cansas_reader_HDF5.py @ 1b82623

ESS_GUIESS_GUI_DocsESS_GUI_batch_fittingESS_GUI_bumps_abstractionESS_GUI_iss1116ESS_GUI_iss879ESS_GUI_iss959ESS_GUI_openclESS_GUI_orderingESS_GUI_sync_sascalccostrafo411magnetic_scattrelease-4.1.1release-4.1.2release-4.2.2ticket-1009ticket-1094-headlessticket-1242-2d-resolutionticket-1243ticket-1249ticket885unittest-saveload

Last change on this file since 1b82623 was 5e906207, checked in by lewis, 8 years ago
Read all metadata from HDF5 files
Property mode set to `100644`
File size: 24.9 KB

Line
1	"""
2	CanSAS 2D data reader for reading HDF5 formatted CanSAS files.
3	"""
4
5	import h5py
6	import numpy as np
7	import re
8	import os
9	import sys
10
11	from sas.sascalc.dataloader.data_info import plottable_1D, plottable_2D, Data1D, Data2D, DataInfo, Process, Aperture
12	from sas.sascalc.dataloader.data_info import Collimation, TransmissionSpectrum, Detector
13	from sas.sascalc.dataloader.data_info import combine_data_info_with_plottable
14
15
16
17	class Reader():
18	"""
19	A class for reading in CanSAS v2.0 data files. The existing iteration opens Mantid generated HDF5 formatted files
20	with file extension .h5/.H5. Any number of data sets may be present within the file and any dimensionality of data
21	may be used. Currently 1D and 2D SAS data sets are supported, but future implementations will include 1D and 2D
22	SESANS data.
23
24	Any number of SASdata sets may be present in a SASentry and the data within can be either 1D I(Q) or 2D I(Qx, Qy).
25
26	Also supports reading NXcanSAS formatted HDF5 files
27
28	:Dependencies:
29	The CanSAS HDF5 reader requires h5py => v2.5.0 or later.
30	"""
31
32	## CanSAS version
33	cansas_version = 2.0
34	## Logged warnings or messages
35	logging = None
36	## List of errors for the current data set
37	errors = None
38	## Raw file contents to be processed
39	raw_data = None
40	## Data info currently being read in
41	current_datainfo = None
42	## SASdata set currently being read in
43	current_dataset = None
44	## List of plottable1D objects that should be linked to the current_datainfo
45	data1d = None
46	## List of plottable2D objects that should be linked to the current_datainfo
47	data2d = None
48	## Data type name
49	type_name = "CanSAS 2.0"
50	## Wildcards
51	type = ["CanSAS 2.0 HDF5 Files (.h5)\|.h5"]
52	## List of allowed extensions
53	ext = ['.h5', '.H5']
54	## Flag to bypass extension check
55	allow_all = False
56	## List of files to return
57	output = None
58
59	def read(self, filename):
60	"""
61	This is the general read method that all SasView data_loaders must have.
62
63	:param filename: A path for an HDF5 formatted CanSAS 2D data file.
64	:return: List of Data1D/2D objects and/or a list of errors.
65	"""
66	## Reinitialize the class when loading a new data file to reset all class variables
67	self.reset_class_variables()
68	## Check that the file exists
69	if os.path.isfile(filename):
70	basename = os.path.basename(filename)
71	_, extension = os.path.splitext(basename)
72	# If the file type is not allowed, return empty list
73	if extension in self.ext or self.allow_all:
74	## Load the data file
75	self.raw_data = h5py.File(filename, 'r')
76	## Read in all child elements of top level SASroot
77	self.read_children(self.raw_data, [])
78	## Add the last data set to the list of outputs
79	self.add_data_set()
80	## Close the data file
81	self.raw_data.close()
82	## Return data set(s)
83	return self.output
84
85	def reset_class_variables(self):
86	"""
87	Create the reader object and define initial states for class variables
88	"""
89	self.current_datainfo = None
90	self.current_dataset = None
91	self.data1d = []
92	self.data2d = []
93	self.raw_data = None
94	self.errors = set()
95	self.logging = []
96	self.output = []
97	self.parent_class = u''
98	self.detector = Detector()
99	self.collimation = Collimation()
100	self.aperture = Aperture()
101	self.process = Process()
102	self.trans_spectrum = TransmissionSpectrum()
103
104	def read_children(self, data, parent_list):
105	"""
106	A recursive method for stepping through the hierarchical data file.
107
108	:param data: h5py Group object of any kind
109	:param parent: h5py Group parent name
110	"""
111
112	## Loop through each element of the parent and process accordingly
113	for key in data.keys():
114	## Get all information for the current key
115	value = data.get(key)
116	if value.attrs.get(u'canSAS_class') is not None:
117	class_name = value.attrs.get(u'canSAS_class')
118	else:
119	class_name = value.attrs.get(u'NX_class')
120	if class_name is not None:
121	class_prog = re.compile(class_name)
122	else:
123	class_prog = re.compile(value.name)
124
125	if isinstance(value, h5py.Group):
126	self.parent_class = class_name
127	parent_list.append(key)
128	## If this is a new sasentry, store the current data sets and create a fresh Data1D/2D object
129	if class_prog.match(u'SASentry'):
130	self.add_data_set(key)
131	elif class_prog.match(u'SASdata'):
132	self._initialize_new_data_set(parent_list)
133	## Recursion step to access data within the group
134	self.read_children(value, parent_list)
135	self.add_intermediate()
136	parent_list.remove(key)
137
138	elif isinstance(value, h5py.Dataset):
139	## If this is a dataset, store the data appropriately
140	data_set = data[key][:]
141	unit = self._get_unit(value)
142
143	## I and Q Data
144	if key == u'I':
145	if type(self.current_dataset) is plottable_2D:
146	self.current_dataset.data = data_set
147	self.current_dataset.zaxis("Intensity", unit)
148	else:
149	self.current_dataset.y = data_set.flatten()
150	self.current_dataset.yaxis("Intensity", unit)
151	continue
152	elif key == u'Idev':
153	if type(self.current_dataset) is plottable_2D:
154	self.current_dataset.err_data = data_set.flatten()
155	else:
156	self.current_dataset.dy = data_set.flatten()
157	continue
158	elif key == u'Q':
159	self.current_dataset.xaxis("Q", unit)
160	if type(self.current_dataset) is plottable_2D:
161	self.current_dataset.q = data_set.flatten()
162	else:
163	self.current_dataset.x = data_set.flatten()
164	continue
165	elif key == u'Qy':
166	self.current_dataset.yaxis("Q_y", unit)
167	self.current_dataset.qy_data = data_set.flatten()
168	continue
169	elif key == u'Qydev':
170	self.current_dataset.dqy_data = data_set.flatten()
171	continue
172	elif key == u'Qx':
173	self.current_dataset.xaxis("Q_x", unit)
174	self.current_dataset.qx_data = data_set.flatten()
175	continue
176	elif key == u'Qxdev':
177	self.current_dataset.dqx_data = data_set.flatten()
178	continue
179	elif key == u'Mask':
180	self.current_dataset.mask = data_set.flatten()
181	continue
182
183	for data_point in data_set:
184	## Top Level Meta Data
185	if key == u'definition':
186	self.current_datainfo.meta_data['reader'] = data_point
187	elif key == u'run':
188	self.current_datainfo.run.append(data_point)
189	try:
190	run_name = value.attrs['name']
191	run_dict = {data_point: run_name}
192	self.current_datainfo.run_name = run_dict
193	except:
194	pass
195	elif key == u'title':
196	self.current_datainfo.title = data_point
197	elif key == u'SASnote':
198	self.current_datainfo.notes.append(data_point)
199
200	## Sample Information
201	elif key == u'Title' and self.parent_class == u'SASsample': # CanSAS 2.0 format
202	self.current_datainfo.sample.name = data_point
203	elif key == u'ID' and self.parent_class == u'SASsample': # NXcanSAS format
204	self.current_datainfo.sample.name = data_point
205	elif key == u'thickness' and self.parent_class == u'SASsample':
206	self.current_datainfo.sample.thickness = data_point
207	elif key == u'temperature' and self.parent_class == u'SASsample':
208	self.current_datainfo.sample.temperature = data_point
209	elif key == u'transmission' and self.parent_class == u'SASsample':
210	self.current_datainfo.sample.transmission = data_point
211	elif key == u'x_position' and self.parent_class == u'SASsample':
212	self.current_datainfo.sample.position.x = data_point
213	elif key == u'y_position' and self.parent_class == u'SASsample':
214	self.current_datainfo.sample.position.y = data_point
215	elif key == u'polar_angle' and self.parent_class == u'SASsample':
216	self.current_datainfo.sample.orientation.x = data_point
217	elif key == u'azimuthal_angle' and self.parent_class == u'SASsample':
218	self.current_datainfo.sample.orientation.z = data_point
219	elif key == u'details' and self.parent_class == u'SASsample':
220	self.current_datainfo.sample.details.append(data_point)
221
222	## Instrumental Information
223	elif key == u'name' and self.parent_class == u'SASinstrument':
224	self.current_datainfo.instrument = data_point
225	elif key == u'name' and self.parent_class == u'SASdetector':
226	self.detector.name = data_point
227	elif key == u'SDD' and self.parent_class == u'SASdetector':
228	self.detector.distance = float(data_point)
229	self.detector.distance_unit = unit
230	elif key == u'slit_length' and self.parent_class == u'SASdetector':
231	self.detector.slit_length = float(data_point)
232	self.detector.slit_length_unit = unit
233	elif key == u'x_position' and self.parent_class == u'SASdetector':
234	self.detector.offset.x = float(data_point)
235	self.detector.offset_unit = unit
236	elif key == u'y_position' and self.parent_class == u'SASdetector':
237	self.detector.offset.y = float(data_point)
238	self.detector.offset_unit = unit
239	elif key == u'polar_angle' and self.parent_class == u'SASdetector':
240	self.detector.orientation.x = float(data_point)
241	self.detector.orientation_unit = unit
242	elif key == u'azimuthal_angle' and self.parent_class == u'SASdetector':
243	self.detector.orientation.z = float(data_point)
244	self.detector.orientation_unit = unit
245	elif key == u'beam_center_x' and self.parent_class == u'SASdetector':
246	self.detector.beam_center.x = float(data_point)
247	self.detector.beam_center_unit = unit
248	elif key == u'beam_center_y' and self.parent_class == u'SASdetector':
249	self.detector.beam_center.y = float(data_point)
250	self.detector.beam_center_unit = unit
251	elif key == u'x_pixel_size' and self.parent_class == u'SASdetector':
252	self.detector.pixel_size.x = float(data_point)
253	self.detector.pixel_size_unit = unit
254	elif key == u'y_pixel_size' and self.parent_class == u'SASdetector':
255	self.detector.pixel_size.y = float(data_point)
256	self.detector.pixel_size_unit = unit
257	elif key == u'SSD' and self.parent_class == u'SAScollimation':
258	self.collimation.length = data_point
259	self.collimation.length_unit = unit
260	elif key == u'name' and self.parent_class == u'SAScollimation':
261	self.collimation.name = data_point
262
263	## Process Information
264	elif key == u'name' and self.parent_class == u'SASprocess':
265	self.process.name = data_point
266	elif key == u'Title' and self.parent_class == u'SASprocess': # CanSAS 2.0 format
267	self.process.name = data_point
268	elif key == u'name' and self.parent_class == u'SASprocess': # NXcanSAS format
269	self.process.name = data_point
270	elif key == u'description' and self.parent_class == u'SASprocess':
271	self.process.description = data_point
272	elif key == u'date' and self.parent_class == u'SASprocess':
273	self.process.date = data_point
274	elif self.parent_class == u'SASprocess':
275	self.process.notes.append(data_point)
276
277	## Transmission Spectrum
278	elif key == u'T' and self.parent_class == u'SAStransmission_spectrum':
279	self.trans_spectrum.transmission.append(data_point)
280	elif key == u'Tdev' and self.parent_class == u'SAStransmission_spectrum':
281	self.trans_spectrum.transmission_deviation.append(data_point)
282	elif key == u'lambda' and self.parent_class == u'SAStransmission_spectrum':
283	self.trans_spectrum.wavelength.append(data_point)
284
285	## Source
286	elif key == u'wavelength' and self.parent_class == u'SASdata':
287	self.current_datainfo.source.wavelength = data_point
288	self.current_datainfo.source.wavelength_unit = unit
289	elif key == u'incident_wavelength' and self.parent_class == u'SASsource':
290	self.current_datainfo.source.wavelength = data_point
291	self.current_datainfo.source.wavelength_unit = unit
292	elif key == u'wavelength_max' and self.parent_class == u'SASsource':
293	self.current_datainfo.source.wavelength_max = data_point
294	self.current_datainfo.source.wavelength_max_unit = unit
295	elif key == u'wavelength_min' and self.parent_class == u'SASsource':
296	self.current_datainfo.source.wavelength_min = data_point
297	self.current_datainfo.source.wavelength_min_unit = unit
298	elif key == u'wavelength_spread' and self.parent_class == u'SASsource':
299	self.current_datainfo.source.wavelength_spread = data_point
300	self.current_datainfo.source.wavelength_spread_unit = unit
301	elif key == u'beam_size_x' and self.parent_class == u'SASsource':
302	self.current_datainfo.source.beam_size.x = data_point
303	self.current_datainfo.source.beam_size_unit = unit
304	elif key == u'beam_size_y' and self.parent_class == u'SASsource':
305	self.current_datainfo.source.beam_size.y = data_point
306	self.current_datainfo.source.beam_size_unit = unit
307	elif key == u'beam_shape' and self.parent_class == u'SASsource':
308	self.current_datainfo.source.beam_shape = data_point
309	elif key == u'radiation' and self.parent_class == u'SASsource':
310	self.current_datainfo.source.radiation = data_point
311	elif key == u'transmission' and self.parent_class == u'SASdata':
312	self.current_datainfo.sample.transmission = data_point
313
314	## Everything else goes in meta_data
315	else:
316	new_key = self._create_unique_key(self.current_datainfo.meta_data, key)
317	self.current_datainfo.meta_data[new_key] = data_point
318
319	else:
320	## I don't know if this reachable code
321	self.errors.add("ShouldNeverHappenException")
322
323	def add_intermediate(self):
324	"""
325	This method stores any intermediate objects within the final data set after fully reading the set.
326
327	:param parent: The NXclass name for the h5py Group object that just finished being processed
328	"""
329
330	if self.parent_class == u'SASprocess':
331	self.current_datainfo.process.append(self.process)
332	self.process = Process()
333	elif self.parent_class == u'SASdetector':
334	self.current_datainfo.detector.append(self.detector)
335	self.detector = Detector()
336	elif self.parent_class == u'SAStransmission_spectrum':
337	self.current_datainfo.trans_spectrum.append(self.trans_spectrum)
338	self.trans_spectrum = TransmissionSpectrum()
339	elif self.parent_class == u'SAScollimation':
340	self.current_datainfo.collimation.append(self.collimation)
341	self.collimation = Collimation()
342	elif self.parent_class == u'SASaperture':
343	self.collimation.aperture.append(self.aperture)
344	self.aperture = Aperture()
345	elif self.parent_class == u'SASdata':
346	if type(self.current_dataset) is plottable_2D:
347	self.data2d.append(self.current_dataset)
348	elif type(self.current_dataset) is plottable_1D:
349	self.data1d.append(self.current_dataset)
350
351	def final_data_cleanup(self):
352	"""
353	Does some final cleanup and formatting on self.current_datainfo and all data1D and data2D objects and then
354	combines the data and info into Data1D and Data2D objects
355	"""
356
357	## Type cast data arrays to float64
358	if len(self.current_datainfo.trans_spectrum) > 0:
359	spectrum_list = []
360	for spectrum in self.current_datainfo.trans_spectrum:
361	spectrum.transmission = np.delete(spectrum.transmission, [0])
362	spectrum.transmission = spectrum.transmission.astype(np.float64)
363	spectrum.transmission_deviation = np.delete(spectrum.transmission_deviation, [0])
364	spectrum.transmission_deviation = spectrum.transmission_deviation.astype(np.float64)
365	spectrum.wavelength = np.delete(spectrum.wavelength, [0])
366	spectrum.wavelength = spectrum.wavelength.astype(np.float64)
367	if len(spectrum.transmission) > 0:
368	spectrum_list.append(spectrum)
369	self.current_datainfo.trans_spectrum = spectrum_list
370
371	## Append errors to dataset and reset class errors
372	self.current_datainfo.errors = self.errors
373	self.errors.clear()
374
375	## Combine all plottables with datainfo and append each to output
376	## Type cast data arrays to float64 and find min/max as appropriate
377	for dataset in self.data2d:
378	dataset.data = dataset.data.astype(np.float64)
379	dataset.err_data = dataset.err_data.astype(np.float64)
380	if dataset.qx_data is not None:
381	dataset.xmin = np.min(dataset.qx_data)
382	dataset.xmax = np.max(dataset.qx_data)
383	dataset.qx_data = dataset.qx_data.astype(np.float64)
384	if dataset.dqx_data is not None:
385	dataset.dqx_data = dataset.dqx_data.astype(np.float64)
386	if dataset.qy_data is not None:
387	dataset.ymin = np.min(dataset.qy_data)
388	dataset.ymax = np.max(dataset.qy_data)
389	dataset.qy_data = dataset.qy_data.astype(np.float64)
390	if dataset.dqy_data is not None:
391	dataset.dqy_data = dataset.dqy_data.astype(np.float64)
392	if dataset.q_data is not None:
393	dataset.q_data = dataset.q_data.astype(np.float64)
394	zeros = np.ones(dataset.data.size, dtype=bool)
395	try:
396	for i in range (0, dataset.mask.size - 1):
397	zeros[i] = dataset.mask[i]
398	except:
399	self.errors.add(sys.exc_value)
400	dataset.mask = zeros
401	## Calculate the actual Q matrix
402	try:
403	if dataset.q_data.size <= 1:
404	dataset.q_data = np.sqrt(dataset.qx_data * dataset.qx_data + dataset.qy_data * dataset.qy_data)
405	except:
406	dataset.q_data = None
407
408	if dataset.data.ndim == 2:
409	(n_rows, n_cols) = dataset.data.shape
410	dataset.y_bins = dataset.qy_data[0::n_cols]
411	dataset.x_bins = dataset.qx_data[:n_cols]
412	dataset.data = dataset.data.flatten()
413
414	final_dataset = combine_data_info_with_plottable(dataset, self.current_datainfo)
415	self.output.append(final_dataset)
416
417	for dataset in self.data1d:
418	if dataset.x is not None:
419	dataset.x = dataset.x.astype(np.float64)
420	dataset.xmin = np.min(dataset.x)
421	dataset.xmax = np.max(dataset.x)
422	if dataset.y is not None:
423	dataset.y = dataset.y.astype(np.float64)
424	dataset.ymin = np.min(dataset.y)
425	dataset.ymax = np.max(dataset.y)
426	if dataset.dx is not None:
427	dataset.dx = dataset.dx.astype(np.float64)
428	if dataset.dxl is not None:
429	dataset.dxl = dataset.dxl.astype(np.float64)
430	if dataset.dxw is not None:
431	dataset.dxw = dataset.dxw.astype(np.float64)
432	if dataset.dy is not None:
433	dataset.dy = dataset.dy.astype(np.float64)
434	final_dataset = combine_data_info_with_plottable(dataset, self.current_datainfo)
435	self.output.append(final_dataset)
436
437	def add_data_set(self, key=""):
438	"""
439	Adds the current_dataset to the list of outputs after preforming final processing on the data and then calls a
440	private method to generate a new data set.
441
442	:param key: NeXus group name for current tree level
443	"""
444
445	if self.current_datainfo and self.current_dataset:
446	self.final_data_cleanup()
447	self.data1d = []
448	self.data2d = []
449	self.current_datainfo = DataInfo()
450
451
452	def _initialize_new_data_set(self, parent_list = None):
453	"""
454	A private class method to generate a new 1D or 2D data object based on the type of data within the set.
455	Outside methods should call add_data_set() to be sure any existing data is stored properly.
456
457	:param parent_list: List of names of parent elements
458	"""
459
460	if parent_list is None:
461	parent_list = []
462	if self._find_intermediate(parent_list, "Qx"):
463	self.current_dataset = plottable_2D()
464	else:
465	x = np.array(0)
466	y = np.array(0)
467	self.current_dataset = plottable_1D(x, y)
468	self.current_datainfo.filename = self.raw_data.filename
469
470	def _find_intermediate(self, parent_list, basename=""):
471	"""
472	A private class used to find an entry by either using a direct key or knowing the approximate basename.
473
474	:param parent_list: List of parents to the current level in the HDF5 file
475	:param basename: Approximate name of an entry to search for
476	:return:
477	"""
478
479	entry = False
480	key_prog = re.compile(basename)
481	top = self.raw_data
482	for parent in parent_list:
483	top = top.get(parent)
484	for key in top.keys():
485	if (key_prog.match(key)):
486	entry = True
487	break
488	return entry
489
490	def _create_unique_key(self, dictionary, name, numb=0):
491	"""
492	Create a unique key value for any dictionary to prevent overwriting
493	Recurses until a unique key value is found.
494
495	:param dictionary: A dictionary with any number of entries
496	:param name: The index of the item to be added to dictionary
497	:param numb: The number to be appended to the name, starts at 0
498	:return: The new name for the dictionary entry
499	"""
500	if dictionary.get(name) is not None:
501	numb += 1
502	name = name.split("_")[0]
503	name += "_{0}".format(numb)
504	name = self._create_unique_key(dictionary, name, numb)
505	return name
506
507	def _get_unit(self, value):
508	"""
509	Find the unit for a particular value within the h5py dictionary
510
511	:param value: attribute dictionary for a particular value set
512	:return: unit for the value passed to the method
513	"""
514	unit = value.attrs.get(u'units')
515	if unit == None:
516	unit = value.attrs.get(u'unit')
517	## Convert the unit formats
518	if unit == "1/A":
519	unit = "A^{-1}"
520	elif unit == "1/cm":
521	unit = "cm^{-1}"
522	return unit

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SasView

source: sasview/src/sas/sascalc/dataloader/readers/cansas_reader_HDF5.py @ 1b82623

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