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I am looking for a cuda based parallel algorithm that performs key based aggregation. Input: a vector of key, values. For simplicity assume that key is integer. Vector can be large - 16 million pairs. Values are a small array of floats with constant small size i.e. 40 values.

Required aggregation: For each key, each value is the result of an operator (i.e. sum or max) for that value on all the records with same key.

Example: {1,{2,3,4}} means key=1, values={2,3,4}

Input:  
{ {1,{2,3,4}},
  {3,{4,5,8}},
  {1,{2,3,4}},
  {1,{2,7,8}},
  {2,{4,5,8}},
  {1,{4,5,8}},
  {3,{2,5,5}}
}

Output for "sum" operator:
{ {1,{10,18,24}},
  {2,{4,5,8}},
  {3,{6,10,13}}
}

Output for "max" operator:
{ {1,{4,7,8}},
  {2,{4,5,8}},
  {3,{4,5,8}}
}

If it is simpler the output KEYS don't have to be sorted (the order of values must stay), so the following is ok as well

"sum" operator:
{ {1,{10,18,24}},
  {3,{6,10,13}},
  {2,{4,5,8}}
}

Trying to use thrust with Sort_by_key, Reduce_by_key works but is too slow because thrust operations cant work in parallel between operations.

As requested by Robert I am adding the code after some cleaning. It is quite long which is why I did not do it till now.

/*
 * aggregation with multiple value vectors
 *
*/
#include <thrust/transform_reduce.h>
#include <thrust/device_vector.h>
#include <thrust/host_vector.h>
#include <thrust/iterator/zip_iterator.h>
#include <thrust/inner_product.h>
#include <thrust/reduce.h>
#include <thrust/sort.h>
#include <thrust/experimental/cuda/pinned_allocator.h>

#include <map>

#include <cuda_runtime_api.h>

#include<iostream>
#include <sys/time.h>


typedef int    KEY_TYPE;
typedef float  VALUE_TYPE;

typedef thrust::host_vector<KEY_TYPE, thrust::experimental::cuda::pinned_allocator<KEY_TYPE> > thrust_key_host_vector;
typedef thrust::host_vector<VALUE_TYPE, thrust::experimental::cuda::pinned_allocator<VALUE_TYPE> > thrust_val_host_vector;
typedef thrust::host_vector<int, thrust::experimental::cuda::pinned_allocator<int> > thrust_idx_host_vector;

struct values
{
private:
        static const int vsize = 2;

public:
        VALUE_TYPE v[vsize];

        // Defualt ctor
        values() {
                for (int i=0; i< vsize; i++) {
                        v[i] = 0;
                }
        }

        // Copy ctor
        values(const values& other) {
                for (int i=0; i< vsize; i++) {
                        v[i] = other.v[i];
                }
        }

        values (const std::vector<VALUE_TYPE>& val_vec) {
                for (int i=0; i< vsize; i++) {
                        v[i] = val_vec[i];
                }
        }

        __host__ __device__
        int  get_size() const {
                return vsize;
        }

        __host__ __device__
        values& operator=(const values &rhs) {
                for (int i=0; i< vsize; i++) {
                        v[i] = rhs.v[i];
                }
                return *this;
        }

        __host__ __device__
        bool operator==(const values &other) const {
                 return thrust::equal(v, v+vsize, other.v);
        }

        __host__ __device__
        bool operator!=(const values &other) const {
                 return !(*this == other);
        }

        friend std::ostream& operator<<(std::ostream& output, const values& v);
};


std::ostream& operator<<(std::ostream& output, const values& vl) {
        output << "{";
        if (vl.get_size() > 0) {
                output << vl.v[0];
        }
        for (int i = 1; i < vl.get_size(); i++) {
                output << "," << vl.v[i];
        }
        output << "}" << std::endl;
        return output;  // for multiple << operators.
}

int main(void) {

        // size of input
        const int N = 1 << 24;

        // Number of different keys in the input - affects performance
        const int NUM_KEYS = 50000;

        // A value that affects the values variation - used in initialization
        const int MAX_MEASUREMENT = 37;

        // input host vectors in pinned memory
        thrust_key_host_vector h_key(N);
        thrust_val_host_vector h_val0(N);
        thrust_val_host_vector h_val1(N);

        // output vectors
        thrust::host_vector<KEY_TYPE> h_key_output(N);

        thrust::host_vector<VALUE_TYPE> h_val_output0(N);
        thrust::host_vector<VALUE_TYPE> h_val_output1(N);


        // initialize data
        for (int i=0; i < N; i++) {
                h_key[i] = (KEY_TYPE)(i % NUM_KEYS);
                h_val0[i] = (VALUE_TYPE)(i % MAX_MEASUREMENT);
                h_val1[i] = (VALUE_TYPE)(i*17 % MAX_MEASUREMENT);
                if (N <= 30) { // debug print for small tests
                        std::cout << "h_key[" << i << "] =" << h_key[i] << " , "
                                  << "h_val0[" << i << "] =" << h_val0[i] << " , "
                                  << "h_val1[" << i << "] =" << h_val1[i] << std::endl;
                }
        }

        // *************************************************************
        // CPU simulation running on the HOST using std::map
        // *************************************************************
        std::cout << std::endl<< std::endl
                  << "-----------------------------------------------" << std::endl
                  << "Starting CPU aggregation of " << N << " records" << std::endl
                  << "-----------------------------------------------" << std::endl << std::endl ;

        // start timer
        struct timeval cpu_start, cpu_stop;
        gettimeofday(&cpu_start, NULL);

        // create the map
        std::map<KEY_TYPE,values> aggr_map;
        int key;

        // Perform aggregation by key
        std::map<KEY_TYPE,values>::iterator itr;
        values val;

        for (int i=0; i < N; i++) {
                key = h_key[i];
                if ((itr = aggr_map.find(key)) == aggr_map.end()) {
                        val.v[0] = h_val0[i];
                        val.v[1] = h_val1[i];
                        aggr_map.insert(std::pair<KEY_TYPE,values>(key,val)); // first time - create and initialize
                }
                else {
                        (*itr).second.v[0] += h_val0[i];
                        (*itr).second.v[1] += h_val1[i];
                }
        }

        // Extract the results from the map into a results vector
        std::vector<std::pair<KEY_TYPE,values> > res_vec(aggr_map.size());
        itr = aggr_map.begin();
        while (itr++ != aggr_map.end()) {
                res_vec.push_back(*itr);
        }

        // stop timer
        gettimeofday(&cpu_stop, NULL);

        long int seconds = cpu_stop.tv_sec - cpu_start.tv_sec;
        long int useconds = cpu_stop.tv_usec - cpu_start.tv_usec;
        double cpu_runtime = (double(seconds) * 1000 + double(useconds)/1000); // convert to ms

        printf("CPU runtime: %lg ms\n", cpu_runtime);

        // *************************************
        // GPU base aggregations
        // *************************************

        std::cout << std::endl << std::endl
                  << "--------------------------------------------------" << std::endl
                  << "Starting GPGPU aggregation of " << N << " records" << std::endl
                  << "--------------------------------------------------" << std::endl << std::endl ;

        // set timers to measure the elapsed time
        cudaEvent_t start, stop;

        cudaEventCreate(&start);
        cudaEventCreate(&stop);

        cudaEventRecord(start);

        // copy data to device
        thrust::device_vector<KEY_TYPE> d_key = h_key;

        // prepare working vectors on device
        thrust::device_vector<VALUE_TYPE> d_val(N);
        thrust::device_vector<VALUE_TYPE> d_sorted(N);
        thrust::device_vector<KEY_TYPE> d_key_output(d_key.size());
        thrust::device_vector<VALUE_TYPE> d_val_output(d_val.size());
        thrust::pair<thrust::device_vector<KEY_TYPE>::iterator, thrust::device_vector<VALUE_TYPE>::iterator> end_of_results;

        // prepare index to be used for multiple values
        size_t key_size = d_key.size();
        thrust::device_vector<int> d_indices(key_size);
        thrust::sequence(d_indices.begin(),d_indices.end());

        // sort by key
        thrust::sort_by_key(d_key.begin(), d_key.end(), d_indices.begin());

        // Iteration 1
        // copy one values vector from host
        d_val = h_val0;

        // gather values by the sorted indices
        thrust::gather(d_indices.begin(), d_indices.end(), d_val.begin(), d_sorted.begin());

        // reduce by keys
        end_of_results =
                thrust::reduce_by_key(d_key.begin(), d_key.end(), d_sorted.begin(),
                                        d_key_output.begin(), d_val_output.begin());

        // copy FINAL reduces results back to host
        // ONLY ON FIRST iteration - copy the keys. they do not change
        thrust::copy(d_key_output.begin(), end_of_results.first, h_key_output.begin());
        thrust::copy(d_val_output.begin(), end_of_results.second, h_val_output0.begin());

        // Iteration 2 - (Explicit second iteration. Need to change to work in a loop)
        // copy one values vector from host
        d_val = h_val1;

        // gather values by the sorted indices
        thrust::gather(d_indices.begin(), d_indices.end(), d_val.begin(), d_sorted.begin());

        // reduce by keys
        end_of_results =
                thrust::reduce_by_key(d_key.begin(), d_key.end(), d_sorted.begin(),
                                        d_key_output.begin(), d_val_output.begin());

        // copy FINAL reduces results back to host
        thrust::copy(d_val_output.begin(), end_of_results.second, h_val_output1.begin());

        // stop the timer
        cudaEventRecord(stop);
        cudaEventSynchronize(stop);

        // print timing
        float total_gpu_runtime = 0;
        cudaEventElapsedTime(&total_gpu_runtime, start, stop);
        printf("GPGPU runtime  %.2f ms\n", total_gpu_runtime, N);
        printf("\nCPU time / GPGPU time = %.2f\n", cpu_runtime / total_gpu_runtime);

        // *************************************
        // verify results
        int mismatches = 0;
        for (int i=0; (i < NUM_KEYS) && (mismatches < 40) && (i < N); i++) {
                if ((aggr_map[i].v[0] != h_val_output0[h_key_output[i]]) ||
                    (aggr_map[i].v[1] != h_val_output1[h_key_output[i]])) {
                        ++mismatches;
                        std::cout << "Results mismatch: aggr_map[" << i << "]=" << aggr_map[i]
                                  << " , h_val_output0[" << h_key_output[i] << "]=" << h_val_output0[h_key_output[i]]
                                  << " , h_val_output1[" << h_key_output[i] << "]=" << h_val_output1[h_key_output[i]]
                                  << std::endl;
                }
        }

        return 0;
}
share|improve this question
    
What you mean by "Reduce_by_key works but is too slow because thrust operations cant work in parallel between operations." – talonmies Feb 19 '13 at 10:41
    
Are there many values with the same key? If not you can use atomic operations without notable slowdown. – stuhlo Feb 19 '13 at 10:43
    
Reduce_by_key works - means that that it does compute a correct answer. When the values are defined as an array of floats it takes a long time to compute the results. Theoretically I can work with multiple value vectors and compute them in parallel using multiple parallel Reduce_by_key. But Reduce_by_key is a thrust command and you can't run multiple thrust commands in parallel, they all use stream 0. – yoavs Feb 19 '13 at 14:30
    
There may be many values with same key (can be millions) depend on the data. – yoavs Feb 19 '13 at 14:31
    
Can't you pass your own reduction operator to thrust::reduce_by_key, where your reduction operator can reduce arrays instead of scalars? – Tom Feb 19 '13 at 17:42

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