1 | |
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2 | /* |
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3 | ########################################################## |
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4 | # # |
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5 | # !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! # |
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6 | # !! !! # |
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7 | # !! KEEP THIS CODE CONSISTENT WITH KERNELPY.PY !! # |
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8 | # !! !! # |
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9 | # !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! # |
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10 | # # |
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11 | ########################################################## |
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12 | */ |
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13 | |
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14 | #ifndef _PAR_BLOCK_ // protected block so we can include this code twice. |
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15 | #define _PAR_BLOCK_ |
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16 | |
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17 | typedef struct { |
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18 | #if MAX_PD > 0 |
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19 | int32_t pd_par[MAX_PD]; // id of the nth polydispersity variable |
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20 | int32_t pd_length[MAX_PD]; // length of the nth polydispersity weight vector |
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21 | int32_t pd_offset[MAX_PD]; // offset of pd weights in the value & weight vector |
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22 | int32_t pd_stride[MAX_PD]; // stride to move to the next index at this level |
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23 | #endif // MAX_PD > 0 |
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24 | int32_t pd_prod; // total number of voxels in hypercube |
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25 | int32_t pd_sum; // total length of the weights vector |
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26 | int32_t num_active; // number of non-trivial pd loops |
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27 | int32_t theta_par; // id of spherical correction variable |
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28 | } ProblemDetails; |
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29 | |
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30 | typedef struct { |
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31 | PARAMETER_TABLE; |
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32 | } ParameterBlock; |
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33 | #endif |
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34 | |
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35 | |
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36 | kernel |
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37 | void KERNEL_NAME( |
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38 | int32_t nq, // number of q values |
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39 | const int32_t pd_start, // where we are in the polydispersity loop |
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40 | const int32_t pd_stop, // where we are stopping in the polydispersity loop |
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41 | global const ProblemDetails *details, |
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42 | global const double *values, |
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43 | global const double *q, // nq q values, with padding to boundary |
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44 | global double *result, // nq+1 return values, again with padding |
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45 | const double cutoff // cutoff in the polydispersity weight product |
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46 | ) |
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47 | { |
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48 | // Storage for the current parameter values. These will be updated as we |
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49 | // walk the polydispersity cube. local_values will be aliased to pvec. |
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50 | ParameterBlock local_values; |
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51 | double *pvec = (double *)&local_values; |
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52 | |
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53 | // who we are and what element we are working with |
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54 | const int q_index = get_global_id(0); |
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55 | |
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56 | // Fill in the initial variables |
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57 | for (int i=0; i < NPARS; i++) { |
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58 | pvec[i] = values[2+i]; |
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59 | } |
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60 | |
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61 | // Monodisperse computation |
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62 | if (details->num_active == 0) { |
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63 | double norm, scale, background; |
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64 | // TODO: only needs to be done by one process... |
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65 | #ifdef INVALID |
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66 | if (INVALID(local_values)) { return; } |
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67 | #endif |
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68 | |
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69 | norm = CALL_VOLUME(local_values); |
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70 | scale = values[0]; |
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71 | background = values[1]; |
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72 | |
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73 | if (q_index < nq) { |
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74 | double scattering = CALL_IQ(q, q_index, local_values); |
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75 | result[q_index] = (norm>0. ? scale*scattering/norm + background : background); |
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76 | } |
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77 | return; |
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78 | } |
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79 | |
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80 | #if MAX_PD > 0 |
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81 | |
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82 | double this_result; |
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83 | |
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84 | //printf("Entering polydispersity from %d to %d\n", pd_start, pd_stop); |
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85 | |
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86 | global const double *pd_value = values+2+NPARS; |
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87 | global const double *pd_weight = pd_value+details->pd_sum; |
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88 | |
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89 | // need product of weights at every Iq calc, so keep product of |
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90 | // weights from the outer loops so that weight = partial_weight * fast_weight |
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91 | double pd_norm; |
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92 | double partial_weight; // product of weight w4*w3*w2 but not w1 |
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93 | double spherical_correction; // cosine correction for latitude variation |
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94 | double weight; // product of partial_weight*w1*spherical_correction |
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95 | int p0_par; |
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96 | int p0_length; |
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97 | int p0_offset; |
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98 | int p0_is_theta; |
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99 | int p0_index; |
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100 | |
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101 | // Number of elements in the longest polydispersity loop |
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102 | p0_par = details->pd_par[0]; |
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103 | p0_length = details->pd_length[0]; |
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104 | p0_offset = details->pd_offset[0]; |
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105 | p0_is_theta = (p0_par == details->theta_par); |
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106 | |
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107 | // Trigger the reset behaviour that happens at the end the fast loop |
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108 | // by setting the initial index >= weight vector length. |
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109 | p0_index = p0_length; |
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110 | |
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111 | // Default the spherical correction to 1.0 in case it is not otherwise set |
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112 | spherical_correction = 1.0; |
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113 | weight=1.0; |
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114 | |
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115 | // Since we are no longer looping over the entire polydispersity hypercube |
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116 | // for each q, we need to track the result and normalization values between |
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117 | // calls. This means initializing them to 0 at the start and accumulating |
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118 | // them between calls. |
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119 | pd_norm = pd_start == 0 ? 0.0 : result[nq]; |
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120 | |
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121 | if (q_index < nq) { |
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122 | this_result = pd_start == 0 ? 0.0 : result[q_index]; |
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123 | } |
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124 | |
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125 | // Loop over the weights then loop over q, accumulating values |
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126 | for (int loop_index=pd_start; loop_index < pd_stop; loop_index++) { |
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127 | // check if fast loop needs to be reset |
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128 | if (p0_index == p0_length) { |
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129 | //printf("should be here with %d active\n", num_active); |
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130 | |
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131 | // Compute position in polydispersity hypercube and partial weight |
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132 | partial_weight = 1.0; |
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133 | for (int k=1; k < details->num_active; k++) { |
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134 | int pk = details->pd_par[k]; |
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135 | int index = details->pd_offset[k] + (loop_index/details->pd_stride[k])%details->pd_length[k]; |
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136 | pvec[pk] = pd_value[index]; |
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137 | partial_weight *= pd_weight[index]; |
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138 | //printf("index[%d] = %d\n",k,index); |
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139 | if (pk == details->theta_par) { |
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140 | spherical_correction = fmax(fabs(cos(M_PI_180*pvec[pk])), 1.e-6); |
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141 | } |
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142 | } |
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143 | p0_index = loop_index%p0_length; |
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144 | //printf("\n"); |
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145 | } |
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146 | |
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147 | // Update parameter p0 |
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148 | weight = partial_weight*pd_weight[p0_offset + p0_index]; |
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149 | pvec[p0_par] = pd_value[p0_offset + p0_index]; |
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150 | if (p0_is_theta) { |
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151 | spherical_correction = fmax(fabs(cos(M_PI_180*pvec[p0_par])), 1.e-6); |
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152 | } |
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153 | p0_index++; |
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154 | //printf("\n"); |
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155 | |
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156 | // Increment fast index |
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157 | |
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158 | #ifdef INVALID |
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159 | if (INVALID(local_values)) continue; |
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160 | #endif |
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161 | |
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162 | // Accumulate I(q) |
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163 | // Note: weight==0 must always be excluded |
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164 | if (weight > cutoff) { |
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165 | // spherical correction has some nasty effects when theta is +90 or -90 |
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166 | // where it becomes zero. If the entirety of the correction |
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167 | weight *= spherical_correction; |
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168 | pd_norm += weight * CALL_VOLUME(local_values); |
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169 | |
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170 | const double scattering = CALL_IQ(q, q_index, local_values); |
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171 | this_result += weight*scattering; |
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172 | } |
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173 | } |
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174 | |
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175 | if (q_index < nq) { |
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176 | if (pd_stop >= details->pd_prod) { |
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177 | // End of the PD loop we can normalize |
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178 | double scale, background; |
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179 | scale = values[0]; |
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180 | background = values[1]; |
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181 | result[q_index] = (pd_norm>0. ? scale*this_result/pd_norm + background : background); |
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182 | } else { |
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183 | // Partial result, so remember it but don't normalize it. |
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184 | result[q_index] = this_result; |
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185 | } |
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186 | |
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187 | // Remember the updated norm. |
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188 | if (q_index == 0) result[nq] = pd_norm; |
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189 | } |
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190 | |
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191 | #endif // MAX_PD > 0 |
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192 | } |
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