). This removed the need to track offsets, because I could simply ignore the contents of the 51st bins when reporting results.

While I mentioned in the answer that storing cumulative counts for each bin and element would require too much memory, I was able to store the cumulative counts for each bin and range endpoint in linear time. Then, for each range, I calculated the occurrences of each element by subtracting the cumulative count for that element at the left endpoint of the range from the count at the right endpoint. Here is what I used:

struct range{
    unsigned int lowerbound;
    unsigned int upperbound;
    unsigned int bins[52];
};

struct endpoint{
    int n;
    unsigned int counts[50];
};

range ranges[N_RANGES];
endpoint endpoints[N_RANGES*2];
cumulative_counts[52];

// ... < data manipulation > ... 

endpoint* first_ep = &endpoints[0];
endpoint* last_ep = &endpoints[N_RANGES*2-1];
endpoint* next_ep;

for(next_ep=&endpoints[0];next_ep<last_ep;next_ep++){
    unsigned char* i = &data[next_ep->n];
    unsigned char* i_end = &data[(next_ep+1)->n];
    for(int j=0;j<51;j++) next_ep->counts[j] = cumulative_counts[j];
    while(i<i_end) cumulative_counts[*(i++)]++;
}
for(int i=0;i<51;i++) last_ep->sums[i] = cumulative_counts[i];
for(int i=0;i<N_RANGES;i++){
    while(first_ep->n != ranges[i].lowerbound) first_ep++;
    last_ep = first_ep+1;
    while(last_ep->n != ranges[i].upperbound) last_ep++;
    for(int j=0;j<51;j++) tests[i].bins[j] = end_ep->counts[j]-start_ep->counts[j];
    ranges[i].bins[data[last_ep->n]]++;
}
share|improve this answer
    
And... what is the speed up (assuming a fixed number of ranges on the same data)? – sehe Nov 19 '12 at 0:00
1  
The data manipulation, not shown in the listing, takes 5-10 seconds. Including this time, on a fixed set of data and over a fixed number of ranges, my original algorithm took about 90 seconds, Rubens' took 40, and my new algorithm takes about 15. – Andrew Buss Nov 19 '12 at 18:51
    
That's pretty cool. Thanks for revealing the numbers – sehe Nov 19 '12 at 22:49

It sounded like you already had your answer when you said your offsets are limited by 50 -- and they seem to be positive integers.

What about indexing a vector of vectors for each value of data, from 0 to 50, and then doing the other calculations would be way cheaper. This would be a sort of reverse index, from data to database entries.

So, you would have:

data[50][...] = {offsets related to the given data value}

The calculations would be performed checking, for each array, the initial element, and skipping from array to array, maintaining the position of the last element verified.

This would be linear on the number of elements of your entire array, times your search range, times the number of elements in the array "data" (0 to 50), which, considering you need to do this lots of times, wouldn't be the best approach.

Another approach, then, would be to use, for each data entry, from 0 to 50, a binary tree -- or even a hash structure --, so that you can now whether an database entry identifier belongs to the set of ids of the current data element (from 0 to 50). This would be, in the best case, linear on your search range, for each iteraction.

I've considered 50 as a constant on the analysis, so that searching only in the first data array, or in all the fifty entries of the array "data" would be the same. I'm not sure if this is a valid assumption, so the complexity would be: O(nr), with n equal to your data maximum range (0 to 50), and r equal to your search range (the number of entries in your data base). This is valid for each calculation, so that, considering i as the number of calculations, the complexity would be given as O(nri).

share|improve this answer
    
This did provide a noticeable increase in speed; thank you for the writeup. However, it was unfortunately still not fast enough. I was able to run the counts in linear time with a more memory-efficient method of caching results. I'll post an answer in a moment to explain. – Andrew Buss Nov 18 '12 at 17:29
1  
You're very welcome, and I really do enjoy thinking "algorithmically", any further problem like this, dont forget to bring it up (: Your solution uses dynamic programmimg, since the problem itself has an optimal structure -- you're able to overlap previous calculated solutions in order to obtain a next solution, and so on. Really nice you noticed this feature in your problem, and have been able to implement it. Regards! – Rubens Nov 18 '12 at 18:09

Could this work.

(Demo live at http://ideone.com/6rAj7k)

#include <algorithm>
#include <iostream>

unsigned char data[/*70*1000*1000*/]   = {0,2,1,1,0,2,1,4,2};
unsigned int offsets[/*10*1000*1000*/] = {0,1,2,4,6,7,8};

using namespace std;

void do_something_for_data_index(unsigned int data_index)
{
    std::cout << "visited: " << (int) data[data_index] << " (at index " << data_index << ")\n";
}

void foo(size_t first_data_index, size_t high_data_index)
{
    const auto low  = lower_bound(begin(offsets), end(offsets), first_data_index);
    const auto high = upper_bound(low           , end(offsets), high_data_index);
    for(auto offset_it = low; offset_it != high; ++offset_it)
    {
        do_something_for_data_index(*offset_it);
    }
}

int main()
{
    foo(1,4);
}

Output:

visited: 2 (at index 1)
visited: 1 (at index 2)
visited: 0 (at index 4)
share|improve this answer
    
Live demo at ideone.com/6rAj7k (using a C++0x compatibility workaround for Ideone.com) – sehe Nov 17 '12 at 21:59
    
I might have misunderstood this, but it does not seem to offer any algorithmic improvements. – Andrew Buss Nov 18 '12 at 17:58
    
@AndreBoos I apparently lost track of the prose in the question around "binned counts". My quick response did already sidestep the (gross) inefficiency of while(j<range_starts[i]) pi++; in the OP. Note that std::lower_bound has O(log n) rather than linear runtime. I realize that your own solution goes a lot further than this. Perhaps you can still exploit the 'strictly increasing' property of your offsets data. Cheers – sehe Nov 19 '12 at 0:03

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