1 | """ |
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2 | Sasview model constructor. |
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3 | |
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4 | Given a module defining an OpenCL kernel such as sasmodels.models.cylinder, |
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5 | create a sasview model class to run that kernel as follows:: |
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6 | |
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7 | from sasmodels.sasview_model import load_custom_model |
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8 | CylinderModel = load_custom_model('sasmodels/models/cylinder.py') |
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9 | """ |
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10 | from __future__ import print_function |
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11 | |
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12 | import math |
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13 | from copy import deepcopy |
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14 | import collections |
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15 | import traceback |
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16 | import logging |
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17 | from os.path import basename, splitext |
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18 | |
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19 | import numpy as np # type: ignore |
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20 | |
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21 | from . import core |
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22 | from . import custom |
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23 | from . import generate |
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24 | from . import weights |
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25 | from . import modelinfo |
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26 | from .details import make_kernel_args, dispersion_mesh |
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27 | |
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28 | try: |
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29 | from typing import Dict, Mapping, Any, Sequence, Tuple, NamedTuple, List, Optional, Union, Callable |
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30 | from .modelinfo import ModelInfo, Parameter |
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31 | from .kernel import KernelModel |
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32 | MultiplicityInfoType = NamedTuple( |
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33 | 'MuliplicityInfo', |
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34 | [("number", int), ("control", str), ("choices", List[str]), |
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35 | ("x_axis_label", str)]) |
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36 | SasviewModelType = Callable[[int], "SasviewModel"] |
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37 | except ImportError: |
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38 | pass |
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39 | |
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40 | SUPPORT_OLD_STYLE_PLUGINS = True |
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41 | |
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42 | def _register_old_models(): |
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43 | # type: () -> None |
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44 | """ |
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45 | Place the new models into sasview under the old names. |
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46 | |
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47 | Monkey patch sas.sascalc.fit as sas.models so that sas.models.pluginmodel |
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48 | is available to the plugin modules. |
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49 | """ |
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50 | import sys |
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51 | import sas |
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52 | import sas.sascalc.fit |
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53 | sys.modules['sas.models'] = sas.sascalc.fit |
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54 | sas.models = sas.sascalc.fit |
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55 | |
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56 | import sas.models |
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57 | from sasmodels.conversion_table import CONVERSION_TABLE |
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58 | for new_name, conversion in CONVERSION_TABLE.items(): |
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59 | old_name = conversion[0] |
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60 | module_attrs = {old_name: find_model(new_name)} |
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61 | ConstructedModule = type(old_name, (), module_attrs) |
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62 | old_path = 'sas.models.' + old_name |
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63 | setattr(sas.models, old_path, ConstructedModule) |
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64 | sys.modules[old_path] = ConstructedModule |
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65 | |
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66 | |
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67 | # TODO: separate x_axis_label from multiplicity info |
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68 | MultiplicityInfo = collections.namedtuple( |
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69 | 'MultiplicityInfo', |
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70 | ["number", "control", "choices", "x_axis_label"], |
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71 | ) |
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72 | |
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73 | MODELS = {} |
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74 | def find_model(modelname): |
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75 | # type: (str) -> SasviewModelType |
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76 | """ |
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77 | Find a model by name. If the model name ends in py, try loading it from |
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78 | custom models, otherwise look for it in the list of builtin models. |
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79 | """ |
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80 | # TODO: used by sum/product model to load an existing model |
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81 | # TODO: doesn't handle custom models properly |
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82 | if modelname.endswith('.py'): |
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83 | return load_custom_model(modelname) |
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84 | elif modelname in MODELS: |
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85 | return MODELS[modelname] |
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86 | else: |
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87 | raise ValueError("unknown model %r"%modelname) |
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88 | |
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89 | |
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90 | # TODO: figure out how to say that the return type is a subclass |
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91 | def load_standard_models(): |
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92 | # type: () -> List[SasviewModelType] |
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93 | """ |
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94 | Load and return the list of predefined models. |
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95 | |
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96 | If there is an error loading a model, then a traceback is logged and the |
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97 | model is not returned. |
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98 | """ |
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99 | models = [] |
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100 | for name in core.list_models(): |
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101 | try: |
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102 | MODELS[name] = _make_standard_model(name) |
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103 | models.append(MODELS[name]) |
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104 | except Exception: |
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105 | logging.error(traceback.format_exc()) |
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106 | if SUPPORT_OLD_STYLE_PLUGINS: |
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107 | _register_old_models() |
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108 | |
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109 | return models |
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110 | |
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111 | |
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112 | def load_custom_model(path): |
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113 | # type: (str) -> SasviewModelType |
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114 | """ |
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115 | Load a custom model given the model path. |
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116 | """ |
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117 | #print("load custom", path) |
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118 | kernel_module = custom.load_custom_kernel_module(path) |
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119 | try: |
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120 | model = kernel_module.Model |
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121 | # Old style models do not set the name in the class attributes, so |
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122 | # set it here; this name will be overridden when the object is created |
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123 | # with an instance variable that has the same value. |
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124 | if model.name == "": |
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125 | model.name = splitext(basename(path))[0] |
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126 | except AttributeError: |
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127 | model_info = modelinfo.make_model_info(kernel_module) |
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128 | model = _make_model_from_info(model_info) |
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129 | MODELS[model.name] = model |
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130 | return model |
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131 | |
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132 | |
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133 | def _make_standard_model(name): |
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134 | # type: (str) -> SasviewModelType |
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135 | """ |
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136 | Load the sasview model defined by *name*. |
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137 | |
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138 | *name* can be a standard model name or a path to a custom model. |
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139 | |
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140 | Returns a class that can be used directly as a sasview model. |
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141 | """ |
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142 | kernel_module = generate.load_kernel_module(name) |
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143 | model_info = modelinfo.make_model_info(kernel_module) |
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144 | return _make_model_from_info(model_info) |
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145 | |
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146 | |
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147 | def _make_model_from_info(model_info): |
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148 | # type: (ModelInfo) -> SasviewModelType |
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149 | """ |
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150 | Convert *model_info* into a SasView model wrapper. |
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151 | """ |
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152 | def __init__(self, multiplicity=None): |
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153 | SasviewModel.__init__(self, multiplicity=multiplicity) |
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154 | attrs = _generate_model_attributes(model_info) |
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155 | attrs['__init__'] = __init__ |
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156 | ConstructedModel = type(model_info.name, (SasviewModel,), attrs) # type: SasviewModelType |
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157 | return ConstructedModel |
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158 | |
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159 | def _generate_model_attributes(model_info): |
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160 | # type: (ModelInfo) -> Dict[str, Any] |
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161 | """ |
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162 | Generate the class attributes for the model. |
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163 | |
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164 | This should include all the information necessary to query the model |
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165 | details so that you do not need to instantiate a model to query it. |
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166 | |
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167 | All the attributes should be immutable to avoid accidents. |
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168 | """ |
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169 | |
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170 | # TODO: allow model to override axis labels input/output name/unit |
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171 | |
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172 | # Process multiplicity |
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173 | non_fittable = [] # type: List[str] |
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174 | xlabel = model_info.profile_axes[0] if model_info.profile is not None else "" |
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175 | variants = MultiplicityInfo(0, "", [], xlabel) |
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176 | for p in model_info.parameters.kernel_parameters: |
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177 | if p.name == model_info.control: |
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178 | non_fittable.append(p.name) |
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179 | variants = MultiplicityInfo( |
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180 | len(p.choices) if p.choices else int(p.limits[1]), |
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181 | p.name, p.choices, xlabel |
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182 | ) |
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183 | break |
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184 | |
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185 | # Only a single drop-down list parameter available |
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186 | fun_list = [] |
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187 | for p in model_info.parameters.kernel_parameters: |
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188 | if p.choices: |
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189 | fun_list = p.choices |
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190 | if p.length > 1: |
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191 | non_fittable.extend(p.id+str(k) for k in range(1, p.length+1)) |
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192 | break |
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193 | |
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194 | # Organize parameter sets |
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195 | orientation_params = [] |
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196 | magnetic_params = [] |
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197 | fixed = [] |
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198 | for p in model_info.parameters.user_parameters(): |
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199 | if p.type == 'orientation': |
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200 | orientation_params.append(p.name) |
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201 | orientation_params.append(p.name+".width") |
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202 | fixed.append(p.name+".width") |
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203 | elif p.type == 'magnetic': |
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204 | orientation_params.append(p.name) |
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205 | magnetic_params.append(p.name) |
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206 | fixed.append(p.name+".width") |
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207 | |
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208 | |
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209 | # Build class dictionary |
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210 | attrs = {} # type: Dict[str, Any] |
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211 | attrs['_model_info'] = model_info |
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212 | attrs['name'] = model_info.name |
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213 | attrs['id'] = model_info.id |
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214 | attrs['description'] = model_info.description |
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215 | attrs['category'] = model_info.category |
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216 | attrs['is_structure_factor'] = model_info.structure_factor |
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217 | attrs['is_form_factor'] = model_info.ER is not None |
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218 | attrs['is_multiplicity_model'] = variants[0] > 1 |
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219 | attrs['multiplicity_info'] = variants |
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220 | attrs['orientation_params'] = tuple(orientation_params) |
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221 | attrs['magnetic_params'] = tuple(magnetic_params) |
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222 | attrs['fixed'] = tuple(fixed) |
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223 | attrs['non_fittable'] = tuple(non_fittable) |
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224 | attrs['fun_list'] = tuple(fun_list) |
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225 | |
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226 | return attrs |
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227 | |
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228 | class SasviewModel(object): |
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229 | """ |
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230 | Sasview wrapper for opencl/ctypes model. |
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231 | """ |
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232 | # Model parameters for the specific model are set in the class constructor |
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233 | # via the _generate_model_attributes function, which subclasses |
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234 | # SasviewModel. They are included here for typing and documentation |
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235 | # purposes. |
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236 | _model = None # type: KernelModel |
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237 | _model_info = None # type: ModelInfo |
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238 | #: load/save name for the model |
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239 | id = None # type: str |
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240 | #: display name for the model |
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241 | name = None # type: str |
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242 | #: short model description |
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243 | description = None # type: str |
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244 | #: default model category |
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245 | category = None # type: str |
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246 | |
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247 | #: names of the orientation parameters in the order they appear |
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248 | orientation_params = None # type: Sequence[str] |
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249 | #: names of the magnetic parameters in the order they appear |
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250 | magnetic_params = None # type: Sequence[str] |
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251 | #: names of the fittable parameters |
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252 | fixed = None # type: Sequence[str] |
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253 | # TODO: the attribute fixed is ill-named |
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254 | |
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255 | # Axis labels |
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256 | input_name = "Q" |
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257 | input_unit = "A^{-1}" |
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258 | output_name = "Intensity" |
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259 | output_unit = "cm^{-1}" |
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260 | |
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261 | #: default cutoff for polydispersity |
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262 | cutoff = 1e-5 |
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263 | |
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264 | # Note: Use non-mutable values for class attributes to avoid errors |
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265 | #: parameters that are not fitted |
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266 | non_fittable = () # type: Sequence[str] |
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267 | |
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268 | #: True if model should appear as a structure factor |
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269 | is_structure_factor = False |
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270 | #: True if model should appear as a form factor |
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271 | is_form_factor = False |
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272 | #: True if model has multiplicity |
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273 | is_multiplicity_model = False |
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274 | #: Mulitplicity information |
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275 | multiplicity_info = None # type: MultiplicityInfoType |
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276 | |
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277 | # Per-instance variables |
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278 | #: parameter {name: value} mapping |
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279 | params = None # type: Dict[str, float] |
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280 | #: values for dispersion width, npts, nsigmas and type |
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281 | dispersion = None # type: Dict[str, Any] |
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282 | #: units and limits for each parameter |
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283 | details = None # type: Dict[str, Sequence[Any]] |
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284 | # # actual type is Dict[str, List[str, float, float]] |
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285 | #: multiplicity value, or None if no multiplicity on the model |
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286 | multiplicity = None # type: Optional[int] |
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287 | #: memory for polydispersity array if using ArrayDispersion (used by sasview). |
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288 | _persistency_dict = None # type: Dict[str, Tuple[np.ndarray, np.ndarray]] |
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289 | |
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290 | def __init__(self, multiplicity=None): |
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291 | # type: (Optional[int]) -> None |
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292 | |
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293 | # TODO: _persistency_dict to persistency_dict throughout sasview |
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294 | # TODO: refactor multiplicity to encompass variants |
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295 | # TODO: dispersion should be a class |
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296 | # TODO: refactor multiplicity info |
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297 | # TODO: separate profile view from multiplicity |
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298 | # The button label, x and y axis labels and scale need to be under |
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299 | # the control of the model, not the fit page. Maximum flexibility, |
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300 | # the fit page would supply the canvas and the profile could plot |
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301 | # how it wants, but this assumes matplotlib. Next level is that |
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302 | # we provide some sort of data description including title, labels |
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303 | # and lines to plot. |
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304 | |
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305 | # Get the list of hidden parameters given the mulitplicity |
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306 | # Don't include multiplicity in the list of parameters |
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307 | self.multiplicity = multiplicity |
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308 | if multiplicity is not None: |
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309 | hidden = self._model_info.get_hidden_parameters(multiplicity) |
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310 | hidden |= set([self.multiplicity_info.control]) |
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311 | else: |
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312 | hidden = set() |
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313 | |
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314 | self._persistency_dict = {} |
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315 | self.params = collections.OrderedDict() |
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316 | self.dispersion = collections.OrderedDict() |
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317 | self.details = {} |
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318 | for p in self._model_info.parameters.user_parameters(): |
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319 | if p.name in hidden: |
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320 | continue |
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321 | self.params[p.name] = p.default |
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322 | self.details[p.id] = [p.units, p.limits[0], p.limits[1]] |
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323 | if p.polydisperse: |
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324 | self.details[p.id+".width"] = [ |
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325 | "", 0.0, 1.0 if p.relative_pd else np.inf |
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326 | ] |
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327 | self.dispersion[p.name] = { |
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328 | 'width': 0, |
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329 | 'npts': 35, |
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330 | 'nsigmas': 3, |
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331 | 'type': 'gaussian', |
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332 | } |
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333 | |
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334 | def __get_state__(self): |
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335 | # type: () -> Dict[str, Any] |
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336 | state = self.__dict__.copy() |
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337 | state.pop('_model') |
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338 | # May need to reload model info on set state since it has pointers |
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339 | # to python implementations of Iq, etc. |
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340 | #state.pop('_model_info') |
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341 | return state |
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342 | |
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343 | def __set_state__(self, state): |
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344 | # type: (Dict[str, Any]) -> None |
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345 | self.__dict__ = state |
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346 | self._model = None |
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347 | |
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348 | def __str__(self): |
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349 | # type: () -> str |
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350 | """ |
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351 | :return: string representation |
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352 | """ |
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353 | return self.name |
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354 | |
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355 | def is_fittable(self, par_name): |
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356 | # type: (str) -> bool |
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357 | """ |
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358 | Check if a given parameter is fittable or not |
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359 | |
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360 | :param par_name: the parameter name to check |
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361 | """ |
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362 | return par_name in self.fixed |
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363 | #For the future |
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364 | #return self.params[str(par_name)].is_fittable() |
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365 | |
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366 | |
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367 | def getProfile(self): |
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368 | # type: () -> (np.ndarray, np.ndarray) |
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369 | """ |
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370 | Get SLD profile |
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371 | |
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372 | : return: (z, beta) where z is a list of depth of the transition points |
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373 | beta is a list of the corresponding SLD values |
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374 | """ |
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375 | args = {} # type: Dict[str, Any] |
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376 | for p in self._model_info.parameters.kernel_parameters: |
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377 | if p.id == self.multiplicity_info.control: |
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378 | value = float(self.multiplicity) |
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379 | elif p.length == 1: |
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380 | value = self.params.get(p.id, np.NaN) |
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381 | else: |
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382 | value = np.array([self.params.get(p.id+str(k), np.NaN) |
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383 | for k in range(1, p.length+1)]) |
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384 | args[p.id] = value |
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385 | |
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386 | x, y = self._model_info.profile(**args) |
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387 | return x, 1e-6*y |
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388 | |
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389 | def setParam(self, name, value): |
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390 | # type: (str, float) -> None |
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391 | """ |
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392 | Set the value of a model parameter |
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393 | |
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394 | :param name: name of the parameter |
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395 | :param value: value of the parameter |
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396 | |
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397 | """ |
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398 | # Look for dispersion parameters |
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399 | toks = name.split('.') |
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400 | if len(toks) == 2: |
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401 | for item in self.dispersion.keys(): |
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402 | if item == toks[0]: |
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403 | for par in self.dispersion[item]: |
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404 | if par == toks[1]: |
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405 | self.dispersion[item][par] = value |
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406 | return |
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407 | else: |
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408 | # Look for standard parameter |
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409 | for item in self.params.keys(): |
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410 | if item == name: |
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411 | self.params[item] = value |
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412 | return |
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413 | |
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414 | raise ValueError("Model does not contain parameter %s" % name) |
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415 | |
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416 | def getParam(self, name): |
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417 | # type: (str) -> float |
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418 | """ |
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419 | Set the value of a model parameter |
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420 | |
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421 | :param name: name of the parameter |
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422 | |
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423 | """ |
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424 | # Look for dispersion parameters |
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425 | toks = name.split('.') |
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426 | if len(toks) == 2: |
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427 | for item in self.dispersion.keys(): |
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428 | if item == toks[0]: |
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429 | for par in self.dispersion[item]: |
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430 | if par == toks[1]: |
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431 | return self.dispersion[item][par] |
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432 | else: |
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433 | # Look for standard parameter |
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434 | for item in self.params.keys(): |
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435 | if item == name: |
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436 | return self.params[item] |
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437 | |
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438 | raise ValueError("Model does not contain parameter %s" % name) |
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439 | |
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440 | def getParamList(self): |
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441 | # type: () -> Sequence[str] |
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442 | """ |
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443 | Return a list of all available parameters for the model |
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444 | """ |
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445 | param_list = list(self.params.keys()) |
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446 | # WARNING: Extending the list with the dispersion parameters |
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447 | param_list.extend(self.getDispParamList()) |
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448 | return param_list |
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449 | |
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450 | def getDispParamList(self): |
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451 | # type: () -> Sequence[str] |
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452 | """ |
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453 | Return a list of polydispersity parameters for the model |
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454 | """ |
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455 | # TODO: fix test so that parameter order doesn't matter |
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456 | ret = ['%s.%s' % (p_name, ext) |
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457 | for p_name in self.dispersion.keys() |
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458 | for ext in ('npts', 'nsigmas', 'width')] |
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459 | #print(ret) |
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460 | return ret |
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461 | |
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462 | def clone(self): |
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463 | # type: () -> "SasviewModel" |
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464 | """ Return a identical copy of self """ |
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465 | return deepcopy(self) |
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466 | |
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467 | def run(self, x=0.0): |
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468 | # type: (Union[float, (float, float), List[float]]) -> float |
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469 | """ |
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470 | Evaluate the model |
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471 | |
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472 | :param x: input q, or [q,phi] |
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473 | |
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474 | :return: scattering function P(q) |
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475 | |
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476 | **DEPRECATED**: use calculate_Iq instead |
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477 | """ |
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478 | if isinstance(x, (list, tuple)): |
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479 | # pylint: disable=unpacking-non-sequence |
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480 | q, phi = x |
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481 | return self.calculate_Iq([q*math.cos(phi)], [q*math.sin(phi)])[0] |
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482 | else: |
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483 | return self.calculate_Iq([x])[0] |
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484 | |
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485 | |
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486 | def runXY(self, x=0.0): |
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487 | # type: (Union[float, (float, float), List[float]]) -> float |
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488 | """ |
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489 | Evaluate the model in cartesian coordinates |
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490 | |
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491 | :param x: input q, or [qx, qy] |
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492 | |
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493 | :return: scattering function P(q) |
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494 | |
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495 | **DEPRECATED**: use calculate_Iq instead |
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496 | """ |
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497 | if isinstance(x, (list, tuple)): |
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498 | return self.calculate_Iq([x[0]], [x[1]])[0] |
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499 | else: |
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500 | return self.calculate_Iq([x])[0] |
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501 | |
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502 | def evalDistribution(self, qdist): |
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503 | # type: (Union[np.ndarray, Tuple[np.ndarray, np.ndarray], List[np.ndarray]]) -> np.ndarray |
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504 | r""" |
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505 | Evaluate a distribution of q-values. |
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506 | |
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507 | :param qdist: array of q or a list of arrays [qx,qy] |
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508 | |
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509 | * For 1D, a numpy array is expected as input |
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510 | |
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511 | :: |
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512 | |
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513 | evalDistribution(q) |
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514 | |
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515 | where *q* is a numpy array. |
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516 | |
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517 | * For 2D, a list of *[qx,qy]* is expected with 1D arrays as input |
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518 | |
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519 | :: |
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520 | |
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521 | qx = [ qx[0], qx[1], qx[2], ....] |
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522 | qy = [ qy[0], qy[1], qy[2], ....] |
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523 | |
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524 | If the model is 1D only, then |
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525 | |
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526 | .. math:: |
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527 | |
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528 | q = \sqrt{q_x^2+q_y^2} |
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529 | |
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530 | """ |
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531 | if isinstance(qdist, (list, tuple)): |
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532 | # Check whether we have a list of ndarrays [qx,qy] |
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533 | qx, qy = qdist |
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534 | if not self._model_info.parameters.has_2d: |
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535 | return self.calculate_Iq(np.sqrt(qx ** 2 + qy ** 2)) |
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536 | else: |
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537 | return self.calculate_Iq(qx, qy) |
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538 | |
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539 | elif isinstance(qdist, np.ndarray): |
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540 | # We have a simple 1D distribution of q-values |
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541 | return self.calculate_Iq(qdist) |
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542 | |
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543 | else: |
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544 | raise TypeError("evalDistribution expects q or [qx, qy], not %r" |
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545 | % type(qdist)) |
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546 | |
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547 | def calculate_Iq(self, qx, qy=None): |
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548 | # type: (Sequence[float], Optional[Sequence[float]]) -> np.ndarray |
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549 | """ |
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550 | Calculate Iq for one set of q with the current parameters. |
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551 | |
---|
552 | If the model is 1D, use *q*. If 2D, use *qx*, *qy*. |
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553 | |
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554 | This should NOT be used for fitting since it copies the *q* vectors |
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555 | to the card for each evaluation. |
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556 | """ |
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557 | #core.HAVE_OPENCL = False |
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558 | if self._model is None: |
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559 | self._model = core.build_model(self._model_info) |
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560 | if qy is not None: |
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561 | q_vectors = [np.asarray(qx), np.asarray(qy)] |
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562 | else: |
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563 | q_vectors = [np.asarray(qx)] |
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564 | calculator = self._model.make_kernel(q_vectors) |
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565 | parameters = self._model_info.parameters |
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566 | pairs = [self._get_weights(p) for p in parameters.call_parameters] |
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567 | #weights.plot_weights(self._model_info, pairs) |
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568 | call_details, values, is_magnetic = make_kernel_args(calculator, pairs) |
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569 | #call_details.show() |
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570 | #print("pairs", pairs) |
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571 | #print("params", self.params) |
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572 | #print("values", values) |
---|
573 | #print("is_mag", is_magnetic) |
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574 | result = calculator(call_details, values, cutoff=self.cutoff, |
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575 | magnetic=is_magnetic) |
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576 | calculator.release() |
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577 | return result |
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578 | |
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579 | def calculate_ER(self): |
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580 | # type: () -> float |
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581 | """ |
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582 | Calculate the effective radius for P(q)*S(q) |
---|
583 | |
---|
584 | :return: the value of the effective radius |
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585 | """ |
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586 | if self._model_info.ER is None: |
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587 | return 1.0 |
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588 | else: |
---|
589 | value, weight = self._dispersion_mesh() |
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590 | fv = self._model_info.ER(*value) |
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591 | #print(values[0].shape, weights.shape, fv.shape) |
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592 | return np.sum(weight * fv) / np.sum(weight) |
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593 | |
---|
594 | def calculate_VR(self): |
---|
595 | # type: () -> float |
---|
596 | """ |
---|
597 | Calculate the volf ratio for P(q)*S(q) |
---|
598 | |
---|
599 | :return: the value of the volf ratio |
---|
600 | """ |
---|
601 | if self._model_info.VR is None: |
---|
602 | return 1.0 |
---|
603 | else: |
---|
604 | value, weight = self._dispersion_mesh() |
---|
605 | whole, part = self._model_info.VR(*value) |
---|
606 | return np.sum(weight * part) / np.sum(weight * whole) |
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607 | |
---|
608 | def set_dispersion(self, parameter, dispersion): |
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609 | # type: (str, weights.Dispersion) -> Dict[str, Any] |
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610 | """ |
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611 | Set the dispersion object for a model parameter |
---|
612 | |
---|
613 | :param parameter: name of the parameter [string] |
---|
614 | :param dispersion: dispersion object of type Dispersion |
---|
615 | """ |
---|
616 | if parameter in self.params: |
---|
617 | # TODO: Store the disperser object directly in the model. |
---|
618 | # The current method of relying on the sasview GUI to |
---|
619 | # remember them is kind of funky. |
---|
620 | # Note: can't seem to get disperser parameters from sasview |
---|
621 | # (1) Could create a sasview model that has not yet been |
---|
622 | # converted, assign the disperser to one of its polydisperse |
---|
623 | # parameters, then retrieve the disperser parameters from the |
---|
624 | # sasview model. |
---|
625 | # (2) Could write a disperser parameter retriever in sasview. |
---|
626 | # (3) Could modify sasview to use sasmodels.weights dispersers. |
---|
627 | # For now, rely on the fact that the sasview only ever uses |
---|
628 | # new dispersers in the set_dispersion call and create a new |
---|
629 | # one instead of trying to assign parameters. |
---|
630 | self.dispersion[parameter] = dispersion.get_pars() |
---|
631 | else: |
---|
632 | raise ValueError("%r is not a dispersity or orientation parameter") |
---|
633 | |
---|
634 | def _dispersion_mesh(self): |
---|
635 | # type: () -> List[Tuple[np.ndarray, np.ndarray]] |
---|
636 | """ |
---|
637 | Create a mesh grid of dispersion parameters and weights. |
---|
638 | |
---|
639 | Returns [p1,p2,...],w where pj is a vector of values for parameter j |
---|
640 | and w is a vector containing the products for weights for each |
---|
641 | parameter set in the vector. |
---|
642 | """ |
---|
643 | pars = [self._get_weights(p) |
---|
644 | for p in self._model_info.parameters.call_parameters |
---|
645 | if p.type == 'volume'] |
---|
646 | return dispersion_mesh(self._model_info, pars) |
---|
647 | |
---|
648 | def _get_weights(self, par): |
---|
649 | # type: (Parameter) -> Tuple[np.ndarray, np.ndarray] |
---|
650 | """ |
---|
651 | Return dispersion weights for parameter |
---|
652 | """ |
---|
653 | if par.name not in self.params: |
---|
654 | if par.name == self.multiplicity_info.control: |
---|
655 | return [self.multiplicity], [1.0] |
---|
656 | else: |
---|
657 | return [np.NaN], [1.0] |
---|
658 | elif par.polydisperse: |
---|
659 | dis = self.dispersion[par.name] |
---|
660 | if dis['type'] == 'array': |
---|
661 | value, weight = dis['values'], dis['weights'] |
---|
662 | else: |
---|
663 | value, weight = weights.get_weights( |
---|
664 | dis['type'], dis['npts'], dis['width'], dis['nsigmas'], |
---|
665 | self.params[par.name], par.limits, par.relative_pd) |
---|
666 | return value, weight / np.sum(weight) |
---|
667 | else: |
---|
668 | return [self.params[par.name]], [1.0] |
---|
669 | |
---|
670 | def test_model(): |
---|
671 | # type: () -> float |
---|
672 | """ |
---|
673 | Test that a sasview model (cylinder) can be run. |
---|
674 | """ |
---|
675 | Cylinder = _make_standard_model('cylinder') |
---|
676 | cylinder = Cylinder() |
---|
677 | return cylinder.evalDistribution([0.1, 0.1]) |
---|
678 | |
---|
679 | def test_rpa(): |
---|
680 | # type: () -> float |
---|
681 | """ |
---|
682 | Test that a sasview model (cylinder) can be run. |
---|
683 | """ |
---|
684 | RPA = _make_standard_model('rpa') |
---|
685 | rpa = RPA(3) |
---|
686 | return rpa.evalDistribution([0.1, 0.1]) |
---|
687 | |
---|
688 | |
---|
689 | def test_model_list(): |
---|
690 | # type: () -> None |
---|
691 | """ |
---|
692 | Make sure that all models build as sasview models. |
---|
693 | """ |
---|
694 | from .exception import annotate_exception |
---|
695 | for name in core.list_models(): |
---|
696 | try: |
---|
697 | _make_standard_model(name) |
---|
698 | except: |
---|
699 | annotate_exception("when loading "+name) |
---|
700 | raise |
---|
701 | |
---|
702 | def test_old_name(): |
---|
703 | # type: () -> None |
---|
704 | """ |
---|
705 | Load and run cylinder model from sas.models.CylinderModel |
---|
706 | """ |
---|
707 | if not SUPPORT_OLD_STYLE_PLUGINS: |
---|
708 | return |
---|
709 | try: |
---|
710 | # if sasview is not on the path then don't try to test it |
---|
711 | import sas |
---|
712 | except ImportError: |
---|
713 | return |
---|
714 | load_standard_models() |
---|
715 | from sas.models.CylinderModel import CylinderModel |
---|
716 | CylinderModel().evalDistribution([0.1, 0.1]) |
---|
717 | |
---|
718 | if __name__ == "__main__": |
---|
719 | print("cylinder(0.1,0.1)=%g"%test_model()) |
---|