# 3 integer key lookup in CUDA

I'd like to look up 3 integers (i.e. [1 2 3]) in a large data set of around a million points.

I'm currently using MATLAB's Map (hashmap), and for each point I'm doing the following:

``````key = sprintf('%d ', [1 2 3]);       % 23 us
% key = '1 2 3 '
result = lookup_map( key );          % 32 us
``````

This is quite time consuming though - 1 million points * 55 us = 55 seconds.

I'd like to move this to the GPU using CUDA, but I'm not sure of the best way of approaching this.

I could transfer four arrays - `key1, key2, key3, result`, and then perform binary search on the keys, but this would take 20 iterations (2^20 = 1048576) per key. Then I'd also have delays due to concurrent memory access from each thread.

Is there a data structure optimised for parallel (O(1), ideally) multiple key lookups in CUDA?

Q: What are the bounds of the three integers? And what data is looked up?

The integer keys can be between 0 and ~75,000 currently, but may be bigger (200,000+) in the future.

For the purposes of this question, we can assume that the `result` is an integer between 0 and the size of the data set.

Q: Why don't you pack all three numbers into one 64bit number (21 bits per number gives you a range of 0-2,097,152). And use that to index into a sparse array?

``````>> A = uint64(ones(10));
>> sparse_A = sparse(A)
??? Undefined function or method 'sparse' for input arguments of type 'uint64'.

>> A = int64(ones(10));
>> sparse_A = sparse(A)
??? Undefined function or method 'sparse' for input arguments of type 'int64'.
``````

It appears that my matlab doesn't support sparse arrays of 64-bit numbers.

In case this helps anyone else, I wrote a quick function to create a 64-bit key from three <2^21 unsigned integers:

``````function [key] = to_key(face)
key = uint64(bitsll(face(1), 42) + bitsll(face(2), 21) + rand(face(3),1));
end
``````

Q: From @Dennis - why not use logical indexing?

Let's test it!

``````% Generate a million random integers between 0 and 1000
>> M = int32(floor(rand(10000000,4)*1000));
% Find a point to look for
>> search =  M(500000,1:3)
search =
850         910         581
>> tic; idx = M(:,1)==search(1) & M(:,2)==search(2)&M(:,3)==search(3); toc;
Elapsed time is 0.089801 seconds.
>> M(idx,:)
ans =
850         910         581         726
``````

Unfortunately this takes 89801us, which is 1632x slower than my existing solution (55us)! It would take 2.5 hours to run this a million times!

We could try filtering `M` after each search:

``````>> tic; idx1=M(:,1)==search(1); N=M(idx1,:); idx2=N(:,2)==search(2); N2=N(idx2,:); idx3 = N2(:,3)==search(3); toc;
Elapsed time is 0.038272 seconds.
``````

This is a little faster, but still 696x slower than using Map.

I've been thinking about this some more, and I've decided to profile the speed of re-generating some of the data on the fly from a single key lookup - it might be faster than a 3 key lookup, given the potential problems with this approach.

-
As a sidenote, I wish the NVIDIA forums were still accessible - there was a lot of useful info there. –  Alex L Oct 15 '12 at 7:56
What are the bounds of the three integers? And what data is looked up? –  Skyler Saleh Oct 15 '12 at 8:16
Why don't you pack all three numbers into one 64bit number (21 bits per number gives you a range of 0-2,097,152). And use that to index into a sparse array? –  Skyler Saleh Oct 15 '12 at 8:58
@SkylerSaleh A `uint64`? I'll give it a shot - good idea! –  Alex L Oct 15 '12 at 9:05

I'm guessing this question is related to your previous question about tetrahedron faces. I still suggest you should try the `sparse` storage and sparse matrix-vector multiplication for that purpose:

``````size(spA)
ans =

1244810     1244810

tic;
vv = spA*v;
idx = find(vv);
toc;

Elapsed time is 0.106581 seconds.
``````

This is just timing analysis, see my previous answer about how to implement it in your case. Before you move to CUDA and do complicated stuff, check out simpler options.

-
Haha I've got a follower! The reason I moved away from using sparse matrices is that I go over the maximum integer size for my computer (2.1475e+009). If I've got a 75,000 tetra mesh, and therefore 75,000*4 faces, `v=sparse(ntetras*nfaces, 1)` throws the error "Sparse matrix sizes must be non-negative integers less than MAXSIZE as defined by COMPUTER" –  Alex L Oct 15 '12 at 8:52
Am I correct in thinking that if `ntetras*nfaces<=2.1475e+009`, and `nfaces=4*ntetras`, then `ntetras <= sqrt(2.1475e+009/4)` ~ 2317? –  Alex L Oct 15 '12 at 8:54
@AlexL Unrelated to your problem size. Matlab `sparse` has `long` indices and can handle systems with size of 2^64.. And anyway, 75000*4=300000 ... that's a small problem. Probably you have other issues. –  angainor Oct 15 '12 at 8:56
I'm sorry, I think I misunderstood your previous answer. So `v` is used just for the lookup, not to store all the data? –  Alex L Oct 15 '12 at 9:04
@AlexL Yes, that is the indices you search for. The sparse matrix is also not very large. O(number of tetras * number of faces per tetra). –  angainor Oct 15 '12 at 9:06

Given the attention this question has already received it feels like this answer is too simple, but why don't you just do it like this:

``````M=[1:6; 2:7; 3:8; 4:9]'; %Some matrix that contains key 1 2 3, corresponding value is 4
idx=M(:,1)==1&M(:,2)==2&M(:,3)==3;
M(idx,4)
``````

This should evaluate quite fast, even if `M` is 1 million x 4.

-
Cheers for your answer - I've tested it, and it runs ~1600 times slower than my existing solution. I've updated my question with my results, if you're interested! –  Alex L Oct 18 '12 at 8:14
The problem is that `M(:,1)==1` first creates a new array of just the first column, and then compares every value of this new array (not stopping when the result is found). This means that your method will loop 3 million times, plus have to create three new arrays! –  Alex L Oct 18 '12 at 8:17
Sorry, it appears I misunderstood your question. I assumed you wanted to find 1 point out of a million. Now i would like to ask whether you want to find 1 million points (that can occur multiple times?) Or for example each point exactly once? In that case i would consider some kind of sorting. –  Dennis Jaheruddin Oct 18 '12 at 10:02