| 1 | __kernel void EllipsoidKernel(__global const real *qx, __global const real *qy, __global const int *place, __global const real *array, |
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| 2 | __global real *final, const real scale, const real sub, const int length, const int size)//, __local real *poly) |
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| 3 | { |
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| 4 | //__local real rada, radaw, radb, radbw, th, thw, ph, phw; |
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| 5 | |
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| 6 | __local real rada; |
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| 7 | int uno=0; int dos=1; int count = 0; |
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| 8 | int l = get_local_id(0); |
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| 9 | for(int j = 0; j < 4; j++) |
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| 10 | { |
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| 11 | for(int i = place[uno]; i < place[dos]; i++) |
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| 12 | { |
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| 13 | rada[count] = array[i] |
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| 14 | radaw[count] = array[] |
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| 15 | } |
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| 16 | uno+=2; |
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| 17 | dos+=2; |
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| 18 | count = 0; |
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| 19 | } |
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| 20 | |
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| 21 | |
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| 22 | int i = get_global_id(0); |
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| 23 | if(i < length){ |
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| 24 | //do local mem? |
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| 25 | real sum=0.0; real vol=0.0; real norm_vol=0.0; real norm=0.0; |
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| 26 | |
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| 27 | for(int a = 0; a < place[0]; a++) //radius_a values |
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| 28 | { |
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| 29 | real radius_a = array[a]; |
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| 30 | real radius_a_weight = array[a+place[0]]; |
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| 31 | for(int b = place[1]; b < place[2]; b++) //radius_b values |
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| 32 | { |
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| 33 | real radius_b = array[b]; |
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| 34 | real radius_b_weight = array[b+place[2]]; |
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| 35 | for(int t = place[3]; t < place[4]; t++) //Axis_theta values |
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| 36 | { |
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| 37 | real axis_theta = array[t]; |
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| 38 | real axis_theta_weight = array[t+place[4]]; |
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| 39 | for(int p = place[5]; p < place[6]; p++) //axis_phi values |
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| 40 | { |
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| 41 | real axis_phi = array[p]; |
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| 42 | real axis_phi_weight = array[p+place[6]]; |
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| 43 | |
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| 44 | real ret = 0; |
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| 45 | real q = sqrt(qx[i]*qx[i] + qy[i]*qy[i]); |
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| 46 | real pi = 4.0*atan(1.0); |
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| 47 | real theta = axis_theta*pi/180.0; |
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| 48 | real cos_val = cos(theta)*cos(axis_phi*pi/180.0)*(qx[i]/q) + sin(theta)*(qy[i]/q); |
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| 49 | |
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| 50 | real arg = q*radius_b*sqrt(1.0+(cos_val*cos_val*(((radius_a*radius_a/(radius_b*radius_b))-1.0)))); |
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| 51 | if(arg == 0.0){ |
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| 52 | ret = 1.0/3.0; |
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| 53 | } |
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| 54 | else{ |
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| 55 | ret = (sin(arg)-arg*cos(arg))/(arg*arg*arg); |
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| 56 | } |
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| 57 | ret*=ret*9.0*sub*sub*4.0/3.0*acos(-1.0)*radius_b*radius_b*radius_a*scale*(1.0e8); |
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| 58 | real _ptvalue = radius_a_weight*radius_b_weight*axis_theta_weight*radius_a*axis_phi_weight*ret*pow(radius_b, 2); |
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| 59 | if(size > 1){ |
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| 60 | _ptvalue *= fabs(cos(axis_theta*pi/180.0)); |
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| 61 | } |
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| 62 | |
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| 63 | sum += _ptvalue; |
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| 64 | vol += radius_a_weight*radius_b_weight*pow(radius_b, 2)*radius_a; |
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| 65 | norm_vol += radius_a_weight*radius_b_weight; |
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| 66 | norm += radius_a_weight*radius_b_weight*axis_theta_weight*axis_phi_weight; |
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| 67 | } |
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| 68 | } |
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| 69 | } |
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| 70 | } |
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| 71 | |
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| 72 | if(size > 1){ |
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| 73 | norm /= asin(1.0); |
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| 74 | } |
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| 75 | if(vol != 0.0 && norm_vol != 0.0){ |
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| 76 | sum *= norm_vol/vol; |
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| 77 | } |
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| 78 | |
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| 79 | final[i] = sum/norm; |
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| 80 | } |
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| 81 | } |
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