1 | #!/usr/bin/env python |
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2 | # -*- coding: utf-8 -*- |
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3 | |
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4 | import numpy as np |
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5 | import pyopencl as cl |
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6 | |
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7 | from weights import GaussianDispersion |
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8 | from sasmodel import card, set_precision |
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9 | |
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10 | class GpuEllipse(object): |
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11 | PARS = { |
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12 | 'scale':1, 'radius_a':1, 'radius_b':1, 'sldEll':1e-6, 'sldSolv':0, 'background':0, 'axis_theta':0, 'axis_phi':0, |
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13 | } |
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14 | PD_PARS = ['radius_a', 'radius_b', 'axis_theta', 'axis_phi'] |
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15 | |
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16 | def __init__(self, qx, qy, dtype='float32'): |
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17 | |
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18 | ctx,_queue = card() |
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19 | src, qx, qy = set_precision(open('Kernel/Kernel-Ellipse.cpp').read(), qx, qy, dtype=dtype) |
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20 | self.prg = cl.Program(ctx, src).build() |
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21 | self.qx, self.qy = qx, qy |
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22 | |
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23 | #buffers |
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24 | mf = cl.mem_flags |
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25 | self.qx_b = cl.Buffer(ctx, mf.READ_ONLY | mf.COPY_HOST_PTR, hostbuf=self.qx) |
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26 | self.qy_b = cl.Buffer(ctx, mf.READ_ONLY | mf.COPY_HOST_PTR, hostbuf=self.qy) |
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27 | self.res_b = cl.Buffer(ctx, mf.WRITE_ONLY, qx.nbytes) |
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28 | self.res = np.empty_like(self.qx) |
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29 | |
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30 | def eval(self, pars): |
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31 | #b_n = radius_b # want, a_n = radius_a # want, etc |
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32 | _ctx,queue = card() |
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33 | self.res[:] = 0 |
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34 | cl.enqueue_copy(queue, self.res_b, self.res) |
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35 | radius_a, radius_b, axis_theta, axis_phi = \ |
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36 | [GaussianDispersion(int(pars[base+'_pd_n']), pars[base+'_pd'], pars[base+'_pd_nsigma']) |
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37 | for base in GpuEllipse.PD_PARS] |
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38 | |
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39 | radius_a.value, radius_a.weight = radius_a.get_weights(pars['radius_a'], 0, 10000, True) |
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40 | radius_b.value, radius_b.weight = radius_b.get_weights(pars['radius_b'], 0, 10000, True) |
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41 | axis_theta.value, axis_theta.weight = axis_theta.get_weights(pars['axis_theta'], -90, 180, False) |
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42 | axis_phi.value, axis_phi.weight = axis_phi.get_weights(pars['axis_phi'], -90, 180, False) |
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43 | |
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44 | #Perform the computation, with all weight points |
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45 | sum, norm, norm_vol, vol = 0.0, 0.0, 0.0, 0.0 |
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46 | size = len(axis_theta.weight) |
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47 | sub = pars['sldEll'] - pars['sldSolv'] |
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48 | real = np.float32 if self.qx.dtype == np.dtype('float32') else np.float64 |
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49 | |
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50 | #Loop over radius weight points |
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51 | for i in xrange(len(radius_a.weight)): |
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52 | #Loop over length weight points |
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53 | for j in xrange(len(radius_b.weight)): |
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54 | #Average over theta distribution |
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55 | vol += radius_a.weight[i]*radius_b.weight[j]*pow(radius_b.value[j], 2)*radius_a.value[i] |
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56 | norm_vol += radius_a.weight[i]*radius_b.weight[j] |
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57 | |
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58 | for k in xrange(len(axis_theta.weight)): |
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59 | #Average over phi distribution |
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60 | for l in xrange(len(axis_phi.weight)): |
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61 | #call the kernel |
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62 | self.prg.EllipsoidKernel(queue, self.qx.shape, None, real(radius_a.weight[i]), |
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63 | real(radius_b.weight[j]), real(axis_theta.weight[k]), |
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64 | real(axis_phi.weight[l]), real(pars['scale']), real(radius_a.value[i]), |
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65 | real(radius_b.value[j]), real(sub), real(axis_theta.value[k]), |
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66 | real(axis_phi.value[l]), self.qx_b, self.qy_b, self.res_b, |
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67 | np.uint32(self.qx.size), np.uint32(len(axis_theta.weight))) |
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68 | |
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69 | norm += radius_a.weight[i]*radius_b.weight[j]*axis_theta.weight[k]*axis_phi.weight[l] |
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70 | |
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71 | # Averaging in theta needs an extra normalization |
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72 | # factor to account for the sin(theta) term in the |
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73 | # integration (see documentation). |
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74 | |
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75 | # if size > 1: |
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76 | # norm /= math.asin(1.0) |
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77 | cl.enqueue_copy(queue, self.res, self.res_b) |
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78 | sum += self.res |
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79 | if vol != 0.0 and norm_vol != 0.0: |
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80 | sum *= norm_vol/vol |
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81 | |
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82 | return sum/norm+pars['background'] |
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83 | |
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84 | |
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85 | def demo(): |
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86 | from time import time |
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87 | import matplotlib.pyplot as plt |
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88 | |
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89 | #create qx and qy evenly spaces |
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90 | qx = np.linspace(-.02, .02, 128) |
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91 | qy = np.linspace(-.02, .02, 128) |
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92 | qx, qy = np.meshgrid(qx, qy) |
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93 | |
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94 | #saved shape of qx |
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95 | r_shape = qx.shape |
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96 | #reshape for calculation; resize as float32 |
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97 | qx = qx.flatten() |
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98 | qy = qy.flatten() |
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99 | |
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100 | #int main |
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101 | pars = EllipsoidParameters(.027, 60, 180, .297e-6, 5.773e-06, 4.9, 0, 90) |
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102 | |
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103 | t = time() |
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104 | result = GpuEllipse(qx, qy) |
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105 | result.x = result.ellipsoid_fit(qx, qy, pars, b_n=35, t_n=35, a_n=1, p_n=1, sigma=3, b_w=.1, t_w=.1, a_w=.1, p_w=.1) |
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106 | result.x = np.reshape(result.x, r_shape) |
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107 | tt = time() |
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108 | print("Time taken: %f" % (tt - t)) |
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109 | |
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110 | plt.pcolormesh(result.x) |
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111 | plt.show() |
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112 | |
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113 | |
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114 | if __name__ == "__main__": |
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115 | demo() |
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116 | |
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117 | |
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118 | |
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119 | |
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