def write_example(filename): # --- prepare data --- # Generate fake data rawdata = np.ones(180 * 256 * 256, np.uint16).reshape(180, 256, 256) rawdata_white = np.ones(2 * 256 * 256, np.uint16).reshape(2, 256, 256) rawdata_dark = np.zeros(10 * 256 * 256, np.uint16).reshape(10, 256, 256) # x, y and z ranges x = np.arange(256) y = np.arange(256) z = np.arange(180); # --- create file --- # Open DataExchangeFile file f = DataExchangeFile(filename, mode='w') # Create core HDF5 dataset in exchange group for 180 deep stack # of x,y images /exchange/data f.add_entry([ DataExchangeEntry.data(data={'value':rawdata, 'units':'counts'}), DataExchangeEntry.data(data_dark={'value':rawdata_dark, 'units':'counts'}), DataExchangeEntry.data(data_white={'value':rawdata_white, 'units':'counts'}) ] ) # --- All done --- f.close()
def write_example(filename): # --- prepare data --- # Generate fake raw data rawdata = np.ones(180 * 256 * 256, np.uint16).reshape(180, 256, 256) # x, y and z ranges x = np.arange(128) y = np.arange(128) z = np.arange(180); # --- create file --- # Open DataExchange file f = DataExchangeFile(filename, mode='w') # Create core HDF5 dataset in exchange group for 180 deep stack of x,y # images /exchange/data data_en = DataExchangeEntry.data(data={'value': rawdata, 'units':'counts', 'description': 'Projection Data', 'dataset_opts': {'compression': 'gzip', 'compression_opts': 4} }) f.add_entry(data_en) # The default location for sample in DataExchangeEntry is /measurement/sample # To override the default set e.g 'root'='/measurement_4/sample' sample_en = DataExchangeEntry.sample(name={'value': 'Minivirus'}, temperature={'value': 200.0, 'units':'celsius', 'dataset_opts': {'dtype': 'd'}}) f.add_entry(sample_en) # --- All done --- f.close()
def write_example(filename): # --- prepare data --- # Generate fake data rawdata = np.ones(180 * 256 * 256, np.uint16).reshape(180, 256, 256) rawdata_white = np.ones(2 * 256 * 256, np.uint16).reshape(2, 256, 256) rawdata_dark = np.zeros(10 * 256 * 256, np.uint16).reshape(10, 256, 256) # x, y and z ranges x = np.arange(256) y = np.arange(256) z = np.arange(180) # Fabricated theta values theta = (z / float(180)) * 180.0 theta_white = (0.0, 180.0) theta_dark = (0.0, 0.0, 0.0, 0.0, 0.0, 180.0, 180.0, 180.0, 180.0, 180.0) # --- create file --- # Open HDF5 file f = DataExchangeFile(filename, mode='w') #Create HDF5 dataset in exchange group for data, data_dark & data_white, theta, theta_dark, theta_white under /exchange f.add_entry([ DataExchangeEntry.data(data={ 'value': rawdata, 'units': 'counts', 'axes': 'theta:y:x' }), DataExchangeEntry.data(data_dark={ 'value': rawdata_dark, 'units': 'counts', 'axes': 'theta:y:x' }), DataExchangeEntry.data(data_white={ 'value': rawdata_white, 'units': 'counts', 'axes': 'theta:y:x' }), DataExchangeEntry.data(theta={ 'value': theta, 'units': 'degrees' }), DataExchangeEntry.data(theta_dark={ 'value': theta_dark, 'units': 'degrees' }), DataExchangeEntry.data(theta_white={ 'value': theta_white, 'units': 'degrees' }) ]) # --- All done --- f.close()
def main(): file_name = '//local/data/esrf/scan.edf' dark_file_name = '/local/data/esrf/dark.edf' white_file_name = '/local/data/esrf/flat.edf' hdf5_file_name = '/local/data/esrf_test.h5' sample_name = 'esrf' verbose = True if verbose: print file_name if verbose: print white_file_name if verbose: print hdf5_file_name # if verbose: print log_file mydata = Convert() # Create minimal hdf5 file if verbose: print "Reading data ... " mydata.stack(file_name, hdf5_file_name = hdf5_file_name, white_file_name = white_file_name, dark_file_name = dark_file_name, projections_data_type = 'edf', white_data_type = 'edf', dark_data_type = 'edf', sample_name = sample_name ) if verbose: print "Done reading data ... " # Add extra metadata if available # Open DataExchange file f = DataExchangeFile(hdf5_file_name, mode='a') # Create HDF5 subgroup # /measurement/instrument f.add_entry( DataExchangeEntry.instrument(name={'value': 'ESRF'}) ) # Create HDF5 subgroup # /measurement/instrument/source f.add_entry( DataExchangeEntry.source(name={'value': 'ESRF'}, date_time={'value': "2014-12-05T19:42:13+0100"}, beamline={'value': "ID-19"}, ) ) # /measurement/experimenter f.add_entry( DataExchangeEntry.experimenter(name={'value':"Emmanuelle"}, role={'value':"Project PI"}, ) ) f.close() if verbose: print "Done converting ", file_name
def main(): file_name = '/local/data/databank/Diamond/projections_13429.hdf' hdf5_file_name = '/local/data/databank/dataExchange/microCT/Diamond_2bin.h5' verbose = True print "Input files base name: ", file_name print "Output data exchange file name: ", hdf5_file_name mydata = Convert() # Create minimal hdf5 file if verbose: print "Reading data ... " mydata.nexus(file_name, hdf5_file_name = hdf5_file_name, projections_start=20, projections_end=1820, projections_step=2, white_start=11, white_end=20, dark_start=1, dark_end=3, sample_name = 'unknown' ) if verbose: print "Done reading data ... " # Add extra metadata if available # Open DataExchange file f = DataExchangeFile(hdf5_file_name, mode='a') # Create HDF5 subgroup # /measurement/instrument f.add_entry( DataExchangeEntry.instrument(name={'value': 'Diamond I12'}) ) ### Create HDF5 subgroup ### /measurement/instrument/source f.add_entry( DataExchangeEntry.source(name={'value': "Diamond Light Source"}, date_time={'value': "2013-11-30T19:17:04+0100"}, beamline={'value': "JEEP I12"}, ) ) # Create HDF5 subgroup # /measurement/experimenter f.add_entry( DataExchangeEntry.experimenter(name={'value':"Michael Drakopoulos"}, role={'value':"Project PI"}, ) ) f.close() print "Done creating data exchange file: ", hdf5_file_name
def main(): file_name = '/local/data/databank/APS_13_BM/run2_soln1_2_.SPE' hdf5_file_name = '/local/data/databank/dataExchange/microCT/run2_soln1_2.h5' verbose = True if verbose: print "Input files base name: ", file_name if verbose: print "Output data exchange file name: ", hdf5_file_name mydata = Convert() # Create minimal hdf5 file if verbose: print "Reading data ... " mydata.multiple_stack(file_name, hdf5_file_name = hdf5_file_name, projections_start=2, projections_end=7, projections_step=2, white_start=1, white_end=8, white_step=2, sample_name = 'Stripe_Solder_Sample_Tip1' ) if verbose: print "Done reading data ... " # Add extra metadata if available # Open DataExchange file f = DataExchangeFile(hdf5_file_name, mode='a') # Create HDF5 subgroup # /measurement/instrument f.add_entry( DataExchangeEntry.instrument(name={'value': 'APS 13-BM'}) ) ### Create HDF5 subgroup ### /measurement/instrument/source f.add_entry( DataExchangeEntry.source(name={'value': "Advanced Photon Source"}, date_time={'value': "2013-11-30T19:17:04+0100"}, beamline={'value': "13-BM"}, ) ) # Create HDF5 subgroup # /measurement/experimenter f.add_entry( DataExchangeEntry.experimenter(name={'value':"Mark Rivers"}, role={'value':"Project PI"}, ) ) f.close() if verbose: print "Done creating data exchange file: ", hdf5_file_name
def main(): file_name = '/local/data/databank/Diamond/projections_13429.hdf' hdf5_file_name = '/local/data/databank/dataExchange/microCT/Diamond_2bin.h5' mydata = Convert() # Create minimal hdf5 file if verbose: print "Reading data ... " mydata.nexus(file_name, hdf5_file_name = hdf5_file_name, projections_start=20, projections_end=1820, projections_step=2, white_start=11, white_end=20, dark_start=1, dark_end=3, sample_name = 'unknown' ) # Add extra metadata if available / desired # Open DataExchange file f = DataExchangeFile(hdf5_file_name, mode='a') # Create HDF5 subgroup # /measurement/instrument f.add_entry( DataExchangeEntry.instrument(name={'value': 'Diamond I12'}) ) ### Create HDF5 subgroup ### /measurement/instrument/source f.add_entry( DataExchangeEntry.source(name={'value': "Diamond Light Source"}, date_time={'value': "2013-11-30T19:17:04+0100"}, beamline={'value': "JEEP I12"}, ) ) # Create HDF5 subgroup # /measurement/experimenter f.add_entry( DataExchangeEntry.experimenter(name={'value':"Michael Drakopoulos"}, role={'value':"Project PI"}, ) ) f.close() print "Done creating data exchange file: ", hdf5_file_name
def write_example(filename): # --- prepare data --- # Generate fake raw data rawdata = np.ones(180 * 256 * 256, np.uint16).reshape(180, 256, 256) # x, y and z ranges x = np.arange(128) y = np.arange(128) z = np.arange(180); # --- create file --- # Open HDF5 file f = DataExchangeFile(filename, mode='w') # Create core HDF5 dataset in exchange group for 180 deep stack of x,y # images /exchange/data f.add_entry( DataExchangeEntry.data(data={'value': rawdata, 'units':'counts', 'description': 'Projection Data', 'dataset_opts': {'compression': 'gzip', 'compression_opts': 4} }) ) # Create HDF5 subgroup # /measurement/sample f.add_entry( DataExchangeEntry.sample(name={'value': 'Minivirus'}, temperature={'value': 200.0, 'units':'celsius', 'dataset_opts': {'dtype': 'd'}}) ) # Create HDF5 subgroup # /measurement/instrument f.add_entry( DataExchangeEntry.instrument(name={'value': 'APS 2-BM'}) ) # Create HDF5 subgroup # /measurement/instrument/monochromator f.add_entry( DataExchangeEntry.monochromator(name={'value': 'DMM'}, energy={'value': 10.00, 'units':'keV', 'dataset_opts': {'dtype':'d'}})) # --- All done --- f.close()
def write_example(filename): # --- prepare data --- # Generate fake data rawdata = np.ones(180 * 256 * 256, np.uint16).reshape(180, 256, 256) # x, y and z ranges x = np.arange(256) y = np.arange(256) z = np.arange(180); # --- create file --- # Open DataExchange file f = DataExchangeFile(filename, mode='w') # Create a DataExchangeEntry and dd the entry to the data exchange file. f.add_entry(DataExchangeEntry.data(data={'value':rawdata, 'units':'counts'})) # --- All done --- f.close()
def write_example(filename): # --- prepare data --- # Generate fake data rawdata = np.ones(180 * 256 * 256, np.uint16).reshape(180, 256, 256) rawdata_white = np.ones(2 * 256 * 256, np.uint16).reshape(2, 256, 256) rawdata_dark = np.zeros(10 * 256 * 256, np.uint16).reshape(10, 256, 256) # x, y and z ranges x = np.arange(256) y = np.arange(256) z = np.arange(180); # Fabricated theta values theta = (z / float(180)) * 180.0 theta_white = (0.0, 180.0) theta_dark = (0.0, 0.0, 0.0, 0.0, 0.0, 180.0, 180.0, 180.0, 180.0, 180.0) # --- create file --- # Open HDF5 file f = DataExchangeFile(filename, mode='w') #Create HDF5 dataset in exchange group for data, data_dark & data_white, theta, theta_dark, theta_white under /exchange f.add_entry([ DataExchangeEntry.data(data={'value':rawdata, 'units':'counts', 'axes': 'theta:y:x'}), DataExchangeEntry.data(data_dark={'value':rawdata_dark, 'units':'counts', 'axes': 'theta:y:x'}), DataExchangeEntry.data(data_white={'value':rawdata_white, 'units':'counts', 'axes': 'theta:y:x'}), DataExchangeEntry.data(theta={'value':theta, 'units':'degrees'}), DataExchangeEntry.data(theta_dark={'value':theta_dark, 'units':'degrees'}), DataExchangeEntry.data(theta_white={'value':theta_white, 'units':'degrees'}) ]) # --- All done --- f.close()
def main(): file_name = '/local/data/databank/TXM_26ID/Miller1/ABR_1SP_.tif' #dark_file_name = '/local/data/databank/AS/Mayo_tooth_AS/BG__AFTER_.tif' #white_file_name = '/local/data/databank/AS/Mayo_tooth_AS/BG__BEFORE_.tif' hdf5_file_name = '/local/data/databank/dataExchange/TXM/TXM_APS26IDMiller1.h5' sample_name = 'Teeth' projections_start = 0 projections_end = 361 white_start = 0 white_end = 0 white_step = 1 dark_start = 0 dark_end = 0 dark_step = 1 verbose = True if verbose: print "Input projection base name: ", file_name #if verbose: print "Input white base name: ", white_file_name #if verbose: print "Input dark base name: ", dark_file_name if verbose: print "Output data exchange file name: ", hdf5_file_name mydata = Convert() # Create minimal hdf5 file mydata.series_of_images(file_name, hdf5_file_name, projections_start, projections_end, #white_file_name = white_file_name, white_start = white_start, white_end = white_end, white_step = white_step, #dark_file_name = dark_file_name, #dark_start = dark_start, #dark_end = dark_end, #dark_step = dark_step, #sample_name = sample_name, projections_digits = 4, #white_digits = 2, #dark_digits = 2, projections_zeros = True, verbose = False ) if verbose: print "Done reading data ... " # Add extra metadata if available # Open DataExchange file f = DataExchangeFile(hdf5_file_name, mode='a') # Create HDF5 subgroup # /measurement/instrument f.add_entry( DataExchangeEntry.instrument(name={'value': 'Australian Synchrotron Facility'}) ) # Create HDF5 subgroup # /measurement/instrument/source f.add_entry( DataExchangeEntry.source(name={'value': 'Australian Synchrotron FacilityI'}, date_time={'value': "2013-10-19T22:22:13+0100"}, beamline={'value': "Tomography"}, ) ) # /measurement/experimenter f.add_entry( DataExchangeEntry.experimenter(name={'value':"Sherry Mayo"}, role={'value':"Project PI"}, ) ) f.close() if verbose: print "Done creating data exchange file: ", hdf5_file_name
def main(): ##file_name = '/local/data/databank/SLS_2011/Blakely_SLS/Blakely.tif' ##log_file = '/local/data/databank/SLS_2011/Blakely_SLS/Blakely.log' ## ##hdf5_file_name = '/local/data/databank/dataExchange/microCT/Blakely_SLS_2011.h5' file_name = '/local/data/databank/SLS_2011/Hornby_SLS/Hornby_b.tif' log_file = '/local/data/databank/SLS_2011/Hornby_SLS/Hornby.log' hdf5_file_name = '/local/data/databank/dataExchange/microCT/Hornby_SLS_2011.h5' verbose = True if verbose: print file_name if verbose: print log_file if verbose: print hdf5_file_name #Read input SLS data file = open(log_file, 'r') if verbose: print '###############################' for line in file: if 'Number of darks' in line: NumberOfDarks = re.findall(r'\d+', line) if verbose: print 'Number of Darks', NumberOfDarks[0] if 'Number of flats' in line: NumberOfFlats = re.findall(r'\d+', line) if verbose: print 'Number of Flats', NumberOfFlats[0] if 'Number of projections' in line: NumberOfProjections = re.findall(r'\d+', line) if verbose: print 'Number of Projections', NumberOfProjections[0] if 'Number of inter-flats' in line: NumberOfInterFlats = re.findall(r'\d+', line) if verbose: print 'Number of inter-flats', NumberOfInterFlats[0] if 'Inner scan flag' in line: InnerScanFlag = re.findall(r'\d+', line) if verbose: print 'Inner scan flag', InnerScanFlag[0] if 'Flat frequency' in line: FlatFrequency = re.findall(r'\d+', line) if verbose: print 'Flat frequency', FlatFrequency[0] if 'Rot Y min' in line: RotYmin = re.findall(r'\d+.\d+', line) if verbose: print 'Rot Y min', RotYmin[0] if 'Rot Y max' in line: RotYmax = re.findall(r'\d+.\d+', line) if verbose: print 'Rot Y max', RotYmax[0] if 'Angular step' in line: AngularStep = re.findall(r'\d+.\d+', line) if verbose: print 'Angular step', AngularStep[0] if verbose: print '###############################' file.close() dark_start = 1 dark_end = int(NumberOfDarks[0]) + 1 white_start = dark_end white_end = white_start + int(NumberOfFlats[0]) projections_start = white_end projections_end = projections_start + int(NumberOfProjections[0]) if verbose: print dark_start, dark_end if verbose: print white_start, white_end if verbose: print projections_start, projections_end dark_start = 1 dark_end = 21 white_start = 21 white_end = 221 projections_start = 221 projections_end = 1662 ### if testing uncomment ##dark_end = 4 ##white_end = 24 ##projections_end = 224 mydata = Convert() # Create minimal hdf5 file mydata.series_of_images(file_name, hdf5_file_name, projections_start, projections_end, white_start = white_start, white_end = white_end, dark_start = dark_start, dark_end = dark_end, verbose = False ) # Add extra metadata if available # Open DataExchange file f = DataExchangeFile(hdf5_file_name, mode='a') # Create HDF5 subgroup # /measurement/instrument f.add_entry( DataExchangeEntry.instrument(name={'value': 'Tomcat'}) ) # Create HDF5 subgroup # /measurement/instrument/source f.add_entry( DataExchangeEntry.source(name={'value': 'Swiss Light Source'}, date_time={'value': "2010-11-08T14:51:56+0100"}, beamline={'value': "Tomcat"}, current={'value': 401.96, 'units': 'mA', 'dataset_opts': {'dtype': 'd'}}, ) ) # Create HDF5 subgroup # /measurement/instrument/monochromator f.add_entry( DataExchangeEntry.monochromator(type={'value': 'Multilayer'}, energy={'value': 19.260, 'units': 'keV', 'dataset_opts': {'dtype': 'd'}}, mono_stripe={'value': 'Ru/C'}, ) ) # Create HDF5 subgroup # /measurement/experimenter f.add_entry( DataExchangeEntry.experimenter(name={'value':"Federica Marone"}, role={'value':"Project PI"}, affiliation={'value':"Swiss Light Source"}, phone={'value':"+41 56 310 5318"}, email={'value':"*****@*****.**"}, ) ) # Create HDF5 subgroup # /measurement/instrument/detector f.add_entry( DataExchangeEntry.detector(manufacturer={'value':'CooKe Corporation'}, model={'value': 'pco dimax'}, serial_number={'value': '1234XW2'}, bit_depth={'value': 12, 'dataset_opts': {'dtype': 'd'}}, x_pixel_size={'value': 6.7e-6, 'dataset_opts': {'dtype': 'f'}}, y_pixel_size={'value': 6.7e-6, 'dataset_opts': {'dtype': 'f'}}, x_dimensions={'value': 2048, 'dataset_opts': {'dtype': 'i'}}, y_dimensions={'value': 2048, 'dataset_opts': {'dtype': 'i'}}, x_binning={'value': 1, 'dataset_opts': {'dtype': 'i'}}, y_binning={'value': 1, 'dataset_opts': {'dtype': 'i'}}, operating_temperature={'value': 270, 'units':'K', 'dataset_opts': {'dtype': 'f'}}, exposure_time={'value': 170, 'units':'ms', 'dataset_opts': {'dtype': 'd'}}, frame_rate={'value': 3, 'dataset_opts': {'dtype': 'i'}}, output_data={'value':'/exchange'} ) ) f.add_entry(DataExchangeEntry.objective(magnification={'value':10, 'dataset_opts': {'dtype': 'd'}}, ) ) f.add_entry(DataExchangeEntry.scintillator(name={'value':'LuAg '}, type={'value':'LuAg'}, scintillating_thickness={'value':20e-6, 'dataset_opts': {'dtype': 'd'}}, ) ) # Create HDF5 subgroup # /measurement/experiment f.add_entry( DataExchangeEntry.experiment( proposal={'value':"e11218"}, ) ) f.close() if verbose: print "Done converting ", file_name
def write_example(filename): # --- prepare data --- # Generate fake raw data rawdata = np.ones(180 * 256 * 256, np.uint16).reshape(180, 256, 256) rawdata_white = np.ones(2 * 256 * 256, np.uint16).reshape(2, 256, 256) rawdata_dark = np.zeros(10 * 256 * 256, np.uint16).reshape(10, 256, 256) # Generate fake normalized data normalizeddata = np.ones(180 * 256 * 256, \ np.float64).reshape(180, 256, 256) # Generate fake reconstructed data reconstructeddata = np.ones(256 * 256 * 256, \ np.float64).reshape(256, 256, 256) # x, y and z ranges x = np.arange(128) y = np.arange(128) z = np.arange(180); # Fabricated theta values theta = (z / float(180)) * 180.0 theta_white = (0.0, 180.0) theta_dark = (0.0, 0.0, 0.0, 0.0, 0.0, 180.0, 180.0, 180.0, 180.0, 180.0) # Fabricated data_shift_x and data_shift_y value data_shift_x = np.random.randint(-100, 100, size=180) data_shift_y = np.random.randint(-100, 100, size=180) # --- create file --- print filename # Open DataExchange file f = DataExchangeFile(filename, mode='w') # Create core HDF5 dataset in exchange group for 180 deep stack # of x,y images /exchange/data f.add_entry( DataExchangeEntry.data(data={'value': rawdata, 'units':'counts', 'description': 'transmission', 'axes':'theta:y:x', 'dataset_opts': {'compression': 'gzip', 'compression_opts': 4} }) ) f.add_entry( DataExchangeEntry.data(title={'value': 'tomography_raw_projections'})) f.add_entry( DataExchangeEntry.data(data_dark={'value':rawdata_dark, 'units':'counts', 'axes':'theta_dark:y:x', 'dataset_opts': {'compression': 'gzip', 'compression_opts': 4} }) ) f.add_entry( DataExchangeEntry.data(data_white={'value': rawdata_white, 'units':'counts', 'axes':'theta_white:y:x', 'dataset_opts': {'compression': 'gzip', 'compression_opts': 4} }) ) f.add_entry( DataExchangeEntry.data(theta={'value': theta, 'units':'degrees'})) f.add_entry( DataExchangeEntry.data(theta_dark={'value': theta_dark, 'units':'degrees'})) f.add_entry( DataExchangeEntry.data(theta_white={'value': theta_white, 'units':'degrees'})) f.add_entry( DataExchangeEntry.data(data_shift_x={'value': data_shift_x})) f.add_entry( DataExchangeEntry.data(data_shift_y={'value': data_shift_y})) # Exchange HDF5 group # /exchange_2 # this will be the out_put of the normalization process f.add_entry( DataExchangeEntry.data(root='exchange_2', title={'value': 'tomography normalized projections'}) ) f.add_entry( DataExchangeEntry.data(root='exchange_2', data={'value': normalizeddata, 'units':'counts', 'axes':'theta:y:x', 'dataset_opts': {'compression': 'gzip', 'compression_opts': 4} }) ) f.add_entry( DataExchangeEntry.data(root='exchange_2', theta={'value': theta, 'units':'degrees'})) # Exchange HDF5 group # /exchange_3 # this will be the out_put of the reconstruction process f.add_entry( DataExchangeEntry.data(root='exchange_3', title={'value': 'tomography reconstructions'}) ) f.add_entry( DataExchangeEntry.data(root='exchange_3', data={'value': reconstructeddata, 'units':'density', 'axes':'z:y:x', 'dataset_opts': {'compression': 'gzip', 'compression_opts': 4} }) ) # Create HDF5 group measurement # /measuremen f.add_entry( DataExchangeEntry.instrument(name={'value': 'APS 2-BM'}) ) # Create HDF5 subgroup # /measurement/instrument/source f.add_entry( DataExchangeEntry.source(name={'value': 'APS'}, date_time={'value': "2012-07-31T21:15:23+0600"}, beamline={'value': "2-BM"}, current={'value': 101.199, 'units': 'mA', 'dataset_opts': {'dtype': 'd'}}, energy={'value': 7.0, 'units':'GeV', 'dataset_opts': {'dtype': 'd'}}, mode={'value':'TOPUP'} ) ) # Create HDF5 subgroup # /measurement/instrument/attenuator f.add_entry( DataExchangeEntry.attenuator(thickness={'value': 1e-3, 'units': 'm', 'dataset_opts': {'dtype': 'd'}}, type={'value': 'Al'} ) ) # Create HDF5 subgroup # /measurement/instrument/monochromator f.add_entry( DataExchangeEntry.monochromator(type={'value': 'Multilayer'}, energy={'value': 19.26, 'units': 'keV', 'dataset_opts': {'dtype': 'd'}}, energy_error={'value': 1e-3, 'units': 'keV', 'dataset_opts': {'dtype': 'd'}}, mono_stripe={'value': 'Ru/C'}, ) ) # Create HDF5 subgroup # /measurement/instrument/detector f.add_entry( DataExchangeEntry.detector(manufacturer={'value':'CooKe Corporation'}, model={'value': 'pco dimax'}, serial_number={'value': '1234XW2'}, bit_depth={'value': 12, 'dataset_opts': {'dtype': 'd'}}, x_pixel_size={'value': 6.7e-6, 'dataset_opts': {'dtype': 'f'}}, y_pixel_size={'value': 6.7e-6, 'dataset_opts': {'dtype': 'f'}}, x_dimensions={'value': 2048, 'dataset_opts': {'dtype': 'i'}}, y_dimensions={'value': 2048, 'dataset_opts': {'dtype': 'i'}}, x_binning={'value': 1, 'dataset_opts': {'dtype': 'i'}}, y_binning={'value': 1, 'dataset_opts': {'dtype': 'i'}}, operating_temperature={'value': 270, 'units':'K', 'dataset_opts': {'dtype': 'f'}}, exposure_time={'value': 170, 'units':'ms', 'dataset_opts': {'dtype': 'd'}}, frame_rate={'value': 3, 'dataset_opts': {'dtype': 'i'}}, output_data={'value':'/exchange'} ) ) f.add_entry( DataExchangeEntry.roi(name={'value':'Center Third'}, x1={'value':256, 'dataset_opts': {'dtype': 'i'}}, x2={'value':1792, 'dataset_opts': {'dtype': 'i'}}, y1={'value':256, 'dataset_opts': {'dtype': 'i'}}, y2={'value':1792, 'dataset_opts': {'dtype': 'i'}}, ) ) f.add_entry(DataExchangeEntry.objective(manufacturer={'value':'Zeiss'}, model={'value':'Plan-NEOFLUAR 1004-072'}, magnification={'value':20, 'dataset_opts': {'dtype': 'd'}}, numerical_aperture={'value':0.5, 'dataset_opts': {'dtype': 'd'}}, ) ) f.add_entry(DataExchangeEntry.scintillator(manufacturer={'value':'Crytur'}, serial_number={'value':'12'}, name={'value':'YAG polished'}, type={'value':'YAG on YAG'}, scintillating_thickness={'value':5e-6, 'dataset_opts': {'dtype': 'd'}}, substrate_thickness={'value':1e-4, 'dataset_opts': {'dtype': 'd'}}, ) ) # Create HDF5 subgroup # /measurement/sample f.add_entry( DataExchangeEntry.sample( name={'value':'Hornby_b'}, description={'value':'test sample'}, preparation_date={'value':'2011-07-31T21:15:23+0600'}, chemical_formula={'value':'unknown'}, mass={'value':0.25, 'units':'g', 'dataset_opts': {'dtype': 'd'}}, enviroment={'value':'air'}, temperature={'value':120.0, 'units':'Celsius', 'dataset_opts': {'dtype': 'd'}}, temperature_set={'value':130.0, 'units':'Celsius', 'dataset_opts': {'dtype': 'd'}}, ) ) # Create HDF5 subgroup # /measurement/sample/geometry/translation f.add_entry( DataExchangeEntry.translation(root='/measurement/sample/geometry', distances={'value':[0,0,0],'axes':'z:y:x', 'units':'m', 'dataset_opts': {'dtype': 'd'}} ) ) # Create HDF5 subgroup # /measurement/experimenter f.add_entry( DataExchangeEntry.experimenter(name={'value':"John Doe"}, role={'value':"Project PI"}, affiliation={'value':"University of California, Berkeley"}, address={'value':"EPS UC Berkeley CA 94720 4767 USA"}, phone={'value':"+1 123 456 0000"}, email={'value':"*****@*****.**"}, facility_user_id={'value':"a123456"}, ) ) # Create HDF5 subgroup # /measurement/experiment f.add_entry( DataExchangeEntry.experiment( proposal={'value':"1234"}, activity={'value':"e11218"}, safety={'value':"9876"}, ) ) # --- All done --- f.close()
def pack_data_exchange(): f = DataExchangeFile(CXP.io.data_exchange_filename, mode='w') sim = DataExchangeEntry.simulation( name={'value': 'Simulated Ptycho Data.'}, energy={ 'value': CXP.experiment.energy, 'units': 'keV' }, focusing_optic={'value': CXP.experiment.optic}, probe_modes={'value': CXP.reconstruction.probe_modes}, noise_model={'value': CXP.simulation.noise_model}, gaussian_noise_level={'value': CXP.simulation.gaussian_noise_level}, total_photons={'value': CXP.simulation.total_photons}, beam_stop={'value': CXP.simulation.beam_stop}, beam_stop_size={'value': CXP.simulation.beam_stop_size}, beam_stop_attenuation={'value': CXP.simulation.beam_stop_attenuation}, defocus={'value': CXP.simulation.defocus}, position_jitter={ 'value': CXP.reconstruction.initial_position_jitter_radius, 'units': 'pixels' }) f.add_entry(sim) sample = DataExchangeEntry.sample( root='/simulation', name={'value': 'ground truth sample complex amplitude'}, data={ 'value': cxph.sample.data[0], 'units': 'sqrt(counts)' }, ) f.add_entry(sample) probe = DataExchangeEntry.sample( root='/simulation', entry_name='probe', ) for mode in range(CXP.reconstruction.probe_modes): setattr(probe, 'mode_{:d}'.format(mode), { 'value': cxph.input_probe.modes[mode].data[0], 'units': 'counts' }) f.add_entry(probe) detector = DataExchangeEntry.detector( root='/simulation', x_pixel_size={'value': CXP.experiment.dx_d}, y_pixel_size={'value': CXP.experiment.dx_d}, x_dimension={'value': CXP.experiment.px}, y_dimension={'value': CXP.experiment.py}, distance={'value': CXP.experiment.z}, basis_vectors={ 'value': [[0, -CXP.experiment.dx_d, 0], [-CXP.experiment.dx_d, 0, 0]] }, corner_position={'value': [0, 0, 0]}) f.add_entry(detector) data = DataExchangeEntry.data( name={'value': 'simulated_data'}, data={ 'value': sp.array(cxph.det_mod.data), 'axes': 'translation:y:x', 'units': 'counts', 'dataset_opts': { 'compression': 'gzip', 'compression_opts': 4 } }, translation={'value': '/exchange/sample/geometry/translation'}) f.add_entry(data) # Get scan positions into dex format pos = sp.zeros((cxph.positions.total, 3)) y, x = cxph.positions.correct for i in range(cxph.positions.total): pos[i, 0], pos[i, 1] = x[i] * CXP.dx_s, y[i] * CXP.dx_s positions = DataExchangeEntry.translation( root='/exchange/sample/geometry', name={'value': 'ptychography scan positions'}, scan_type={'value': CXP.measurement.ptycho_scan_type}, data={ 'value': pos, 'units': 'm' }) f.add_entry(positions) f.close()
def main(): file_name = '/local/data/databank/TXM_26ID/20130731_004_Stripe_Solder_Sample_Tip1_TomoScript_181imgs_p1s_b1.txrm' white_file_name = '/local/data/databank/TXM_26ID/20130731_001_Background_Reference_20imgs_p5s_b1.xrm' hdf5_file_name = '/local/data/databank/dataExchange/TXM/20130731_004_Stripe_Solder_Sample_Tip1_nx.h5' log_file = '/local/data/databank/dataExchange/TXM/20130731_004_Stripe_Solder_Sample_Tip1.log' mydata = Convert() # Create minimal hdf5 file if verbose: print "Reading data ... " mydata.stack(file_name, hdf5_file_name=hdf5_file_name, white_file_name=white_file_name, sample_name='Stripe_Solder_Sample_Tip1') # Add extra metadata if available / desired reader = xradia.xrm() array = dstruct reader.read_txrm(file_name, array) # Read angles n_angles = np.shape(array.exchange.angles) if verbose: print "Done reading ", n_angles, " angles" theta = np.zeros(n_angles) theta = array.exchange.angles[:] # Save any other available metadata in a log file f = open(log_file, 'w') f.write('Data creation date: \n') f.write(str(array.information.file_creation_datetime)) f.write('\n') f.write('=======================================\n') f.write('Sample name: \n') f.write(str(array.information.sample.name)) f.write('\n') f.write('=======================================\n') f.write('Experimenter name: \n') f.write(str(array.information.experimenter.name)) f.write('\n') f.write('=======================================\n') f.write('X-ray energy: \n') f.write(str(array.exchange.energy)) f.write(str(array.exchange.energy_units)) f.write('\n') f.write('=======================================\n') f.write('Angles: \n') f.write(str(array.exchange.angles)) f.write('\n') f.write('=======================================\n') f.write('Data axes: \n') f.write(str(array.exchange.data_axes)) f.write('\n') f.write('=======================================\n') f.write('x distance: \n') f.write(str(array.exchange.x)) f.write('\n') f.write('=======================================\n') f.write('x units: \n') f.write(str(array.exchange.x_units)) f.write('\n') f.write('=======================================\n') f.write('y distance: \n') f.write(str(array.exchange.y)) f.write('\n') f.write('=======================================\n') f.write('y units: \n') f.write(str(array.exchange.y_units)) f.write('\n') f.close() # Open DataExchange file f = DataExchangeFile(hdf5_file_name, mode='a') # Create HDF5 subgroup # /measurement/instrument f.add_entry(DataExchangeEntry.instrument(name={'value': 'APS-CNM 26-ID'})) ### Create HDF5 subgroup ### /measurement/instrument/source f.add_entry( DataExchangeEntry.source( name={'value': "Advanced Photon Source"}, date_time={'value': "2013-07-31T19:42:13+0100"}, beamline={'value': "26-ID"}, )) # Create HDF5 subgroup # /measurement/instrument/monochromator f.add_entry( DataExchangeEntry.monochromator( type={'value': 'Unknown'}, energy={ 'value': float(array.exchange.energy[0]), 'units': 'keV', 'dataset_opts': { 'dtype': 'd' } }, mono_stripe={'value': 'Unknown'}, )) # Create HDF5 subgroup # /measurement/experimenter f.add_entry( DataExchangeEntry.experimenter( name={'value': "Robert Winarski"}, role={'value': "Project PI"}, )) # Create HDF5 subgroup # /measurement/sample f.add_entry( DataExchangeEntry.data(theta={ 'value': theta, 'units': 'degrees' })) f.close() print "Done creating data exchange file: ", hdf5_file_name
def create_theta_stack(filenames, output_filename): shutil.copy(filenames[0], output_filename) f_tomo = DataExchangeFile(output_filename, mode='a') # Stackable datasets # I will create a theta stack for every dataset which has a root entry called 'exchange' and 'exchange_N' with DataExchangeFile(filenames[0], mode='r') as f_dex: stackable_datasets = [dataset for dataset in f_dex.keys() if dataset.find('exchange_')>-1] print 'Found {:d} stackable datasets: '.format(len(stackable_datasets)), stackable_datasets for dataset in stackable_datasets: print 'Adding {:s}'.format(dataset) # loop through all files to determine the image sizes that will be stacked. angles = {} shapes = [] for filename in filenames: f_dex = DataExchangeFile(filename, mode='r') angles[f_dex['/exchange_0/angle'].value] = (filename, f_dex['/'.join([dataset, 'data'])].shape) shapes.append(f_dex['/'.join([dataset, 'data'])].shape) f_dex.close() shapes = list(set(shapes)) print 'Found {:d} different array shapes: '.format(len(shapes)), shapes[0] # Find the max array size if len(shapes)>1: xmin, ymin = 0,0 for dim in shapes[0]: if dim[1]>xmin: xmin=dim[1] if dim[2]>ymin: ymin=dim[2] else: channels, xmin, ymin = shapes[0] array_shape = [len(filenames), channels, xmin, ymin] # Need to add the DataExchange entry in non-standard way because arrays are so large they can't # be held in memory simultaneously. So I create a dataset with a single array and the resize # it to the right shape. Then arrays can be added individually. try: del f_tomo[dataset+'/data'] except KeyError: pass if dataset == 'exchange_0': try: del f_tomo[dataset+'/angle'] except KeyError: pass for i_theta, angle in enumerate(sorted(angles.keys(), key=float)): print 'Adding angle {:s}'.format(angle) with DataExchangeFile(angles[angle][0], mode='r') as f_dex: if i_theta==0: ashape = list(f_dex[dataset+'/data'].shape) ashape.insert(0,1) entry = DataExchangeEntry.data( root='/'+dataset, data={ 'value': sp.zeros(ashape), 'units': f_dex['/'.join([dataset, 'data'])].attrs['units'], 'description': f_dex['/'.join([dataset, 'data'])].attrs['description'], 'axes': 'angle:'+f_dex['/'.join([dataset, 'data'])].attrs['axes'], 'dataset_opts': { 'compression': 'gzip', 'compression_opts': 4, 'maxshape': (None, None, None, None) } }, angles={ 'value': sorted(angles.keys(), key=float), 'units': 'degrees', 'description': 'Angles at which each projection was acquired.' } ) f_tomo.add_entry(entry) f_tomo['/'.join([dataset, 'data'])].resize(tuple(array_shape)) f_tomo['/'.join([dataset, 'data'])][i_theta,:,:,:] = f_dex[dataset+'/data'].value f_tomo.close()
def main(): # Petra III collects data over 360deg but in this data sets they had problem with the rotary # stage stop moving . This happened after 180 deg so picking the first 180 deg are good to reconstruct. # The 3 blocks below load only the good 180 deg ### ct2: pj: from 0 -> 3600; bf from 0 -> 20; df from 0 -> 20 ##file_name = '/local/data/databank/PetraIII/ct2/ct2_.tif' ##dark_file_name = '/local/data/databank/PetraIII/ct2/df2b_.tif' ##white_file_name = '/local/data/databank/PetraIII/ct2/bf2b_.tif' ##hdf5_file_name = '/local/data/databank/dataExchange/microCT/PetraIII_ct2_180.h5' ##sample_name = 'ct2' ## ### ct2: Wheat root ### Sample measured at room temperature ## ##projections_start = 0 ##projections_end = 1801 ##white_start = 0 ##white_end = 20 ##white_step = 1 ##dark_start = 0 ##dark_end = 20 ##dark_step = 1 ### ct3: pj: from 0 -> 3601; bf from 20 -> 39; df from 0 -> 19 ##file_name = '/local/data/databank/PetraIII/ct3/ct3_.tif' ##dark_file_name = '/local/data/databank/PetraIII/ct3/df_.tif' ##white_file_name = '/local/data/databank/PetraIII/ct3/bf_.tif' ##hdf5_file_name = '/local/data/databank/dataExchange/microCT/PetraIII_ct3_180.h5' ##sample_name = 'ct3' ## ### ct3: Wheat root ### Same sample as ct3 but measured at cryogenic condition ## ##projections_start = 0 ##projections_end = 1801 ##white_start = 20 ##white_end = 40 ##white_step = 1 ##dark_start = 0 ##dark_end = 20 ##dark_step = 1 # ct4: pj: from 0 -> 1199; bf from 1 -> 18; df from 0 -> 19 file_name = '/local/data/databank/PetraIII/ct4/ct4_.tif' dark_file_name = '/local/data/databank/PetraIII/ct4/df_ct4_.tif' white_file_name = '/local/data/databank/PetraIII/ct4/bf_ct4_.tif' hdf5_file_name = '/local/data/databank/dataExchange/microCT/PetraIII_ct4_180.h5' sample_name = 'ct4' # ct4: Leaf of rice # Fresh sample measured at cryogenic condition projections_start = 0 projections_end = 601 white_start = 1 white_end = 19 white_step = 1 dark_start = 0 dark_end = 20 dark_step = 1 ##### if testing uncomment ##projections_start = 0 ##projections_end = 5 ##white_start = 0 ##white_end = 5 ##white_step = 1 ##dark_start = 0 ##dark_end = 5 ##dark_step = 1 verbose = True if verbose: print file_name if verbose: print hdf5_file_name if verbose: print sample_name if verbose: print "Dark start, end", dark_start, dark_end if verbose: print "White start, end", white_start, white_end if verbose: print "Projections start, end", projections_start, projections_end mydata = Convert() # Create minimal hdf5 file mydata.series_of_images(file_name, hdf5_file_name, projections_start, projections_end, # projections_angle_range=360, white_file_name = white_file_name, white_start = white_start, white_end = white_end, white_step = white_step, dark_file_name = dark_file_name, dark_start = dark_start, dark_end = dark_end, dark_step = dark_step, sample_name = sample_name, projections_digits = 5, zeros = True, verbose = False ) # Add extra metadata if available # Open DataExchange file f = DataExchangeFile(hdf5_file_name, mode='a') # Create HDF5 subgroup # /measurement/instrument f.add_entry( DataExchangeEntry.instrument(name={'value': 'Petra III'}) ) # Create HDF5 subgroup # /measurement/instrument/source f.add_entry( DataExchangeEntry.source(name={'value': 'Petra III'}, date_time={'value': "2011-25-05T19:42:13+0100"}, beamline={'value': "P06"}, ) ) # /measurement/experimenter f.add_entry( DataExchangeEntry.experimenter(name={'value':"Walter Schroeder"}, role={'value':"Project PI"}, ) ) f.close() if verbose: print "Done converting ", file_name
def main(): file_name = '/local/data/databank/TXM_26ID/20130731_004_Stripe_Solder_Sample_Tip1_TomoScript_181imgs_p1s_b1.txrm' white_file_name = '/local/data/databank/TXM_26ID/20130731_001_Background_Reference_20imgs_p5s_b1.xrm' hdf5_file_name = '/local/data/databank/dataExchange/TXM/20130731_004_Stripe_Solder_Sample_Tip1_nx.h5' log_file = '/local/data/databank/dataExchange/TXM/20130731_004_Stripe_Solder_Sample_Tip1.log' mydata = Convert() # Create minimal hdf5 file if verbose: print "Reading data ... " mydata.stack(file_name, hdf5_file_name = hdf5_file_name, white_file_name = white_file_name, sample_name = 'Stripe_Solder_Sample_Tip1' ) # Add extra metadata if available / desired reader = xradia.xrm() array = dstruct reader.read_txrm(file_name,array) # Read angles n_angles = np.shape(array.exchange.angles) if verbose: print "Done reading ", n_angles, " angles" theta = np.zeros(n_angles) theta = array.exchange.angles[:] # Save any other available metadata in a log file f = open(log_file,'w') f.write('Data creation date: \n') f.write(str(array.information.file_creation_datetime)) f.write('\n') f.write('=======================================\n') f.write('Sample name: \n') f.write(str(array.information.sample.name)) f.write('\n') f.write('=======================================\n') f.write('Experimenter name: \n') f.write(str(array.information.experimenter.name)) f.write('\n') f.write('=======================================\n') f.write('X-ray energy: \n') f.write(str(array.exchange.energy)) f.write(str(array.exchange.energy_units)) f.write('\n') f.write('=======================================\n') f.write('Angles: \n') f.write(str(array.exchange.angles)) f.write('\n') f.write('=======================================\n') f.write('Data axes: \n') f.write(str(array.exchange.data_axes)) f.write('\n') f.write('=======================================\n') f.write('x distance: \n') f.write(str(array.exchange.x)) f.write('\n') f.write('=======================================\n') f.write('x units: \n') f.write(str(array.exchange.x_units)) f.write('\n') f.write('=======================================\n') f.write('y distance: \n') f.write(str(array.exchange.y)) f.write('\n') f.write('=======================================\n') f.write('y units: \n') f.write(str(array.exchange.y_units)) f.write('\n') f.close() # Open DataExchange file f = DataExchangeFile(hdf5_file_name, mode='a') # Create HDF5 subgroup # /measurement/instrument f.add_entry( DataExchangeEntry.instrument(name={'value': 'APS-CNM 26-ID'}) ) ### Create HDF5 subgroup ### /measurement/instrument/source f.add_entry( DataExchangeEntry.source(name={'value': "Advanced Photon Source"}, date_time={'value': "2013-07-31T19:42:13+0100"}, beamline={'value': "26-ID"}, ) ) # Create HDF5 subgroup # /measurement/instrument/monochromator f.add_entry( DataExchangeEntry.monochromator(type={'value': 'Unknown'}, energy={'value': float(array.exchange.energy[0]), 'units': 'keV', 'dataset_opts': {'dtype': 'd'}}, mono_stripe={'value': 'Unknown'}, ) ) # Create HDF5 subgroup # /measurement/experimenter f.add_entry( DataExchangeEntry.experimenter(name={'value':"Robert Winarski"}, role={'value':"Project PI"}, ) ) # Create HDF5 subgroup # /measurement/sample f.add_entry( DataExchangeEntry.data(theta={'value': theta, 'units':'degrees'})) f.close() print "Done creating data exchange file: ", hdf5_file_name
def xtomo_exchange(self, data, data_white=None, data_dark=None, theta=None, sample_name=None, data_exchange_type=None, hdf5_file_name=None, log='INFO'): """ Write 3-D data to a data-exchange file. Parameters ---------- data : ndarray 3-D X-ray absorption tomography raw data. Size of the dimensions should be: [projections, slices, pixels]. data_white, data_dark : ndarray, optional 3-D white-field/dark_field data. Multiple projections are stacked together to obtain a 3-D matrix. 2nd and 3rd dimensions should be the same as data: [shots, slices, pixels]. theta : ndarray, optional Data acquisition angles corresponding to each projection. data_excahnge_type : str label defyining the type of data contained in data exchange file for raw data tomography data use 'tomography_raw_projections' hd5_file_name : str Output file. Notes ----- If file exists, does nothing Examples -------- - Convert tomographic projection series (raw, dark, white) of tiff in data exchange: >>> from dataexchange import xtomo_importer as dx >>> from dataexchange import xtomo_exporter as ex >>> file_name = '/local/dataraid/databank/Anka/radios/image_.tif' >>> dark_file_name = '/local/dataraid/databank/Anka/darks/image_.tif' >>> white_file_name = '/local/dataraid/databank/Anka/flats/image_.tif' >>> hdf5_file_name = '/local/dataraid/databank/dataExchange/tmp/Anka.h5' >>> projections_start = 0 >>> projections_end = 3167 >>> white_start = 0 >>> white_end = 100 >>> dark_start = 0 >>> dark_end = 100 >>> sample_name = 'Anka' >>> >>> mydata = dx.Import() >>> # Read series of images >>> data, white, dark, theta = mydata.xtomo_raw(file_name, >>> projections_start = projections_start, >>> projections_end = projections_end, >>> white_file_name = white_file_name, >>> white_start = white_start, >>> white_end = white_end, >>> dark_file_name = dark_file_name, >>> dark_start = dark_start, >>> dark_end = dark_end, >>> projections_digits = 5, >>> log='INFO' >>> ) >>> mydata = ex.Export() >>> # Create minimal data exchange hdf5 file >>> mydata.xtomo_exchange(data = data, >>> data_white = white, >>> data_dark = dark, >>> theta = theta, >>> hdf5_file_name = hdf5_file_name, >>> data_exchange_type = 'tomography_raw_projections', >>> sample_name = sample_name >>> ) """ if (hdf5_file_name != None): if os.path.isfile(hdf5_file_name): self.logger.error("Data Exchange file: [%s] already exists", hdf5_file_name) else: # Create new folder. dirPath = os.path.dirname(hdf5_file_name) if not os.path.exists(dirPath): os.makedirs(dirPath) # Get the file_name in lower case. lFn = hdf5_file_name.lower() # Split the string with the delimeter '.' end = lFn.split('.') # Write the Data Exchange HDF5 file. # Open DataExchange file f = DataExchangeFile(hdf5_file_name, mode='w') self.logger.info("Creating Data Exchange File [%s]", hdf5_file_name) # Create core HDF5 dataset in exchange group for projections_theta_range # deep stack of x,y images /exchange/data self.logger.info( "Adding projections to Data Exchange File [%s]", hdf5_file_name) f.add_entry( DataExchangeEntry.data( data={ 'value': data, 'units': 'counts', 'description': 'transmission', 'axes': 'theta:y:x' })) # f.add_entry( DataExchangeEntry.data(data={'value': data, 'units':'counts', 'description': 'transmission', 'axes':'theta:y:x', 'dataset_opts': {'compression': 'gzip', 'compression_opts': 4} })) if (theta != None): f.add_entry( DataExchangeEntry.data(theta={ 'value': theta, 'units': 'degrees' })) self.logger.info("Adding theta to Data Exchange File [%s]", hdf5_file_name) else: self.logger.warning("theta is not defined") if (data_dark != None): self.logger.info( "Adding dark fields to Data Exchange File [%s]", hdf5_file_name) f.add_entry( DataExchangeEntry.data( data_dark={ 'value': data_dark, 'units': 'counts', 'axes': 'theta_dark:y:x' })) # f.add_entry( DataExchangeEntry.data(data_dark={'value': data_dark, 'units':'counts', 'axes':'theta_dark:y:x', 'dataset_opts': {'compression': 'gzip', 'compression_opts': 4} })) else: self.logger.warning("data dark is not defined") if (data_white != None): self.logger.info( "Adding white fields to Data Exchange File [%s]", hdf5_file_name) f.add_entry( DataExchangeEntry.data( data_white={ 'value': data_white, 'units': 'counts', 'axes': 'theta_white:y:x' })) # f.add_entry( DataExchangeEntry.data(data_white={'value': data_white, 'units':'counts', 'axes':'theta_white:y:x', 'dataset_opts': {'compression': 'gzip', 'compression_opts': 4} })) else: self.logger.warning("data white is not defined") if (data_exchange_type != None): self.logger.info( "Adding data type to Data Exchange File [%s]", hdf5_file_name) f.add_entry( DataExchangeEntry.data( title={'value': data_exchange_type})) if (sample_name == None): sample_name = end[0] f.add_entry( DataExchangeEntry.sample( name={'value': sample_name}, description={ 'value': 'Sample name was assigned by the HDF5 converter and based on the HDF5 file name' })) else: f.add_entry( DataExchangeEntry.sample( name={'value': sample_name}, description={ 'value': 'Sample name was read from the user log file' })) f.close() self.logger.info("DONE!!!!. Created Data Exchange File [%s]", hdf5_file_name) else: self.logger.warning("Nothing to do ...")
def pack_data_exchange(): f = DataExchangeFile(CXP.io.data_exchange_filename, mode='w') sim = DataExchangeEntry.simulation( name={'value': 'Simulated Ptycho Data.'}, energy={'value': CXP.experiment.energy, 'units':'keV'}, focusing_optic={'value': CXP.experiment.optic}, probe_modes={'value':CXP.reconstruction.probe_modes}, noise_model={'value': CXP.simulation.noise_model}, gaussian_noise_level={'value': CXP.simulation.gaussian_noise_level}, total_photons={'value': CXP.simulation.total_photons}, beam_stop={'value': CXP.simulation.beam_stop}, beam_stop_size={'value':CXP.simulation.beam_stop_size}, beam_stop_attenuation={'value':CXP.simulation.beam_stop_attenuation}, defocus = {'value':CXP.simulation.defocus}, position_jitter={'value': CXP.reconstruction.initial_position_jitter_radius, 'units':'pixels'} ) f.add_entry(sim) sample = DataExchangeEntry.sample( root='/simulation', name={'value':'ground truth sample complex amplitude'}, data={'value': cxph.sample.data[0], 'units':'sqrt(counts)'}, ) f.add_entry(sample) probe = DataExchangeEntry.sample( root='/simulation', entry_name='probe', ) for mode in range(CXP.reconstruction.probe_modes): setattr(probe, 'mode_{:d}'.format(mode), {'value': cxph.input_probe.modes[mode].data[0], 'units':'counts'}) f.add_entry(probe) detector = DataExchangeEntry.detector( root='/simulation', x_pixel_size={'value': CXP.experiment.dx_d}, y_pixel_size={'value': CXP.experiment.dx_d}, x_dimension={'value': CXP.experiment.px}, y_dimension={'value': CXP.experiment.py}, distance={'value': CXP.experiment.z}, basis_vectors={'value': [[0,-CXP.experiment.dx_d,0],[-CXP.experiment.dx_d,0,0]]}, corner_position={'value': [0,0,0]} ) f.add_entry(detector) data = DataExchangeEntry.data( name={'value': 'simulated_data'}, data={'value': sp.array(cxph.det_mod.data), 'axes':'translation:y:x', 'units':'counts', 'dataset_opts': {'compression': 'gzip', 'compression_opts': 4}}, translation={'value':'/exchange/sample/geometry/translation'} ) f.add_entry(data) # Get scan positions into dex format pos = sp.zeros((cxph.positions.total, 3)) y, x = cxph.positions.correct for i in range(cxph.positions.total): pos[i,0], pos[i, 1] = x[i]*CXP.dx_s, y[i]*CXP.dx_s positions = DataExchangeEntry.translation( root='/exchange/sample/geometry', name={'value':'ptychography scan positions'}, scan_type={'value': CXP.measurement.ptycho_scan_type}, data={'value': pos, 'units': 'm'} ) f.add_entry(positions) f.close()
def convert_to_SDE(filename): """ ..function:: convert_to_SDE(filename) This function converts a single MAPS created HDF5 file to Scientific Data Exchange format. ..param:: filename - the filename of the MAPS hdf5 file to be converted to Scientific Data Exchange format. """ f_maps = h5py.File(filename, mode='r') f_dex = DataExchangeFile('/'.join(filename.split('/')[:-1])+'/'+filename.split('/')[-1].split('.')[0]+'_SDE.h5', mode='w') for group in MAPS_to_SDE_mapping.keys(): for entry_type in MAPS_to_SDE_mapping[group].keys(): for entry in MAPS_to_SDE_mapping[group][entry_type].keys(): d, kwargs = {}, {} # root root = MAPS_to_SDE_mapping[group][entry_type][entry][0] # value if type(MAPS_to_SDE_mapping[group][entry_type][entry][1])==h5val: d['value'] = f_maps[MAPS_to_SDE_mapping[group][entry_type][entry][1].args[0]].value if len(MAPS_to_SDE_mapping[group][entry_type][entry][1].args)>1: d['value'] = d['value'][MAPS_to_SDE_mapping[group][entry_type][entry][1].args[1]] elif type(MAPS_to_SDE_mapping[group][entry_type][entry][1])==h5att: d['value'] = f_maps[MAPS_to_SDE_mapping[group][entry_type][entry][1].args[0]].attrs[MAPS_to_SDE_mapping[group][entry_type][entry][1].args[1]] else: d['value'] = MAPS_to_SDE_mapping[group][entry_type][entry][1] #units try: if type(MAPS_to_SDE_mapping[group][entry_type][entry][2])==h5val: d['units'] = f_maps[MAPS_to_SDE_mapping[group][entry_type][entry][2].args[0]].value elif type(MAPS_to_SDE_mapping[group][entry_type][entry][1])==h5att: d['units'] = f_maps[MAPS_to_SDE_mapping[group][entry_type][entry][2].args[0]].attrs[MAPS_to_SDE_mapping[group][entry_type][entry][2].args[1]] else: if MAPS_to_SDE_mapping[group][entry_type][entry][2]: # Could be None d['units'] = MAPS_to_SDE_mapping[group][entry_type][entry][2] #description if type(MAPS_to_SDE_mapping[group][entry_type][entry][3])==h5val: d['description'] = f_maps[MAPS_to_SDE_mapping[group][entry_type][entry][3].args[0]].value elif type(MAPS_to_SDE_mapping[group][entry_type][entry][3])==h5att: d['description'] = f_maps[MAPS_to_SDE_mapping[group][entry_type][entry][3].args[0]].attrs[MAPS_to_SDE_mapping[group][entry_type][entry][3].args[1]] else: d['description'] = f_maps[MAPS_to_SDE_mapping[group][entry_type][entry][3]] #axes d['axes'] = MAPS_to_SDE_mapping[group][entry_type][entry][4] #dataset_opts d['dataset_opts'] = MAPS_to_SDE_mapping[group][entry_type][entry][5] except IndexError: pass if root is None: f_dex.add_entry( getattr(DataExchangeEntry, entry_type)(**{entry: d}) ) else: f_dex.add_entry( getattr(DataExchangeEntry, entry_type)(**{'root': root, entry: d}) ) f_dex.close() f_maps.close()
def main(): ##file_name = '/local/data/databank/APS_2_BM/Sam18_hornby/raw/Hornby_19keV_10x_.hdf' ##log_file = '/local/data/databank/APS_2_BM/Sam18_hornby/raw/Hornby.log' ## ##hdf5_file_name = '/local/data/databank/dataExchange/microCT/Hornby_APS_2011.h5' file_name = '/local/data/databank/APS_2_BM/Sam19_blakely/raw/Blakely_19keV_10x_.hdf' log_file = '/local/data/databank/APS_2_BM/Sam19_blakely/raw/Blakely.log' hdf5_file_name = '/local/data/databank/dataExchange/microCT/Blakely_APS_2011.h5' verbose = True if verbose: print file_name if verbose: print log_file if verbose: print hdf5_file_name #Read input SLS data file = open(log_file, 'r') if verbose: print '###############################' for line in file: if 'Number of darks' in line: NumberOfDarks = re.findall(r'\d+', line) if verbose: print 'Number of Darks', NumberOfDarks[0] if 'Number of flats' in line: NumberOfFlats = re.findall(r'\d+', line) if verbose: print 'Number of Flats', NumberOfFlats[0] if 'Number of projections' in line: NumberOfProjections = re.findall(r'\d+', line) if verbose: print 'Number of Projections', NumberOfProjections[0] if 'Number of inter-flats' in line: NumberOfInterFlats = re.findall(r'\d+', line) if verbose: print 'Number of inter-flats', NumberOfInterFlats[0] if 'Inner scan flag' in line: InnerScanFlag = re.findall(r'\d+', line) if verbose: print 'Inner scan flag', InnerScanFlag[0] if 'Flat frequency' in line: FlatFrequency = re.findall(r'\d+', line) if verbose: print 'Flat frequency', FlatFrequency[0] if 'Rot Y min' in line: RotYmin = re.findall(r'\d+.\d+', line) if verbose: print 'Rot Y min', RotYmin[0] if 'Rot Y max' in line: RotYmax = re.findall(r'\d+.\d+', line) if verbose: print 'Rot Y max', RotYmax[0] if 'Angular step' in line: AngularStep = re.findall(r'\d+.\d+', line) if verbose: print 'Angular step', AngularStep[0] if verbose: print '###############################' file.close() dark_start = 1 dark_end = int(NumberOfDarks[0]) + 1 white_start = dark_end white_end = white_start + int(NumberOfFlats[0]) projections_start = white_end projections_end = projections_start + int(NumberOfProjections[0]) if verbose: print dark_start, dark_end if verbose: print white_start, white_end if verbose: print projections_start, projections_end dark_start = 1504 dark_end = 1505 white_start = 1 white_end = 2 projections_start = 2 projections_end = 1503 ### if testing uncomment ##dark_start = 1 ##dark_end = 3 ##white_start = 10 ##white_end = 12 ##projections_start = 20 ##projections_end = 23 if verbose: print dark_start, dark_end if verbose: print white_start, white_end if verbose: print projections_start, projections_end mydata = Convert() # Create minimal hdf5 file mydata.series_of_images(file_name, hdf5_file_name, projections_start, projections_end, white_start = white_start, white_end = white_end, dark_start = dark_start, dark_end = dark_end, projections_digits = 5, data_type = 'hdf4', #verbose = False ) # Add extra metadata if available # Open DataExchange file f = DataExchangeFile(hdf5_file_name, mode='a') # Create HDF5 subgroup # /measurement/instrument f.add_entry( DataExchangeEntry.instrument(name={'value': 'APS 2-BM'}) ) f.add_entry( DataExchangeEntry.source(name={'value': 'Advanced Photon Source'}, date_time={'value': "2012-07-31T21:15:23+0600"}, beamline={'value': "2-BM"}, current={'value': 101.199, 'units': 'mA', 'dataset_opts': {'dtype': 'd'}}, energy={'value': 7.0, 'units':'GeV', 'dataset_opts': {'dtype': 'd'}}, mode={'value':'TOPUP'} ) ) # Create HDF5 subgroup # /measurement/instrument/attenuator f.add_entry( DataExchangeEntry.attenuator(thickness={'value': 1e-3, 'units': 'm', 'dataset_opts': {'dtype': 'd'}}, type={'value': 'Al'} ) ) # Create HDF5 subgroup # Create HDF5 subgroup # /measurement/instrument/monochromator f.add_entry( DataExchangeEntry.monochromator(type={'value': 'Multilayer'}, energy={'value': 19.26, 'units': 'keV', 'dataset_opts': {'dtype': 'd'}}, energy_error={'value': 1e-3, 'units': 'keV', 'dataset_opts': {'dtype': 'd'}}, mono_stripe={'value': 'Ru/C'}, ) ) # Create HDF5 subgroup # /measurement/experimenter f.add_entry( DataExchangeEntry.experimenter(name={'value':"Jane Waruntorn"}, role={'value':"Project PI"}, affiliation={'value':"University of California"}, facility_user_id={'value':"64924"}, ) ) f.add_entry(DataExchangeEntry.objective(manufacturer={'value':'Zeiss'}, model={'value':'Plan-NEOFLUAR 1004-072'}, magnification={'value':5, 'dataset_opts': {'dtype': 'd'}}, numerical_aperture={'value':0.5, 'dataset_opts': {'dtype': 'd'}}, ) ) f.add_entry(DataExchangeEntry.scintillator(manufacturer={'value':'Crytur'}, serial_number={'value':'12'}, name={'value':'LuAg '}, type={'value':'LuAg'}, scintillating_thickness={'value':50e-6, 'dataset_opts': {'dtype': 'd'}}, substrate_thickness={'value':50e-6, 'dataset_opts': {'dtype': 'd'}}, ) ) # Create HDF5 subgroup # /measurement/experiment f.add_entry( DataExchangeEntry.experiment( proposal={'value':"GUP-34353"}, activity={'value':"32-IDBC-2013-106491"}, safety={'value':"106491-49734"}, ) ) f.close() if verbose: print "Done converting ", file_name
def main(): file_name = '/local/data/databank/TXM_26ID/Miller1/ABR_1SP_.tif' #dark_file_name = '/local/data/databank/AS/Mayo_tooth_AS/BG__AFTER_.tif' #white_file_name = '/local/data/databank/AS/Mayo_tooth_AS/BG__BEFORE_.tif' hdf5_file_name = '/local/data/databank/dataExchange/TXM/TXM_APS26IDMiller1.h5' sample_name = 'Teeth' projections_start = 0 projections_end = 361 white_start = 0 white_end = 0 white_step = 1 dark_start = 0 dark_end = 0 dark_step = 1 verbose = True if verbose: print "Input projection base name: ", file_name #if verbose: print "Input white base name: ", white_file_name #if verbose: print "Input dark base name: ", dark_file_name if verbose: print "Output data exchange file name: ", hdf5_file_name mydata = Convert() # Create minimal hdf5 file mydata.series_of_images( file_name, hdf5_file_name, projections_start, projections_end, #white_file_name = white_file_name, white_start=white_start, white_end=white_end, white_step=white_step, #dark_file_name = dark_file_name, #dark_start = dark_start, #dark_end = dark_end, #dark_step = dark_step, #sample_name = sample_name, projections_digits=4, #white_digits = 2, #dark_digits = 2, projections_zeros=True, verbose=False) if verbose: print "Done reading data ... " # Add extra metadata if available # Open DataExchange file f = DataExchangeFile(hdf5_file_name, mode='a') # Create HDF5 subgroup # /measurement/instrument f.add_entry( DataExchangeEntry.instrument( name={'value': 'Australian Synchrotron Facility'})) # Create HDF5 subgroup # /measurement/instrument/source f.add_entry( DataExchangeEntry.source( name={'value': 'Australian Synchrotron FacilityI'}, date_time={'value': "2013-10-19T22:22:13+0100"}, beamline={'value': "Tomography"}, )) # /measurement/experimenter f.add_entry( DataExchangeEntry.experimenter( name={'value': "Sherry Mayo"}, role={'value': "Project PI"}, )) f.close() if verbose: print "Done creating data exchange file: ", hdf5_file_name
def xtomo_exchange( self, data, data_white=None, data_dark=None, theta=None, data_exchange_type=None, source_name=None, source_mode=None, source_datetime=None, beamline=None, energy=None, current=None, actual_pixel_size=None, experimenter_name=None, experimenter_affiliation=None, experimenter_email=None, instrument_comment=None, sample_name=None, sample_comment=None, acquisition_mode=None, acquisition_comment=None, sample_position_x=None, sample_position_y=None, sample_position_z=None, sample_image_shift_x=None, sample_image_shift_y=None, image_exposure_time=None, image_time=None, image_theta=None, hdf5_file_name=None, axes="theta:y:x", log="INFO", ): """ Write 3-D data to a data-exchange file. Parameters data : ndarray 3-D X-ray absorption tomography raw data. Size of the dimensions should be: [projections, slices, pixels]. data_white, data_dark : ndarray, optional 3-D white-field/dark_field data. Multiple projections are stacked together to obtain a 3-D matrix. 2nd and 3rd dimensions should be the same as data: [shots, slices, pixels]. theta : ndarray, optional Data acquisition angles corresponding to each projection. data_excahnge_type : str, optional label defyining the type of data contained in data exchange file for raw data tomography data use 'tomography_raw_projections' source_name, source_mode, source_datetime : str, optional label defining the source name, operation mode and date/time when these values were taken beamline : str, optional label defining the beamline name energy, current : float, optional X-ray energy and bean current actual_pixel_size : float, optional pixel size on the sample plane experimenter_name, experimenter_affiliation, experimenter_email : str, optional user name, affiliation and e-mail address instrument_comment : str, optional instrument comment sample_name, sample_comment : str, optional sample name and comment acquisition_mode, acquisition_comment : str, optional acquisition mode and comment hd5_file_name : str Output file. Notes ----- If file exists, does nothing Examples - Convert tomographic projection series (raw, dark, white) of tiff in data exchange: >>> import dataexchange >>> file_name = '/local/dataraid/databank/Anka/radios/image_.tif' >>> dark_file_name = '/local/dataraid/databank/Anka/darks/image_.tif' >>> white_file_name = '/local/dataraid/databank/Anka/flats/image_.tif' >>> hdf5_file_name = '/local/dataraid/databank/dataExchange/tmp/Anka.h5' >>> projections_start = 0 >>> projections_end = 3167 >>> white_start = 0 >>> white_end = 100 >>> dark_start = 0 >>> dark_end = 100 >>> sample_name = 'Anka' >>> >>> # Read raw data >>> read = dataexchange.Import() >>> data, white, dark, theta = read.xtomo_raw(file_name, >>> projections_start = projections_start, >>> projections_end = projections_end, >>> white_file_name = white_file_name, >>> white_start = white_start, >>> white_end = white_end, >>> dark_file_name = dark_file_name, >>> dark_start = dark_start, >>> dark_end = dark_end, >>> projections_digits = 5, >>> log='INFO' >>> ) >>> >>> # Save data >>> write = dataexchange.Export() >>> write.xtomo_exchange(data = data, >>> data_white = white, >>> data_dark = dark, >>> theta = theta, >>> hdf5_file_name = hdf5_file_name, >>> data_exchange_type = 'tomography_raw_projections', >>> sample_name = sample_name >>> ) """ if hdf5_file_name != None: if os.path.isfile(hdf5_file_name): self.logger.error("Data Exchange file: [%s] already exists", hdf5_file_name) else: # Create new folder. dirPath = os.path.dirname(hdf5_file_name) if not os.path.exists(dirPath): os.makedirs(dirPath) # Get the file_name in lower case. lFn = hdf5_file_name.lower() # Split the string with the delimeter '.' end = lFn.split(".") # Write the Data Exchange HDF5 file. # Open DataExchange file f = DataExchangeFile(hdf5_file_name, mode="w") self.logger.info("Creating Data Exchange File [%s]", hdf5_file_name) # Create core HDF5 dataset in exchange group for projections_theta_range # deep stack of x,y images /exchange/data self.logger.info("Adding projections to Data Exchange File [%s]", hdf5_file_name) f.add_entry( DataExchangeEntry.data( data={"value": data, "units": "counts", "description": "transmission", "axes": axes} ) ) # f.add_entry( DataExchangeEntry.data(data={'value': data, 'units':'counts', 'description': 'transmission', 'axes':'theta:y:x', 'dataset_opts': {'compression': 'gzip', 'compression_opts': 4} })) if theta != None: f.add_entry(DataExchangeEntry.data(theta={"value": theta, "units": "degrees"})) self.logger.info("Adding theta to Data Exchange File [%s]", hdf5_file_name) else: self.logger.warning("theta is not defined") if data_dark != None: self.logger.info("Adding dark fields to Data Exchange File [%s]", hdf5_file_name) f.add_entry( DataExchangeEntry.data( data_dark={"value": data_dark, "units": "counts", "axes": "theta_dark:y:x"} ) ) # f.add_entry( DataExchangeEntry.data(data_dark={'value': data_dark, 'units':'counts', 'axes':'theta_dark:y:x', 'dataset_opts': {'compression': 'gzip', 'compression_opts': 4} })) else: self.logger.warning("data dark is not defined") if data_white != None: self.logger.info("Adding white fields to Data Exchange File [%s]", hdf5_file_name) f.add_entry( DataExchangeEntry.data( data_white={"value": data_white, "units": "counts", "axes": "theta_white:y:x"} ) ) # f.add_entry( DataExchangeEntry.data(data_white={'value': data_white, 'units':'counts', 'axes':'theta_white:y:x', 'dataset_opts': {'compression': 'gzip', 'compression_opts': 4} })) else: self.logger.warning("data white is not defined") if data_exchange_type != None: self.logger.info("Adding data type to Data Exchange File [%s]", hdf5_file_name) f.add_entry(DataExchangeEntry.data(title={"value": data_exchange_type})) if source_name != None: f.add_entry(DataExchangeEntry.source(name={"value": source_name})) if source_mode != None: f.add_entry(DataExchangeEntry.source(mode={"value": source_mode})) if source_datetime != None: f.add_entry(DataExchangeEntry.source(datetime={"value": source_datetime})) if beamline != None: f.add_entry(DataExchangeEntry.source(beamline={"value": beamline})) if energy != None: f.add_entry( DataExchangeEntry.monochromator( energy={"value": energy, "units": "keV", "dataset_opts": {"dtype": "d"}} ) ) if current != None: f.add_entry( DataExchangeEntry.source( current={"value": current, "units": "mA", "dataset_opts": {"dtype": "d"}} ) ) if actual_pixel_size != None: f.add_entry( DataExchangeEntry.detector( actual_pixel_size_x={ "value": actual_pixel_size, "units": "microns", "dataset_opts": {"dtype": "d"}, }, actual_pixel_size_y={ "value": actual_pixel_size, "units": "microns", "dataset_opts": {"dtype": "d"}, }, ) ) if experimenter_name != None: f.add_entry(DataExchangeEntry.experimenter(name={"value": experimenter_name})) if experimenter_affiliation != None: f.add_entry(DataExchangeEntry.experimenter(affiliation={"value": experimenter_affiliation})) if experimenter_email != None: f.add_entry(DataExchangeEntry.experimenter(email={"value": experimenter_email})) if instrument_comment != None: f.add_entry(DataExchangeEntry.instrument(comment={"value": instrument_comment})) if sample_name == None: sample_name = end[0] f.add_entry( DataExchangeEntry.sample( name={"value": sample_name}, description={ "value": "Sample name assigned by the HDF5 converter and based on the HDF5 file name" }, ) ) else: f.add_entry(DataExchangeEntry.sample(name={"value": sample_name})) if sample_comment != None: f.add_entry(DataExchangeEntry.sample(comment={"value": sample_comment})) if acquisition_mode != None: f.add_entry(DataExchangeEntry.acquisition(mode={"value": acquisition_mode})) if acquisition_comment != None: f.add_entry(DataExchangeEntry.acquisition(comment={"value": acquisition_comment})) if sample_position_x != None: f.add_entry( DataExchangeEntry.acquisition( sample_position_x={ "value": sample_position_x, "units": "microns", "dataset_opts": {"dtype": "d"}, } ) ) if sample_position_y != None: f.add_entry( DataExchangeEntry.acquisition( sample_position_y={ "value": sample_position_y, "units": "microns", "dataset_opts": {"dtype": "d"}, } ) ) if sample_position_z != None: f.add_entry( DataExchangeEntry.acquisition( sample_position_z={ "value": sample_position_z, "units": "microns", "dataset_opts": {"dtype": "d"}, } ) ) if sample_image_shift_x != None: f.add_entry( DataExchangeEntry.acquisition( sample_image_shift_x={ "value": sample_image_shift_x, "units": "microns", "dataset_opts": {"dtype": "d"}, } ) ) if sample_image_shift_y != None: f.add_entry( DataExchangeEntry.acquisition( sample_image_shift_y={ "value": sample_image_shift_y, "units": "microns", "dataset_opts": {"dtype": "d"}, } ) ) if image_exposure_time != None: f.add_entry( DataExchangeEntry.acquisition( image_exposure_time={ "value": image_exposure_time, "units": "s", "dataset_opts": {"dtype": "d"}, } ) ) if image_time != None: f.add_entry(DataExchangeEntry.acquisition(image_time={"value": image_time})) if image_theta != None: f.add_entry(DataExchangeEntry.acquisition(image_theta={"value": image_theta, "units": "degrees"})) f.close() self.logger.info("DONE!!!!. Created Data Exchange File [%s]", hdf5_file_name) else: self.logger.warning("Nothing to do ...")
current={'value': 100.96, 'units': 'mA', 'dataset_opts': {'dtype': 'd'}}, ) ) # Create HDF5 subgroup # /measurement/instrument/monochromator f.add_entry( DataExchangeEntry.monochromator(type={'value': 'unknow'}, energy={'value': 65, 'units': 'keV', 'dataset_opts': {'dtype': 'd'}}, mono_stripe={'value': 'unknow'}, ) ) # Create HDF5 subgroup # /measurement/experimenter f.add_entry( DataExchangeEntry.experimenter(name={'value':"Peter Kenesei"}, role={'value':"Project PI"}, affiliation={'value':"Advanced Photon Source"}, phone={'value':"+1 630 252-0133"}, email={'value':"*****@*****.**"}, ) ) f.close() if verbose: print "Done converting ", file_name ###if __name__ == "__main__": ### main()
def xtomo_exchange(xtomo, data, data_white=None, data_dark=None, theta=None, sample_name=None, data_exchange_type=None, hdf5_file_name=None, log='INFO' ): """ Write 3-D data to a data-exchange file. Parameters ---------- data : ndarray 3-D X-ray absorption tomography raw data. Size of the dimensions should be: [projections, slices, pixels]. data_white, data_dark : ndarray, optional 3-D white-field/dark_field data. Multiple projections are stacked together to obtain a 3-D matrix. 2nd and 3rd dimensions should be the same as data: [shots, slices, pixels]. theta : ndarray, optional Data acquisition angles corresponding to each projection. data_excahnge_type : str label defyining the type of data contained in data exchange file for raw data tomography data use 'tomography_raw_projections' hd5_file_name : str Output file. Notes ----- If file exists, does nothing Examples -------- - Convert tomographic projection series (raw, dark, white) of tiff in data exchange: >>> from dataexchange import xtomo_importer as dx >>> from dataexchange import xtomo_exporter as ex >>> file_name = '/local/dataraid/databank/Anka/radios/image_.tif' >>> dark_file_name = '/local/dataraid/databank/Anka/darks/image_.tif' >>> white_file_name = '/local/dataraid/databank/Anka/flats/image_.tif' >>> >>> hdf5_file_name = '/local/dataraid/databank/dataExchange/microCT/xx_yy_Anka.h5' >>> >>> projections_start = 0 >>> projections_end = 3167 >>> white_start = 0 >>> white_end = 100 >>> dark_start = 0 >>> dark_end = 100 >>> >>> sample_name = 'Anka' >>> >>> mydata = dx.Import() >>> # Read series of images >>> data, white, dark, theta = mydata.series_of_images(file_name, >>> projections_start = projections_start, >>> projections_end = projections_end, >>> white_file_name = white_file_name, >>> white_start = white_start, >>> white_end = white_end, >>> dark_file_name = dark_file_name, >>> dark_start = dark_start, >>> dark_end = dark_end, >>> sample_name = sample_name, >>> projections_digits = 5, >>> log='INFO' >>> ) >>> >>> mydata = ex.Export() >>> # Create minimal data exchange hdf5 file >>> mydata.xtomo_exchange(data = data, >>> data_white = white, >>> data_dark = dark, >>> theta = theta, >>> hdf5_file_name = hdf5_file_name, >>> data_exchange_type = 'tomography_raw_projections' >>> ) """ if (hdf5_file_name != None): if os.path.isfile(hdf5_file_name): xtomo.logger.info("Data Exchange file already exists: [%s]. Next time use the Data Exchange reader instead", hdf5_file_name) else: # Create new folder. dirPath = os.path.dirname(hdf5_file_name) if not os.path.exists(dirPath): os.makedirs(dirPath) # Get the file_name in lower case. lFn = hdf5_file_name.lower() # Split the string with the delimeter '.' end = lFn.split('.') # Write the Data Exchange HDF5 file. # Open DataExchange file f = DataExchangeFile(hdf5_file_name, mode='w') xtomo.logger.info("Creating Data Exchange File [%s]", hdf5_file_name) # Create core HDF5 dataset in exchange group for projections_theta_range # deep stack of x,y images /exchange/data xtomo.logger.info("Adding projections to Data Exchange File [%s]", hdf5_file_name) f.add_entry( DataExchangeEntry.data(data={'value': data, 'units':'counts', 'description': 'transmission', 'axes':'theta:y:x' })) # f.add_entry( DataExchangeEntry.data(data={'value': data, 'units':'counts', 'description': 'transmission', 'axes':'theta:y:x', 'dataset_opts': {'compression': 'gzip', 'compression_opts': 4} })) if (theta != None): f.add_entry( DataExchangeEntry.data(theta={'value': theta, 'units':'degrees'})) xtomo.logger.info("Adding theta to Data Exchange File [%s]", hdf5_file_name) if (data_dark != None): xtomo.logger.info("Adding dark fields to Data Exchange File [%s]", hdf5_file_name) f.add_entry( DataExchangeEntry.data(data_dark={'value': data_dark, 'units':'counts', 'axes':'theta_dark:y:x' })) # f.add_entry( DataExchangeEntry.data(data_dark={'value': data_dark, 'units':'counts', 'axes':'theta_dark:y:x', 'dataset_opts': {'compression': 'gzip', 'compression_opts': 4} })) if (data_white != None): xtomo.logger.info("Adding white fields to Data Exchange File [%s]", hdf5_file_name) f.add_entry( DataExchangeEntry.data(data_white={'value': data_white, 'units':'counts', 'axes':'theta_white:y:x' })) # f.add_entry( DataExchangeEntry.data(data_white={'value': data_white, 'units':'counts', 'axes':'theta_white:y:x', 'dataset_opts': {'compression': 'gzip', 'compression_opts': 4} })) if (data_exchange_type != None): xtomo.logger.info("Adding data type to Data Exchange File [%s]", hdf5_file_name) f.add_entry( DataExchangeEntry.data(title={'value': data_exchange_type})) if (sample_name == None): sample_name = end[0] f.add_entry( DataExchangeEntry.sample( name={'value':sample_name}, description={'value':'Sample name was assigned by the HDF5 converter and based on the HDF5 file name'})) else: f.add_entry( DataExchangeEntry.sample( name={'value':sample_name}, description={'value':'Sample name was read from the user log file'})) f.close() xtomo.logger.info("DONE!!!!. Created Data Exchange File [%s]", hdf5_file_name) else: xtomo.logger.info("Nothing to do ...")
def xtomo_exchange(self, data, data_white=None, data_dark=None, theta=None, data_exchange_type=None, source_name=None, source_mode=None, source_datetime=None, beamline=None, energy=None, current=None, actual_pixel_size=None, experimenter_name=None, experimenter_affiliation=None, experimenter_email=None, instrument_comment=None, sample_name=None, sample_comment=None, acquisition_mode=None, acquisition_comment=None, sample_position_x=None, sample_position_y=None, sample_position_z=None, sample_image_shift_x=None, sample_image_shift_y=None, hdf5_file_name=None, axes='theta:y:x', log='INFO'): """ Write 3-D data to a data-exchange file. Parameters data : ndarray 3-D X-ray absorption tomography raw data. Size of the dimensions should be: [projections, slices, pixels]. data_white, data_dark : ndarray, optional 3-D white-field/dark_field data. Multiple projections are stacked together to obtain a 3-D matrix. 2nd and 3rd dimensions should be the same as data: [shots, slices, pixels]. theta : ndarray, optional Data acquisition angles corresponding to each projection. data_excahnge_type : str, optional label defyining the type of data contained in data exchange file for raw data tomography data use 'tomography_raw_projections' source_name, source_mode, source_datetime : str, optional label defining the source name, operation mode and date/time when these values were taken beamline : str, optional label defining the beamline name energy, current : float, optional X-ray energy and bean current actual_pixel_size : float, optional pixel size on the sample plane experimenter_name, experimenter_affiliation, experimenter_email : str, optional user name, affiliation and e-mail address instrument_comment : str, optional instrument comment sample_name, sample_comment : str, optional sample name and comment acquisition_mode, acquisition_comment : str, optional acquisition mode and comment hd5_file_name : str Output file. Notes ----- If file exists, does nothing Examples - Convert tomographic projection series (raw, dark, white) of tiff in data exchange: >>> import dataexchange >>> file_name = '/local/dataraid/databank/Anka/radios/image_.tif' >>> dark_file_name = '/local/dataraid/databank/Anka/darks/image_.tif' >>> white_file_name = '/local/dataraid/databank/Anka/flats/image_.tif' >>> hdf5_file_name = '/local/dataraid/databank/dataExchange/tmp/Anka.h5' >>> projections_start = 0 >>> projections_end = 3167 >>> white_start = 0 >>> white_end = 100 >>> dark_start = 0 >>> dark_end = 100 >>> sample_name = 'Anka' >>> >>> # Read raw data >>> read = dataexchange.Import() >>> data, white, dark, theta = read.xtomo_raw(file_name, >>> projections_start = projections_start, >>> projections_end = projections_end, >>> white_file_name = white_file_name, >>> white_start = white_start, >>> white_end = white_end, >>> dark_file_name = dark_file_name, >>> dark_start = dark_start, >>> dark_end = dark_end, >>> projections_digits = 5, >>> log='INFO' >>> ) >>> >>> # Save data >>> write = dataexchange.Export() >>> write.xtomo_exchange(data = data, >>> data_white = white, >>> data_dark = dark, >>> theta = theta, >>> hdf5_file_name = hdf5_file_name, >>> data_exchange_type = 'tomography_raw_projections', >>> sample_name = sample_name >>> ) """ if (hdf5_file_name != None): if os.path.isfile(hdf5_file_name): self.logger.error("Data Exchange file: [%s] already exists", hdf5_file_name) else: # Create new folder. dirPath = os.path.dirname(hdf5_file_name) if not os.path.exists(dirPath): os.makedirs(dirPath) # Get the file_name in lower case. lFn = hdf5_file_name.lower() # Split the string with the delimeter '.' end = lFn.split('.') # Write the Data Exchange HDF5 file. # Open DataExchange file f = DataExchangeFile(hdf5_file_name, mode='w') self.logger.info("Creating Data Exchange File [%s]", hdf5_file_name) # Create core HDF5 dataset in exchange group for projections_theta_range # deep stack of x,y images /exchange/data self.logger.info( "Adding projections to Data Exchange File [%s]", hdf5_file_name) f.add_entry( DataExchangeEntry.data( data={ 'value': data, 'units': 'counts', 'description': 'transmission', 'axes': axes })) # f.add_entry( DataExchangeEntry.data(data={'value': data, 'units':'counts', 'description': 'transmission', 'axes':'theta:y:x', 'dataset_opts': {'compression': 'gzip', 'compression_opts': 4} })) if (theta != None): f.add_entry( DataExchangeEntry.data(theta={ 'value': theta, 'units': 'degrees' })) self.logger.info("Adding theta to Data Exchange File [%s]", hdf5_file_name) else: self.logger.warning("theta is not defined") if (data_dark != None): self.logger.info( "Adding dark fields to Data Exchange File [%s]", hdf5_file_name) f.add_entry( DataExchangeEntry.data( data_dark={ 'value': data_dark, 'units': 'counts', 'axes': 'theta_dark:y:x' })) # f.add_entry( DataExchangeEntry.data(data_dark={'value': data_dark, 'units':'counts', 'axes':'theta_dark:y:x', 'dataset_opts': {'compression': 'gzip', 'compression_opts': 4} })) else: self.logger.warning("data dark is not defined") if (data_white != None): self.logger.info( "Adding white fields to Data Exchange File [%s]", hdf5_file_name) f.add_entry( DataExchangeEntry.data( data_white={ 'value': data_white, 'units': 'counts', 'axes': 'theta_white:y:x' })) # f.add_entry( DataExchangeEntry.data(data_white={'value': data_white, 'units':'counts', 'axes':'theta_white:y:x', 'dataset_opts': {'compression': 'gzip', 'compression_opts': 4} })) else: self.logger.warning("data white is not defined") if (data_exchange_type != None): self.logger.info( "Adding data type to Data Exchange File [%s]", hdf5_file_name) f.add_entry( DataExchangeEntry.data( title={'value': data_exchange_type})) if (source_name != None): f.add_entry( DataExchangeEntry.source(name={'value': source_name})) if (source_mode != None): f.add_entry( DataExchangeEntry.source(mode={'value': source_mode})) if (source_datetime != None): f.add_entry( DataExchangeEntry.source( datetime={'value': source_datetime})) if (beamline != None): f.add_entry( DataExchangeEntry.source(beamline={'value': beamline})) if (energy != None): f.add_entry( DataExchangeEntry.monochromator( energy={ 'value': energy, 'units': 'keV', 'dataset_opts': { 'dtype': 'd' } })) if (current != None): f.add_entry( DataExchangeEntry.source( current={ 'value': current, 'units': 'mA', 'dataset_opts': { 'dtype': 'd' } })) if (actual_pixel_size != None): f.add_entry( DataExchangeEntry.detector(actual_pixel_size_x={ 'value': actual_pixel_size, 'units': 'microns', 'dataset_opts': { 'dtype': 'd' } }, actual_pixel_size_y={ 'value': actual_pixel_size, 'units': 'microns', 'dataset_opts': { 'dtype': 'd' } })) if (experimenter_name != None): f.add_entry( DataExchangeEntry.experimenter( name={'value': experimenter_name})) if (experimenter_affiliation != None): f.add_entry( DataExchangeEntry.experimenter( affiliation={'value': experimenter_affiliation})) if (experimenter_email != None): f.add_entry( DataExchangeEntry.experimenter( email={'value': experimenter_email})) if (instrument_comment != None): f.add_entry( DataExchangeEntry.instrument( comment={'value': instrument_comment})) if (sample_name == None): sample_name = end[0] f.add_entry( DataExchangeEntry.sample( name={'value': sample_name}, description={ 'value': 'Sample name assigned by the HDF5 converter and based on the HDF5 file name' })) else: f.add_entry( DataExchangeEntry.sample(name={'value': sample_name})) if (sample_comment != None): f.add_entry( DataExchangeEntry.sample( comment={'value': sample_comment})) if (acquisition_mode != None): f.add_entry( DataExchangeEntry.acquisition( mode={'value': acquisition_mode})) if (acquisition_comment != None): f.add_entry( DataExchangeEntry.acquisition( comment={'value': acquisition_comment})) if (sample_position_x != None): f.add_entry( DataExchangeEntry.acquisition( sample_position_x={ 'value': sample_position_x, 'units': 'microns', 'dataset_opts': { 'dtype': 'd' } })) if (sample_position_y != None): f.add_entry( DataExchangeEntry.acquisition( sample_position_y={ 'value': sample_position_y, 'units': 'microns', 'dataset_opts': { 'dtype': 'd' } })) if (sample_position_z != None): f.add_entry( DataExchangeEntry.acquisition( sample_position_z={ 'value': sample_position_z, 'units': 'microns', 'dataset_opts': { 'dtype': 'd' } })) if (sample_image_shift_x != None): f.add_entry( DataExchangeEntry.acquisition( sample_image_shift_x={ 'value': sample_image_shift_x, 'units': 'microns', 'dataset_opts': { 'dtype': 'd' } })) if (sample_image_shift_y != None): f.add_entry( DataExchangeEntry.acquisition( sample_image_shift_y={ 'value': sample_image_shift_y, 'units': 'microns', 'dataset_opts': { 'dtype': 'd' } })) f.close() self.logger.info("DONE!!!!. Created Data Exchange File [%s]", hdf5_file_name) else: self.logger.warning("Nothing to do ...")
def write_example(filename): # --- prepare data --- # Generate fake raw data rawdata = np.ones(180 * 256 * 256, np.uint16).reshape(180, 256, 256) # x, y and z ranges x = np.arange(128) y = np.arange(128) z = np.arange(180) # --- create file --- # Open HDF5 file f = DataExchangeFile(filename, mode='w') # Create core HDF5 dataset in exchange group for 180 deep stack of x,y # images /exchange/data f.add_entry( DataExchangeEntry.data( data={ 'value': rawdata, 'units': 'counts', 'description': 'Projection Data', 'dataset_opts': { 'compression': 'gzip', 'compression_opts': 4 } })) # Create HDF5 subgroup # /measurement/sample f.add_entry( DataExchangeEntry.sample(name={'value': 'Minivirus'}, temperature={ 'value': 200.0, 'units': 'celsius', 'dataset_opts': { 'dtype': 'd' } })) # Create HDF5 subgroup # /measurement/instrument f.add_entry(DataExchangeEntry.instrument(name={'value': 'APS 2-BM'})) # Create HDF5 subgroup # /measurement/instrument/monochromator f.add_entry( DataExchangeEntry.monochromator(name={'value': 'DMM'}, energy={ 'value': 10.00, 'units': 'keV', 'dataset_opts': { 'dtype': 'd' } })) # --- All done --- f.close()
def nexus(self, file_name, hdf5_file_name, projections_start=None, projections_end=None, projections_step=None, slices_start=None, slices_end=None, slices_step=None, pixels_start=None, pixels_end=None, pixels_step=None, white_start=None, white_end=None, dark_start=None, dark_end=None, array_name='entry/instrument/detector/data', sample_name=None, dtype='float32'): """ Read Data Exchange HDF5 file. Parameters ---------- file_name : str Input file. projections_start, projections_end, projections_step : scalar, optional Values of the start, end and step of the projections to be used for slicing for the whole ndarray. slices_start, slices_end, slices_step : scalar, optional Values of the start, end and step of the slices to be used for slicing for the whole ndarray. pixels_start, pixels_end, pixels_step : scalar, optional Values of the start, end and step of the pixels to be used for slicing for the whole ndarray. white_start, white_end : scalar, optional Values of the start, end and step of the slicing for the whole white field shots. dark_start, dark_end : scalar, optional Values of the start, end and step of the slicing for the whole dark field shots. dtype : str, optional Desired output data type. """ print "Reading NeXus file ..." self.file_name = file_name # Initialize f to null. f = None # Get the file_name in lower case. lFn = file_name.lower() # Split the string with the delimeter '.' end = lFn.split('.') # If the string has an extension. if len(end) > 1: # Check. if end[len(end) - 1] == 'h5' or end[len(end) - 1] == 'hdf': f = Hdf5() # If f != None the call read on it. if not f == None: # Read data from exchange group. self.data = f.read(file_name, array_name=array_name, x_start=projections_start, x_end=projections_end, x_step=projections_step, y_start=slices_start, y_end=slices_end, y_step=slices_step, z_start=pixels_start, z_end=pixels_end, z_step=pixels_step).astype(dtype) # Read white field data from exchange group. print white_start, white_end, slices_start, slices_end self.white = f.read(file_name, array_name=array_name, x_start=white_start, x_end=white_end, y_start=slices_start, y_end=slices_end, y_step=slices_step, z_start=pixels_start, z_end=pixels_end, z_step=pixels_step).astype(dtype) # Read dark field data from exchange group. self.dark = f.read(file_name, array_name=array_name, x_start=dark_start, x_end=dark_end, y_start=slices_start, y_end=slices_end, y_step=slices_step, z_start=pixels_start, z_end=pixels_end, z_step=pixels_step).astype(dtype) # Assign the rotation center. self.center = self.data.shape[2] / 2 # Write HDF5 file. # Open DataExchange file f = DataExchangeFile(hdf5_file_name, mode='w') logger.info("Writing the HDF5 file") # Create core HDF5 dataset in exchange group for projections_theta_range # deep stack of x,y images /exchange/data f.add_entry( DataExchangeEntry.data(data={'value': self.data, 'units':'counts', 'description': 'transmission', 'axes':'theta:y:x', 'dataset_opts': {'compression': 'gzip', 'compression_opts': 4} })) f.add_entry( DataExchangeEntry.data(theta={'value': self.theta, 'units':'degrees'})) f.add_entry( DataExchangeEntry.data(data_dark={'value': self.dark, 'units':'counts', 'axes':'theta_dark:y:x', 'dataset_opts': {'compression': 'gzip', 'compression_opts': 4} })) f.add_entry( DataExchangeEntry.data(data_white={'value': self.white, 'units':'counts', 'axes':'theta_white:y:x', 'dataset_opts': {'compression': 'gzip', 'compression_opts': 4} })) f.add_entry( DataExchangeEntry.data(title={'value': 'tomography_raw_projections'})) logger.info("Sample name = %s", sample_name) if (sample_name == None): sample_name = end[0] f.add_entry( DataExchangeEntry.sample( name={'value':sample_name}, description={'value':'Sample name was assigned by the HDF5 converter and based on the HDF5 fine name'})) logger.info("Assigned default file name: %s", end[0]) else: f.add_entry( DataExchangeEntry.sample( name={'value':sample_name}, description={'value':'Sample name was read from the user log file'})) logger.info("Assigned file name from user log") f.close() else: print 'Unsupported file.'