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In an SIR infection simulation, a person can either be susceptible to (S), infected by (I) or recovered from (R) a disease. From time t to t+1, the infection status of person i from population P might develop as follows (left-hand table):

Persons 2 and 9 become infected, while person 6 recovers.

(Here, persons 2 and 9 become infected, while person 6 recovers. Note the status of a person can only develop in one direction from S → I → R.)

Now, I also want to group people by their status like in the right-hand table, much like an Excel PivotTable. I will need updated groupings after each time period in the simulation, and ideally each 'grouping array' is sorted (lists people in ascending order by index i).

As such, how can I recalculate/update these 3 grouping arrays in the fastest manner at each time period? (I have considered using atomic operations, but have been advised to avoid atomic operations as much as possible due to being slow.)

The simulation will be implemented in CUDA C, with each thread mapping onto each person within population P.

Many thanks.

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Would a single sorted vector with the starting points of each group be an acceptable solution ? –  Pavan Yalamanchili Jan 10 '13 at 4:30
    
Could you clarify by giving an example of what you mean with respect to the above? Thanks –  Milo Chen Jan 10 '13 at 4:48
    
In your example, t would be 1 2 7 9 10 3 5 6 4 8 followed by another vector with 1 6 9 as starting locations of S, I, R. t+1 would have 1 7 10 2 3 5 9 4 6 8, followed by another vector with 1 4 8 as starting locations. If required, we can have a mapping function from t to t+1 as 1 4 2 7 3 5 6 9 8 10 –  Pavan Yalamanchili Jan 10 '13 at 5:36
    
Yes, @Pavan. That would be an informationally equivalent and hence acceptable solution. Thanks. –  Milo Chen Jan 10 '13 at 6:32

1 Answer 1

up vote 2 down vote accepted
__global__
static void find_groups(int *locs, int *sorted, int num)
{
    int bid = blockIdx.y * gridDim.x + blockIdx.x;
    int tid = bid * blockDim.x + threadIdx.x;

    if (tid < num) {
        int curr = sorted[tid];
        if (tid == 0 || curr != sorted[tid - 1]) locs[curr] = tid;
    }

}

int main()
{
    int h_P0[N] = {0, 0, 1, 2, 1, 1, 0, 2, 0, 0};
    int h_P1[N] = {0, 1, 1, 2, 1, 2, 0, 2, 1, 0};

    thrust::host_vector<int> th_P0(h_P0, h_P0 + N);
    thrust::host_vector<int> th_P1(h_P1, h_P1 + N);

    thrust::device_vector<int> td_P0 = th_P0;
    thrust::device_vector<int> td_P1 = th_P1;

    thrust::device_vector<int> td_S0(N);
    thrust::device_vector<int> td_S1(N);

    thrust::sequence(td_S0.begin(), td_S0.end());
    thrust::sequence(td_S1.begin(), td_S1.end());

    thrust::stable_sort_by_key(td_P0.begin(), td_P0.end(), td_S0.begin());
    thrust::stable_sort_by_key(td_P1.begin(), td_P1.end(), td_S1.begin());

    thrust::device_vector<int> td_l0(3, -1); // Changed here
    thrust::device_vector<int> td_l1(3, -1); // And here

    int threads =  256;
    int blocks_x = (N + 256) / 256;
    int blocks_y = (blocks_x + 65535) / 65535;
    dim3 blocks(blocks_x, blocks_y);

    int *d_l0 = thrust::raw_pointer_cast(td_l0.data());
    int *d_l1 = thrust::raw_pointer_cast(td_l1.data());
    int *d_P0 = thrust::raw_pointer_cast(td_P0.data());
    int *d_P1 = thrust::raw_pointer_cast(td_P1.data());

    find_groups<<<blocks, threads>>>(d_l0, d_P0, N);
    find_groups<<<blocks, threads>>>(d_l1, d_P1, N);

    return 0;
}

The algorithm can be explained in simple steps.

  • Sort P0 by key
  • Sort P1 by key
  • The keys now contain the second table

Now pass P0 and P1 to find_groups kernel. Since you know there are only 3 groups, the thread where the group number changes from n-1 to n writes to global memory. thread 0 will always write 0, because that is the beginning of first group for all vectors.

I tried printing them out. This is what I get. Please keep in mind everything is 0 indexed.

Sorted
t    t+1
0    0
1    6
6    9
8    1
9    2
2    4
4    8
5    3
3    5
7    7
Ranges
Groups   t   t + 1
S    [0-4]   [0-2]
I    [5-7]   [3-6]
R    [8-9]   [7-9]

If you need access to the full code (including the code for printing), visit this link.

I am not sure if this is enough. But do let me know if I missed something here.

EDIT

Changed code to handle where a class is missing. Initialize the relevant vectors with -1. So when you encounter a starting point of -1, it would mean the class doesn't show up in that iteration.

share|improve this answer
    
Much appreciated. But what if P0 and P1 reside on the device to begin with? How to get thrust to operate on vectors that reside on the GPU? –  Milo Chen Jan 11 '13 at 16:34
1  
@MiloChen If you have the vectors already on the gpu, use thrust::device_vector<int>(d_ptr, d_ptr + N) –  Pavan Yalamanchili Jan 11 '13 at 17:23
    
Thanks - also, how do I pass a device vector to another function or give it global scope? –  Milo Chen Jan 12 '13 at 7:40
1  
You can use raw_pointer_cast and get the device vector out and use it like a regular device vector once the processing is done. –  Pavan Yalamanchili Jan 12 '13 at 7:43
    
Sure, but if I use raw_pointer_cast to get the raw device vector out and proceed make changes to the raw device vector, can I still continue to use the old thrust device vector container or will the two become 'out of sync'? –  Milo Chen Jan 12 '13 at 8:22

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