1 | import sys, os, math, re |
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2 | import numpy as np |
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3 | import matplotlib.pyplot as plt |
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4 | sys.path.insert(0, os.path.abspath('..')) |
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5 | from sasmodels import generate, core |
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6 | from sasmodels.direct_model import DirectModel |
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7 | from sasmodels.data import empty_data1D, empty_data2D |
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8 | |
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9 | |
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10 | # Convert ../sasmodels/models/name.py to name |
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11 | model_name = os.path.basename(sys.argv[1])[:-3] |
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12 | model_info = core.load_model_info(model_name) |
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13 | model = core.build_model(model_info) |
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14 | |
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15 | # Load the doc string from the module definition file and store it in rst |
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16 | docstr = generate.make_doc(model_info) |
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17 | |
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18 | |
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19 | # Calculate 1D curve for default parameters |
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20 | pars = dict((p.name, p.default) for p in model_info['parameters']) |
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21 | |
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22 | # Plotting ranges and options |
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23 | opts = { |
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24 | 'xscale' : 'log', |
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25 | 'yscale' : 'log' if not model_info['structure_factor'] else 'linear', |
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26 | 'zscale' : 'log' if not model_info['structure_factor'] else 'linear', |
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27 | 'q_min' : 0.001, |
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28 | 'q_max' : 1.0, |
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29 | 'nq' : 1000, |
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30 | 'nq2d' : 400, |
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31 | 'vmin' : 1e-3, # floor for the 2D data results |
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32 | 'qx_max' : 0.5, |
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33 | } |
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34 | |
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35 | |
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36 | def plot_1d(model, opts, ax): |
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37 | q_min, q_max, nq = opts['q_min'], opts['q_max'], opts['nq'] |
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38 | q_min = math.log10(q_min) |
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39 | q_max = math.log10(q_max) |
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40 | q = np.logspace(q_min, q_max, nq) |
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41 | data = empty_data1D(q) |
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42 | calculator = DirectModel(data, model) |
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43 | Iq1D = calculator() |
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44 | |
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45 | ax.plot(q, Iq1D, color='blue', lw=2, label=model_info['name']) |
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46 | ax.set_xlabel(r'$Q \/(\AA^{-1})$') |
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47 | ax.set_ylabel(r'$I(Q) \/(\mathrm{cm}^{-1})$') |
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48 | ax.set_xscale(opts['xscale']) |
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49 | ax.set_yscale(opts['yscale']) |
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50 | #ax.legend(loc='best') |
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51 | |
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52 | def plot_2d(model, opts, ax): |
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53 | qx_max, nq2d = opts['qx_max'], opts['nq2d'] |
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54 | q = np.linspace(-qx_max, qx_max, nq2d) |
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55 | data2d = empty_data2D(q, resolution=0.0) |
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56 | calculator = DirectModel(data2d, model) |
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57 | Iq2D = calculator() #background=0) |
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58 | Iq2D = Iq2D.reshape(nq2d, nq2d) |
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59 | if opts['zscale'] == 'log': |
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60 | Iq2D = np.log(np.clip(Iq2D, opts['vmin'], np.inf)) |
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61 | h = ax.imshow(Iq2D, interpolation='nearest', aspect=1, origin='upper', |
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62 | extent=[-qx_max, qx_max, -qx_max, qx_max], cmap=ice_cm()) |
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63 | # , vmin=vmin, vmax=vmax) |
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64 | ax.set_xlabel(r'$Q_x \/(\AA^{-1})$') |
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65 | ax.set_ylabel(r'$Q_y \/(\AA^{-1})$') |
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66 | |
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67 | def ice_cm(): |
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68 | from matplotlib._cm import _Blues_data |
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69 | from matplotlib import colors |
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70 | from matplotlib import rcParams |
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71 | def from_white(segments): |
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72 | scale = 1.0/segments[0][1] |
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73 | return [(k, v*scale, w*scale) for k, v, w in segments] |
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74 | ice_data = dict((k,from_white(v)) for k,v in _Blues_data.items()) |
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75 | ice = colors.LinearSegmentedColormap("ice", ice_data, rcParams['image.lut']) |
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76 | return ice |
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77 | |
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78 | |
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79 | # Generate image (comment IF for 1D/2D for the moment) and generate only 1D |
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80 | fig_height = 3.0 # in |
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81 | fig_left = 0.6 # in |
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82 | fig_right = 0.5 # in |
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83 | fig_top = 0.6*0.25 # in |
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84 | fig_bottom = 0.6*0.75 |
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85 | if model_info['has_2d']: |
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86 | plot_height = fig_height - (fig_top+fig_bottom) |
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87 | plot_width = plot_height |
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88 | fig_width = 2*(plot_width + fig_left + fig_right) |
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89 | aspect = (fig_width, fig_height) |
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90 | ratio = aspect[0]/aspect[1] |
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91 | ax_left = fig_left/fig_width |
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92 | ax_bottom = fig_bottom/fig_height |
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93 | ax_height = plot_height/fig_height |
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94 | ax_width = ax_height/ratio # square axes |
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95 | fig = plt.figure(figsize=aspect) |
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96 | ax2d = fig.add_axes([0.5+ax_left, ax_bottom, ax_width, ax_height]) |
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97 | plot_2d(model, opts, ax2d) |
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98 | ax1d = fig.add_axes([ax_left, ax_bottom, ax_width, ax_height]) |
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99 | #ax.set_aspect('square') |
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100 | else: |
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101 | plot_height = fig_height - (fig_top+fig_bottom) |
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102 | plot_width = (1+np.sqrt(5))/2*fig_height |
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103 | fig_width = plot_width + fig_left + fig_right |
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104 | ax_left = fig_left/fig_width |
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105 | ax_bottom = fig_bottom/fig_height |
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106 | ax_width = plot_width/fig_width |
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107 | ax_height = plot_height/fig_height |
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108 | aspect = (fig_width, fig_height) |
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109 | fig = plt.figure(figsize=aspect) |
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110 | ax1d = fig.add_axes([ax_left, ax_bottom, ax_width, ax_height]) |
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111 | plot_1d(model, opts, ax1d) |
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112 | |
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113 | # Save image in model/img |
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114 | figname = model_name + '_autogenfig.png' |
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115 | filename = os.path.join('model', 'img', figname) |
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116 | plt.savefig(filename, bbox_inches='tight') |
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117 | #print "figure saved in",filename |
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118 | |
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119 | # Auto caption for figure |
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120 | captionstr = '\n' |
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121 | captionstr += '.. figure:: img/' + model_info['id'] + '_autogenfig.png\n' |
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122 | captionstr += '\n' |
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123 | captionstr += ' 1D plot corresponding to the default parameters of the model.\n' |
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124 | captionstr += '\n' |
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125 | |
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126 | # Add figure reference and caption to documentation (at end, before References) |
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127 | pattern = '\*\*REFERENCE' |
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128 | m = re.search(pattern, docstr.upper()) |
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129 | |
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130 | if m: |
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131 | docstr1 = docstr[:m.start()] |
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132 | docstr2 = docstr[m.start():] |
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133 | docstr = docstr1 + captionstr + docstr2 |
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134 | else: |
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135 | print '------------------------------------------------------------------' |
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136 | print 'References NOT FOUND for model: ', model_info['id'] |
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137 | print '------------------------------------------------------------------' |
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138 | docstr = docstr + captionstr |
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139 | |
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140 | open(sys.argv[2],'w').write(docstr) |
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