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#include "meanshift_kernels.h"
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#include <stdio.h>
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#include <stdlib.h>
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__global__ void calculate_kernel_matrix_kernel(Matrix shifted_points, Matrix original_points,
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double deviation, Matrix kernel_matrix){
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// each thread calculates one element of kernel_matrix
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int row = blockIdx.x * blockDim.x + threadIdx.x;
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int col = blockIdx.y * blockDim.y + threadIdx.y;
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// performs calculations only if thread's indexes are within matrix bounds
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if (row * kernel_matrix.width + col >= kernel_matrix.width * kernel_matrix.height){
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return;
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}
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int dimensions = shifted_points.width;
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// calculate distance
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double sum = 0, dif;
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for (int i=0; i<dimensions; i++){
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dif = shifted_points.elements[row * dimensions + i]
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- original_points.elements[col * dimensions + i];
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sum += dif * dif;
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}
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double distance = sqrt(sum);
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double deviation_square = deviation*deviation;
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if (distance < deviation_square){
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// computes kernel matrix
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double pow = ((-1)*(distance * distance))/(2*(deviation_square));
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kernel_matrix.elements[row * kernel_matrix.width + col] = exp(pow);
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} else {
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kernel_matrix.elements[row * kernel_matrix.width + col] = 0;
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}
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if (row == col){
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kernel_matrix.elements[row * kernel_matrix.width + col] += 1;
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}
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}
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__global__ void denominator_kernel(Matrix denominator, Matrix kernel_matrix){
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// each thread computes one element of denominator_kernel
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// by accumulating results into cell_value
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double cell_value = 0;
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int row = blockIdx.x * blockDim.x + threadIdx.x;
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// performs calculations only if thread's indexes are within matrix bounds
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if (row >= denominator.height){
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return;
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}
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for (int column = 0; column < kernel_matrix.width; ++column){
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cell_value += kernel_matrix.elements[row * kernel_matrix.width + column];
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}
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denominator.elements[row] = cell_value;
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}
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__global__ void shift_points_kernel(Matrix original_points, Matrix kernel_matrix,
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Matrix shifted_points, Matrix new_shift, Matrix denominator, Matrix mean_shift_vector){
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int BLOCK_SIZE = blockDim.y;
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int block_row = blockIdx.x;
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int block_col = blockIdx.y;
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// each thread computes one element of new_shift by accumulating results into cell_value
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double cell_value = 0;
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// Thread row and column within sub_new_shift
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int row = threadIdx.x;
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int col = threadIdx.y;
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// performs calculations only if thread's indexes are within matrix bounds
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if (BLOCK_SIZE * block_row >= new_shift.height || BLOCK_SIZE * block_col >= new_shift.width){
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return;
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}
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// each thread block computes one sub-matrix sub_new_shift of C
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Matrix sub_new_shift = GetSubMatrix(new_shift, block_row, block_col, BLOCK_SIZE);
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// dynamically allocated shared memory used to store sub_kernel_matrix and sub_original_points
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// respectively
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extern __shared__ double joined_shared_memory[];
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// first part of the allocated memory is used for s_sub_kernel_matrix and second part is used
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// for s_sub_original_points
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double *s_sub_kernel_matrix = &(joined_shared_memory[0]);
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double *s_sub_original_points = &(joined_shared_memory[BLOCK_SIZE * BLOCK_SIZE]);
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// loops over all the sub-matrices of kernel_matrix and original_points that are required to
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// compute sub_new_shift, multiplies each pair of sub-matrices and accumulates the results
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for (int sub_matrix_index = 0; sub_matrix_index < (kernel_matrix.width / BLOCK_SIZE); ++sub_matrix_index) {
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// gets sub-matrix sub_kernel_matrix of kernel_matrix
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Matrix sub_kernel_matrix = GetSubMatrix(kernel_matrix, block_row, sub_matrix_index, BLOCK_SIZE);
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// gets sub-matrix sub_original_points of original_points
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Matrix sub_original_points = GetSubMatrix(original_points, sub_matrix_index, block_col, BLOCK_SIZE);
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// loads s_sub_kernel_matrix and s_sub_original_points from device global memory to shared
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//memory, each thread loads one element of each sub-matrix
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s_sub_kernel_matrix[row * BLOCK_SIZE + col] =
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sub_kernel_matrix.elements[row * sub_kernel_matrix.stride + col];
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s_sub_original_points[row * BLOCK_SIZE + col] =
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sub_original_points.elements[row * sub_original_points.stride + col];
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// synchronizes to make sure the sub-matrices are loaded before starting the computation
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__syncthreads();
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// multiplies sub_kernel_matrix and sub_original_points
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for (int element_index = 0; element_index < BLOCK_SIZE; ++element_index){
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cell_value += s_sub_kernel_matrix[row * BLOCK_SIZE + element_index] *
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s_sub_original_points[element_index * BLOCK_SIZE + col];
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}
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// synchronizes to make sure that the preceding computation is done before loading two new
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// sub-matrices of kernel_matrix and original_points in the next iteration
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__syncthreads();
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}
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// new_shift elements are calculated by dividing with the denominator
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sub_new_shift.elements[row * sub_new_shift.stride + col] =
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cell_value / denominator.elements[block_row * BLOCK_SIZE + row];
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int cell_row = block_row * BLOCK_SIZE + row;
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int cell_col = block_col * BLOCK_SIZE + col;
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mean_shift_vector.elements[cell_row * mean_shift_vector.stride + cell_col] =
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sub_new_shift.elements[row * sub_new_shift.stride + col] -
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shifted_points.elements[cell_row * shifted_points.stride + cell_col];
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}
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// Get the BLOCK_SIZExBLOCK_SIZE sub-matrix Asub of A that is
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// located col sub-matrices to the right and row sub-matrices down
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// from the upper-left corner of A
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__device__ Matrix GetSubMatrix(Matrix A, int row, int col, int BLOCK_SIZE){
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Matrix Asub;
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Asub.width = BLOCK_SIZE;
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Asub.height = BLOCK_SIZE;
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Asub.stride = A.stride;
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Asub.elements = &(A.elements[A.stride * BLOCK_SIZE * row + BLOCK_SIZE * col]);
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return Asub;
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}
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