1 | #!/usr/bin/env python |
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2 | """ Volume Canvas |
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3 | |
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4 | Simulation canvas for real-space simulation of SAS scattering intensity. |
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5 | The user can create an arrangement of basic shapes and estimate I(q) and |
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6 | I(q_x, q_y). Error estimates on the simulation are also available. |
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7 | |
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8 | Example: |
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9 | |
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10 | import sas.sascalc.realspace.VolumeCanvas as VolumeCanvas |
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11 | canvas = VolumeCanvas.VolumeCanvas() |
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12 | canvas.setParam('lores_density', 0.01) |
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13 | |
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14 | sphere = SphereDescriptor() |
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15 | handle = canvas.addObject(sphere) |
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16 | |
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17 | output, error = canvas.getIqError(q=0.1) |
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18 | output, error = canvas.getIq2DError(0.1, 0.1) |
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19 | |
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20 | or alternatively: |
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21 | iq = canvas.run(0.1) |
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22 | i2_2D = canvas.run([0.1, 1.57]) |
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23 | |
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24 | """ |
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25 | |
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26 | from sas.sascalc.calculator.BaseComponent import BaseComponent |
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27 | from sas.sascalc.simulation.pointsmodelpy import pointsmodelpy |
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28 | from sas.sascalc.simulation.geoshapespy import geoshapespy |
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29 | |
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30 | |
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31 | import os.path, math |
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32 | |
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33 | class ShapeDescriptor(object): |
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34 | """ |
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35 | Class to hold the information about a shape |
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36 | The descriptor holds a dictionary of parameters. |
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37 | |
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38 | Note: if shape parameters are accessed directly |
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39 | from outside VolumeCanvas. The getPr method |
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40 | should be called before evaluating I(q). |
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41 | |
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42 | """ |
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43 | def __init__(self): |
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44 | """ |
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45 | Initialization |
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46 | """ |
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47 | ## Real space object |
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48 | self.shapeObject = None |
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49 | ## Parameters of the object |
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50 | self.params = {} |
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51 | self.params["center"] = [0, 0, 0] |
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52 | # Orientation are angular offsets in degrees with respect to X, Y, Z |
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53 | self.params["orientation"] = [0, 0, 0] |
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54 | # Default to lores shape |
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55 | self.params['is_lores'] = True |
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56 | self.params['order'] = 0 |
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57 | |
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58 | def create(self): |
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59 | """ |
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60 | Create an instance of the shape |
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61 | """ |
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62 | # Set center |
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63 | x0 = self.params["center"][0] |
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64 | y0 = self.params["center"][1] |
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65 | z0 = self.params["center"][2] |
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66 | geoshapespy.set_center(self.shapeObject, x0, y0, z0) |
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67 | |
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68 | # Set orientation |
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69 | x0 = self.params["orientation"][0] |
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70 | y0 = self.params["orientation"][1] |
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71 | z0 = self.params["orientation"][2] |
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72 | geoshapespy.set_orientation(self.shapeObject, x0, y0, z0) |
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73 | |
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74 | class SphereDescriptor(ShapeDescriptor): |
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75 | """ |
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76 | Descriptor for a sphere |
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77 | |
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78 | The parameters are: |
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79 | - radius [Angstroem] [default = 20 A] |
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80 | - Contrast [A-2] [default = 1 A-2] |
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81 | |
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82 | """ |
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83 | def __init__(self): |
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84 | """ |
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85 | Initialization |
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86 | """ |
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87 | ShapeDescriptor.__init__(self) |
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88 | # Default parameters |
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89 | self.params["type"] = "sphere" |
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90 | # Radius of the sphere |
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91 | self.params["radius"] = 20.0 |
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92 | # Constrast parameter |
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93 | self.params["contrast"] = 1.0 |
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94 | |
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95 | def create(self): |
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96 | """ |
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97 | Create an instance of the shape |
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98 | @return: instance of the shape |
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99 | """ |
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100 | self.shapeObject = geoshapespy.new_sphere(\ |
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101 | self.params["radius"]) |
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102 | |
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103 | ShapeDescriptor.create(self) |
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104 | return self.shapeObject |
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105 | |
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106 | class CylinderDescriptor(ShapeDescriptor): |
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107 | """ |
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108 | Descriptor for a cylinder |
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109 | Orientation: Default cylinder is along Y |
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110 | |
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111 | Parameters: |
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112 | - Length [default = 40 A] |
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113 | - Radius [default = 10 A] |
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114 | - Contrast [default = 1 A-2] |
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115 | """ |
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116 | def __init__(self): |
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117 | """ |
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118 | Initialization |
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119 | """ |
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120 | ShapeDescriptor.__init__(self) |
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121 | # Default parameters |
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122 | self.params["type"] = "cylinder" |
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123 | # Length of the cylinder |
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124 | self.params["length"] = 40.0 |
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125 | # Radius of the cylinder |
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126 | self.params["radius"] = 10.0 |
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127 | # Constrast parameter |
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128 | self.params["contrast"] = 1.0 |
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129 | |
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130 | def create(self): |
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131 | """ |
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132 | Create an instance of the shape |
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133 | @return: instance of the shape |
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134 | """ |
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135 | self.shapeObject = geoshapespy.new_cylinder(\ |
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136 | self.params["radius"], self.params["length"]) |
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137 | |
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138 | ShapeDescriptor.create(self) |
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139 | return self.shapeObject |
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140 | |
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141 | |
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142 | class EllipsoidDescriptor(ShapeDescriptor): |
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143 | """ |
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144 | Descriptor for an ellipsoid |
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145 | |
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146 | Parameters: |
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147 | - Radius_x along the x-axis [default = 30 A] |
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148 | - Radius_y along the y-axis [default = 20 A] |
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149 | - Radius_z along the z-axis [default = 10 A] |
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150 | - contrast [default = 1 A-2] |
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151 | """ |
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152 | def __init__(self): |
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153 | """ |
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154 | Initialization |
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155 | """ |
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156 | ShapeDescriptor.__init__(self) |
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157 | # Default parameters |
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158 | self.params["type"] = "ellipsoid" |
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159 | self.params["radius_x"] = 30.0 |
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160 | self.params["radius_y"] = 20.0 |
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161 | self.params["radius_z"] = 10.0 |
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162 | self.params["contrast"] = 1.0 |
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163 | |
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164 | def create(self): |
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165 | """ |
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166 | Create an instance of the shape |
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167 | @return: instance of the shape |
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168 | """ |
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169 | self.shapeObject = geoshapespy.new_ellipsoid(\ |
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170 | self.params["radius_x"], self.params["radius_y"], |
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171 | self.params["radius_z"]) |
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172 | |
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173 | ShapeDescriptor.create(self) |
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174 | return self.shapeObject |
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175 | |
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176 | class HelixDescriptor(ShapeDescriptor): |
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177 | """ |
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178 | Descriptor for an helix |
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179 | |
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180 | Parameters: |
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181 | -radius_helix: the radius of the helix [default = 10 A] |
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182 | -radius_tube: radius of the "tube" that forms the helix [default = 3 A] |
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183 | -pitch: distance between two consecutive turns of the helix [default = 34 A] |
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184 | -turns: number of turns of the helix [default = 3] |
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185 | -contrast: contrast parameter [default = 1 A-2] |
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186 | """ |
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187 | def __init__(self): |
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188 | """ |
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189 | Initialization |
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190 | """ |
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191 | ShapeDescriptor.__init__(self) |
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192 | # Default parameters |
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193 | self.params["type"] = "singlehelix" |
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194 | self.params["radius_helix"] = 10.0 |
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195 | self.params["radius_tube"] = 3.0 |
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196 | self.params["pitch"] = 34.0 |
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197 | self.params["turns"] = 3.0 |
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198 | self.params["contrast"] = 1.0 |
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199 | |
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200 | def create(self): |
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201 | """ |
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202 | Create an instance of the shape |
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203 | @return: instance of the shape |
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204 | """ |
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205 | self.shapeObject = geoshapespy.new_singlehelix(\ |
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206 | self.params["radius_helix"], self.params["radius_tube"], |
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207 | self.params["pitch"], self.params["turns"]) |
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208 | |
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209 | ShapeDescriptor.create(self) |
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210 | return self.shapeObject |
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211 | |
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212 | class PDBDescriptor(ShapeDescriptor): |
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213 | """ |
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214 | Descriptor for a PDB set of points |
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215 | |
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216 | Parameter: |
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217 | - file = name of the PDB file |
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218 | """ |
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219 | def __init__(self, filename): |
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220 | """ |
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221 | Initialization |
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222 | @param filename: name of the PDB file to load |
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223 | """ |
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224 | ShapeDescriptor.__init__(self) |
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225 | # Default parameters |
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226 | self.params["type"] = "pdb" |
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227 | self.params["file"] = filename |
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228 | self.params['is_lores'] = False |
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229 | |
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230 | def create(self): |
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231 | """ |
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232 | Create an instance of the shape |
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233 | @return: instance of the shape |
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234 | """ |
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235 | self.shapeObject = pointsmodelpy.new_pdbmodel() |
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236 | pointsmodelpy.pdbmodel_add(self.shapeObject, self.params['file']) |
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237 | |
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238 | #ShapeDescriptor.create(self) |
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239 | return self.shapeObject |
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240 | |
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241 | # Define a dictionary for the shape until we find |
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242 | # a better way to create them |
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243 | shape_dict = {'sphere':SphereDescriptor, |
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244 | 'cylinder':CylinderDescriptor, |
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245 | 'ellipsoid':EllipsoidDescriptor, |
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246 | 'singlehelix':HelixDescriptor} |
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247 | |
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248 | class VolumeCanvas(BaseComponent): |
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249 | """ |
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250 | Class representing an empty space volume to add |
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251 | geometrical object to. |
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252 | |
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253 | For 1D I(q) simulation, getPr() is called internally for the |
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254 | first call to getIq(). |
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255 | |
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256 | """ |
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257 | |
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258 | def __init__(self): |
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259 | """ |
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260 | Initialization |
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261 | """ |
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262 | BaseComponent.__init__(self) |
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263 | |
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264 | ## Maximum value of q reachable |
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265 | self.params['q_max'] = 0.1 |
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266 | self.params['lores_density'] = 0.1 |
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267 | self.params['scale'] = 1.0 |
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268 | self.params['background'] = 0.0 |
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269 | |
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270 | self.lores_model = pointsmodelpy.new_loresmodel(self.params['lores_density']) |
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271 | self.complex_model = pointsmodelpy.new_complexmodel() |
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272 | self.shapes = {} |
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273 | self.shapecount = 0 |
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274 | self.points = None |
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275 | self.npts = 0 |
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276 | self.hasPr = False |
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277 | |
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278 | def _model_changed(self): |
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279 | """ |
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280 | Reset internal data members to reflect the fact that the |
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281 | real-space model has changed |
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282 | """ |
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283 | self.hasPr = False |
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284 | self.points = None |
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285 | |
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286 | def addObject(self, shapeDesc, id=None): |
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287 | """ |
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288 | Adds a real-space object to the canvas. |
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289 | |
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290 | @param shapeDesc: object to add to the canvas [ShapeDescriptor] |
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291 | @param id: string handle for the object [string] [optional] |
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292 | @return: string handle for the object |
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293 | """ |
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294 | # If the handle is not provided, create one |
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295 | if id is None: |
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296 | id = shapeDesc.params["type"]+str(self.shapecount) |
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297 | |
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298 | # Self the order number |
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299 | shapeDesc.params['order'] = self.shapecount |
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300 | # Store the shape in a dictionary entry associated |
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301 | # with the handle |
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302 | self.shapes[id] = shapeDesc |
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303 | self.shapecount += 1 |
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304 | |
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305 | # model changed, need to recalculate P(r) |
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306 | self._model_changed() |
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307 | |
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308 | return id |
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309 | |
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310 | |
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311 | def add(self, shape, id=None): |
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312 | """ |
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313 | The intend of this method is to eventually be able to use it |
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314 | as a factory for the canvas and unify the simulation with the |
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315 | analytical solutions. For instance, if one adds a cylinder and |
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316 | it is the only shape on the canvas, the analytical solution |
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317 | could be called. If multiple shapes are involved, then |
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318 | simulation has to be performed. |
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319 | |
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320 | This function is deprecated, use addObject(). |
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321 | |
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322 | @param shape: name of the object to add to the canvas [string] |
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323 | @param id: string handle for the object [string] [optional] |
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324 | @return: string handle for the object |
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325 | """ |
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326 | # If the handle is not provided, create one |
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327 | if id is None: |
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328 | id = "shape"+str(self.shapecount) |
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329 | |
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330 | # shapeDesc = ShapeDescriptor(shape.lower()) |
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331 | if shape.lower() in shape_dict: |
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332 | shapeDesc = shape_dict[shape.lower()]() |
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333 | elif os.path.isfile(shape): |
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334 | # A valid filename was supplier, create a PDB object |
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335 | shapeDesc = PDBDescriptor(shape) |
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336 | else: |
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337 | raise ValueError("VolumeCanvas.add: Unknown shape %s" % shape) |
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338 | |
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339 | return self.addObject(shapeDesc, id) |
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340 | |
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341 | def delete(self, id): |
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342 | """ |
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343 | Delete a shape. The ID for the shape is required. |
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344 | @param id: string handle for the object [string] [optional] |
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345 | """ |
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346 | |
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347 | if id in self.shapes: |
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348 | del self.shapes[id] |
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349 | else: |
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350 | raise KeyError("VolumeCanvas.delete: could not find shape ID") |
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351 | |
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352 | # model changed, need to recalculate P(r) |
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353 | self._model_changed() |
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354 | |
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355 | |
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356 | def setParam(self, name, value): |
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357 | """ |
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358 | Function to set the value of a parameter. |
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359 | Both VolumeCanvas parameters and shape parameters |
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360 | are accessible. |
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361 | |
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362 | Note: if shape parameters are accessed directly |
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363 | from outside VolumeCanvas. The getPr method |
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364 | should be called before evaluating I(q). |
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365 | |
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366 | TODO: implemented a check method to protect |
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367 | against that. |
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368 | |
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369 | @param name: name of the parameter to change |
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370 | @param value: value to give the parameter |
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371 | """ |
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372 | |
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373 | # Lowercase for case insensitivity |
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374 | name = name.lower() |
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375 | |
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376 | # Look for shape access |
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377 | toks = name.split('.') |
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378 | |
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379 | # If a shape identifier was given, look the shape up |
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380 | # in the dictionary |
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381 | if len(toks): |
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382 | if toks[0] in self.shapes: |
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383 | # The shape was found, now look for the parameter |
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384 | if toks[1] in self.shapes[toks[0]].params: |
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385 | # The parameter was found, now change it |
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386 | self.shapes[toks[0]].params[toks[1]] = value |
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387 | self._model_changed() |
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388 | else: |
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389 | raise ValueError("Could not find parameter %s" % name) |
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390 | else: |
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391 | raise ValueError("Could not find shape %s" % toks[0]) |
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392 | |
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393 | else: |
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394 | # If we are not accessing the parameters of a |
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395 | # shape, see if the parameter is part of this object |
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396 | BaseComponent.setParam(self, name, value) |
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397 | self._model_changed() |
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398 | |
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399 | def getParam(self, name): |
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400 | """ |
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401 | @param name: name of the parameter to change |
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402 | """ |
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403 | #TODO: clean this up |
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404 | |
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405 | # Lowercase for case insensitivity |
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406 | name = name.lower() |
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407 | |
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408 | # Look for sub-model access |
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409 | toks = name.split('.') |
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410 | if len(toks) == 1: |
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411 | try: |
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412 | value = self.params[toks[0]] |
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413 | except KeyError: |
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414 | raise ValueError("VolumeCanvas.getParam: Could not find" |
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415 | " %s" % name) |
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416 | if isinstance(value, ShapeDescriptor): |
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417 | raise ValueError("VolumeCanvas.getParam: Cannot get parameter" |
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418 | " value.") |
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419 | else: |
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420 | return value |
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421 | |
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422 | elif len(toks) == 2: |
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423 | try: |
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424 | shapeinstance = self.shapes[toks[0]] |
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425 | except KeyError: |
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426 | raise ValueError("VolumeCanvas.getParam: Could not find " |
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427 | "%s" % name) |
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428 | |
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429 | if not toks[1] in shapeinstance.params: |
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430 | raise ValueError("VolumeCanvas.getParam: Could not find " |
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431 | "%s" % name) |
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432 | |
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433 | return shapeinstance.params[toks[1]] |
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434 | |
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435 | else: |
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436 | raise ValueError("VolumeCanvas.getParam: Could not find %s" % name) |
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437 | |
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438 | def getParamList(self, shapeid=None): |
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439 | """ |
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440 | return a full list of all available parameters from |
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441 | self.params.keys(). If a key in self.params is a instance |
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442 | of ShapeDescriptor, extend the return list to: |
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443 | [param1,param2,shapeid.param1,shapeid.param2.......] |
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444 | |
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445 | If shapeid is provided, return the list of parameters that |
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446 | belongs to that shape id only : [shapeid.param1, shapeid.param2...] |
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447 | """ |
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448 | |
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449 | param_list = [] |
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450 | if shapeid is None: |
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451 | for key1 in self.params: |
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452 | #value1 = self.params[key1] |
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453 | param_list.append(key1) |
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454 | for key2 in self.shapes: |
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455 | value2 = self.shapes[key2] |
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456 | header = key2 + '.' |
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457 | for key3 in value2.params: |
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458 | fullname = header + key3 |
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459 | param_list.append(fullname) |
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460 | |
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461 | else: |
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462 | if not shapeid in self.shapes: |
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463 | raise ValueError("VolumeCanvas: getParamList: Could not find " |
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464 | "%s" % shapeid) |
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465 | |
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466 | header = shapeid + '.' |
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467 | param_list = [header + param for param in self.shapes[shapeid].params] |
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468 | return param_list |
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469 | |
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470 | def getShapeList(self): |
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471 | """ |
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472 | Return a list of the shapes |
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473 | """ |
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474 | return list(self.shapes.keys()) |
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475 | |
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476 | def _addSingleShape(self, shapeDesc): |
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477 | """ |
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478 | create shapeobject based on shapeDesc |
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479 | @param shapeDesc: shape description |
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480 | """ |
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481 | # Create the object model |
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482 | shapeDesc.create() |
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483 | |
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484 | if shapeDesc.params['is_lores']: |
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485 | # Add the shape to the lores_model |
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486 | pointsmodelpy.lores_add(self.lores_model, |
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487 | shapeDesc.shapeObject, |
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488 | shapeDesc.params['contrast']) |
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489 | |
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490 | def _createVolumeFromList(self): |
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491 | """ |
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492 | Create a new lores model with all the shapes in our internal list |
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493 | Whenever we change a parameter of a shape, we have to re-create |
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494 | the whole thing. |
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495 | |
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496 | Items with higher 'order' number take precedence for regions |
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497 | of space that are shared with other objects. Points in the |
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498 | overlapping region belonging to objects with lower 'order' |
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499 | will be ignored. |
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500 | |
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501 | Items are added in decreasing 'order' number. |
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502 | The item with the highest 'order' will be added *first*. |
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503 | [That conventions is prescribed by the realSpaceModeling module] |
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504 | """ |
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505 | |
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506 | # Create empty model |
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507 | self.lores_model = \ |
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508 | pointsmodelpy.new_loresmodel(self.params['lores_density']) |
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509 | |
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510 | # Create empty complex model |
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511 | self.complex_model = pointsmodelpy.new_complexmodel() |
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512 | |
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513 | # Order the object first |
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514 | obj_list = [] |
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515 | |
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516 | for shape in self.shapes: |
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517 | order = self.shapes[shape].params['order'] |
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518 | # find where to place it in the list |
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519 | stored = False |
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520 | |
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521 | for i in range(len(obj_list)): |
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522 | if obj_list[i][0] > order: |
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523 | obj_list.insert(i, [order, shape]) |
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524 | stored = True |
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525 | break |
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526 | |
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527 | if not stored: |
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528 | obj_list.append([order, shape]) |
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529 | |
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530 | # Add each shape |
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531 | len_list = len(obj_list) |
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532 | for i in range(len_list-1, -1, -1): |
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533 | shapedesc = self.shapes[obj_list[i][1]] |
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534 | self._addSingleShape(shapedesc) |
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535 | |
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536 | return 0 |
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537 | |
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538 | def getPr(self): |
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539 | """ |
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540 | Calculate P(r) from the objects on the canvas. |
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541 | This method should always be called after the shapes |
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542 | on the VolumeCanvas have changed. |
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543 | |
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544 | @return: calculation output flag |
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545 | """ |
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546 | # To find a complete example of the correct call order: |
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547 | # In LORES2, in actionclass.py, method CalculateAction._get_iq() |
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548 | |
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549 | # If there are not shapes, do nothing |
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550 | if len(self.shapes) == 0: |
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551 | self._model_changed() |
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552 | return 0 |
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553 | |
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554 | # generate space filling points from shape list |
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555 | self._createVolumeFromList() |
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556 | |
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557 | self.points = pointsmodelpy.new_point3dvec() |
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558 | |
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559 | pointsmodelpy.complexmodel_add(self.complex_model, |
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560 | self.lores_model, "LORES") |
---|
561 | for shape in self.shapes: |
---|
562 | if not self.shapes[shape].params['is_lores']: |
---|
563 | pointsmodelpy.complexmodel_add(self.complex_model, |
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564 | self.shapes[shape].shapeObject, "PDB") |
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565 | |
---|
566 | #pointsmodelpy.get_lorespoints(self.lores_model, self.points) |
---|
567 | self.npts = pointsmodelpy.get_complexpoints(self.complex_model, self.points) |
---|
568 | |
---|
569 | # expecting the rmax is a positive float or 0. The maximum distance. |
---|
570 | #rmax = pointsmodelpy.get_lores_pr(self.lores_model, self.points) |
---|
571 | |
---|
572 | rmax = pointsmodelpy.get_complex_pr(self.complex_model, self.points) |
---|
573 | self.hasPr = True |
---|
574 | |
---|
575 | return rmax |
---|
576 | |
---|
577 | def run(self, q=0): |
---|
578 | """ |
---|
579 | Returns the value of I(q) for a given q-value |
---|
580 | @param q: q-value ([float] or [list]) ([A-1] or [[A-1], [rad]]) |
---|
581 | @return: I(q) [float] [cm-1] |
---|
582 | """ |
---|
583 | # Check for 1D q length |
---|
584 | if q.__class__.__name__ == 'int' \ |
---|
585 | or q.__class__.__name__ == 'float': |
---|
586 | return self.getIq(q) |
---|
587 | # Check for 2D q-value |
---|
588 | elif q.__class__.__name__ == 'list': |
---|
589 | # Compute (Qx, Qy) from (Q, phi) |
---|
590 | # Phi is in radian and Q-values are in A-1 |
---|
591 | qx = q[0]*math.cos(q[1]) |
---|
592 | qy = q[0]*math.sin(q[1]) |
---|
593 | return self.getIq2D(qx, qy) |
---|
594 | # Through an exception if it's not a |
---|
595 | # type we recognize |
---|
596 | else: |
---|
597 | raise ValueError("run(q): bad type for q") |
---|
598 | |
---|
599 | def runXY(self, q=0): |
---|
600 | """ |
---|
601 | Standard run command for the canvas. |
---|
602 | Redirects to the correct method |
---|
603 | according to the input type. |
---|
604 | @param q: q-value [float] or [list] [A-1] |
---|
605 | @return: I(q) [float] [cm-1] |
---|
606 | """ |
---|
607 | # Check for 1D q length |
---|
608 | if q.__class__.__name__ == 'int' \ |
---|
609 | or q.__class__.__name__ == 'float': |
---|
610 | return self.getIq(q) |
---|
611 | # Check for 2D q-value |
---|
612 | elif q.__class__.__name__ == 'list': |
---|
613 | return self.getIq2D(q[0], q[1]) |
---|
614 | # Through an exception if it's not a |
---|
615 | # type we recognize |
---|
616 | else: |
---|
617 | raise ValueError("runXY(q): bad type for q") |
---|
618 | |
---|
619 | def _create_modelObject(self): |
---|
620 | """ |
---|
621 | Create the simulation model obejct from the list |
---|
622 | of shapes. |
---|
623 | |
---|
624 | This method needs to be called each time a parameter |
---|
625 | changes because of the way the underlying library |
---|
626 | was (badly) written. It is impossible to change a |
---|
627 | parameter, or remove a shape without having to |
---|
628 | refill the space points. |
---|
629 | |
---|
630 | TODO: improve that. |
---|
631 | """ |
---|
632 | # To find a complete example of the correct call order: |
---|
633 | # In LORES2, in actionclass.py, method CalculateAction._get_iq() |
---|
634 | |
---|
635 | # If there are not shapes, do nothing |
---|
636 | if len(self.shapes) == 0: |
---|
637 | self._model_changed() |
---|
638 | return 0 |
---|
639 | |
---|
640 | # generate space filling points from shape list |
---|
641 | self._createVolumeFromList() |
---|
642 | |
---|
643 | self.points = pointsmodelpy.new_point3dvec() |
---|
644 | |
---|
645 | pointsmodelpy.complexmodel_add(self.complex_model, |
---|
646 | self.lores_model, "LORES") |
---|
647 | for shape in self.shapes: |
---|
648 | if not self.shapes[shape].params['is_lores']: |
---|
649 | pointsmodelpy.complexmodel_add(self.complex_model, |
---|
650 | self.shapes[shape].shapeObject, "PDB") |
---|
651 | |
---|
652 | #pointsmodelpy.get_lorespoints(self.lores_model, self.points) |
---|
653 | self.npts = pointsmodelpy.get_complexpoints(self.complex_model, self.points) |
---|
654 | |
---|
655 | |
---|
656 | def getIq2D(self, qx, qy): |
---|
657 | """ |
---|
658 | Returns simulate I(q) for given q_x and q_y values. |
---|
659 | @param qx: q_x [A-1] |
---|
660 | @param qy: q_y [A-1] |
---|
661 | @return: I(q) [cm-1] |
---|
662 | """ |
---|
663 | |
---|
664 | # If this is the first simulation call, we need to generate the |
---|
665 | # space points |
---|
666 | if self.points is None: |
---|
667 | self._create_modelObject() |
---|
668 | |
---|
669 | # Protect against empty model |
---|
670 | if self.points is None: |
---|
671 | return 0 |
---|
672 | |
---|
673 | # Evalute I(q) |
---|
674 | norm = 1.0e8/self.params['lores_density']*self.params['scale'] |
---|
675 | return norm*pointsmodelpy.get_complex_iq_2D(self.complex_model, self.points, qx, qy)\ |
---|
676 | + self.params['background'] |
---|
677 | |
---|
678 | def write_pr(self, filename): |
---|
679 | """ |
---|
680 | Write P(r) to an output file |
---|
681 | @param filename: file name for P(r) output |
---|
682 | """ |
---|
683 | if not self.hasPr: |
---|
684 | self.getPr() |
---|
685 | |
---|
686 | pointsmodelpy.outputPR(self.complex_model, filename) |
---|
687 | |
---|
688 | def getPrData(self): |
---|
689 | """ |
---|
690 | Write P(r) to an output file |
---|
691 | @param filename: file name for P(r) output |
---|
692 | """ |
---|
693 | if not self.hasPr: |
---|
694 | self.getPr() |
---|
695 | |
---|
696 | return pointsmodelpy.get_pr(self.complex_model) |
---|
697 | |
---|
698 | def getIq(self, q): |
---|
699 | """ |
---|
700 | Returns the value of I(q) for a given q-value |
---|
701 | |
---|
702 | This method should remain internal to the class |
---|
703 | and the run() method should be used instead. |
---|
704 | |
---|
705 | @param q: q-value [float] |
---|
706 | @return: I(q) [float] |
---|
707 | """ |
---|
708 | |
---|
709 | if not self.hasPr: |
---|
710 | self.getPr() |
---|
711 | |
---|
712 | # By dividing by the density instead of the actuall V/N, |
---|
713 | # we have an uncertainty of +-1 on N because the number |
---|
714 | # of points chosen for the simulation is int(density*volume). |
---|
715 | # Propagation of error gives: |
---|
716 | # delta(1/density^2) = 2*(1/density^2)/N |
---|
717 | # where N is stored in self.npts |
---|
718 | |
---|
719 | norm = 1.0e8/self.params['lores_density']*self.params['scale'] |
---|
720 | #return norm*pointsmodelpy.get_lores_i(self.lores_model, q) |
---|
721 | return norm*pointsmodelpy.get_complex_i(self.complex_model, q)\ |
---|
722 | + self.params['background'] |
---|
723 | |
---|
724 | def getError(self, q): |
---|
725 | """ |
---|
726 | Returns the error of I(q) for a given q-value |
---|
727 | @param q: q-value [float] |
---|
728 | @return: I(q) [float] |
---|
729 | """ |
---|
730 | |
---|
731 | if not self.hasPr: |
---|
732 | self.getPr() |
---|
733 | |
---|
734 | # By dividing by the density instead of the actual V/N, |
---|
735 | # we have an uncertainty of +-1 on N because the number |
---|
736 | # of points chosen for the simulation is int(density*volume). |
---|
737 | # Propagation of error gives: |
---|
738 | # delta(1/density^2) = 2*(1/density^2)/N |
---|
739 | # where N is stored in self.npts |
---|
740 | |
---|
741 | norm = 1.0e8/self.params['lores_density']*self.params['scale'] |
---|
742 | #return norm*pointsmodelpy.get_lores_i(self.lores_model, q) |
---|
743 | return norm*pointsmodelpy.get_complex_i_error(self.complex_model, q)\ |
---|
744 | + self.params['background'] |
---|
745 | |
---|
746 | def getIqError(self, q): |
---|
747 | """ |
---|
748 | Return the simulated value along with its estimated |
---|
749 | error for a given q-value |
---|
750 | |
---|
751 | Propagation of errors is used to evaluate the |
---|
752 | uncertainty. |
---|
753 | |
---|
754 | @param q: q-value [float] |
---|
755 | @return: mean, error [float, float] |
---|
756 | """ |
---|
757 | val = self.getIq(q) |
---|
758 | # Simulation error (statistical) |
---|
759 | err = self.getError(q) |
---|
760 | # Error on V/N |
---|
761 | simerr = 2*val/self.npts |
---|
762 | return val, err+simerr |
---|
763 | |
---|
764 | def getIq2DError(self, qx, qy): |
---|
765 | """ |
---|
766 | Return the simulated value along with its estimated |
---|
767 | error for a given q-value |
---|
768 | |
---|
769 | Propagation of errors is used to evaluate the |
---|
770 | uncertainty. |
---|
771 | |
---|
772 | @param qx: qx-value [float] |
---|
773 | @param qy: qy-value [float] |
---|
774 | @return: mean, error [float, float] |
---|
775 | """ |
---|
776 | self._create_modelObject() |
---|
777 | |
---|
778 | norm = 1.0e8/self.params['lores_density']*self.params['scale'] |
---|
779 | val = norm*pointsmodelpy.get_complex_iq_2D(self.complex_model, self.points, qx, qy)\ |
---|
780 | + self.params['background'] |
---|
781 | |
---|
782 | # Simulation error (statistical) |
---|
783 | norm = 1.0e8/self.params['lores_density']*self.params['scale'] \ |
---|
784 | * math.pow(self.npts/self.params['lores_density'], 1.0/3.0)/self.npts |
---|
785 | err = norm*pointsmodelpy.get_complex_iq_2D_err(self.complex_model, self.points, qx, qy) |
---|
786 | # Error on V/N |
---|
787 | simerr = 2*val/self.npts |
---|
788 | |
---|
789 | # The error used for the position is over-simplified. |
---|
790 | # The actual error was empirically found to be about |
---|
791 | # an order of magnitude larger. |
---|
792 | return val, 10.0*err+simerr |
---|