def test_validate_observation(): obs = SimpleObservation('test_collection', 'test_obs_id', Algorithm('test_name')) validate(obs) obs = DerivedObservation('test_collection', 'test_obs_id', Algorithm('test_name'), proposal=Proposal('test_proposal'), telescope=Telescope('test_telescope'), instrument=Instrument('test_instrument'), target=Target('test_targets')) obs.algorithm.keywords = 'foo' obs.proposal.keywords = set('foo=42') obs.telescope.keywords = set('foo:42') obs.instrument.keywords.add("tick'marks") obs.target.keywords = set('has multiple spaces') test_plane = Plane('test_plane') test_plane.provenance = Provenance('test_provenance') test_plane.provenance.keywords.add('pipe|denied') obs.planes['test_plane'] = test_plane with pytest.raises(AssertionError): validate(obs)
def stuff(args): obs = None index = 0 for f_name in args.local: product_id = args.lineage[index].split('/')[0] t_header = Table.read(f_name, format='hdf5', path='header') # logging.error(t_header.colnames) # ['VERSION_MAJOR', 'VERSION_MINOR', 'TIME_IN_SEC', # 'TIME_IN_MICROSEC', 'RUN_ID', 'ORIGIN', 'OBSMODE', 'FIELD', 'RA', # 'DEC', 'EXPTIME', 'NUM_IMAGER'] # logging.error(t_header) # t_header['RUN_ID'].data[0].decode() - return this string # 20190805T024026 # logging.error(t_header['RUN_ID'].data[0].decode()) release_date = datetime.strptime( t_header['RUN_ID'].data[0].decode(), '%Y%m%dT%H%M%S') t_image = Table.read(f_name, format='hdf5', path='image') # logging.error(t_image.colnames) # ['col0', 'col1', 'col2'] # logging.error(t_image) # logging.error(t_image['col0'].data[0]) # logging.error(t_image['col0'].data[143999]) t_catalog = Table.read(f_name, format='hdf5', path='catalog') # logging.error(t_catalog.colnames) # ['CAT_ID', 'GAIA_ID', '2MASS_ID', 'RA', 'DEC', 'TAOS_MAG', # 'GAIA_MAG', '2MASS_JMAG'] # logging.error(t_catalog) t_imager = Table.read(f_name, format='hdf5', path='imager') # logging.error(t_imager.colnames) # ['TEL_ID', 'CAM_ID', 'IMGR_ID', 'XLOC', 'YLOC'] # logging.error(t_imager) t_moment = Table.read(f_name, format='hdf5', path='moment') # logging.error(t_moment.colnames) # ['col0', 'col1', 'col2'] # logging.error(t_moment) t_window = Table.read(f_name, format='hdf5', path='window') # logging.error(t_window.colnames) # ['X0', 'X1', 'Y0', 'Y1', 'XC', 'YC'] # logging.error(t_window) t_wcs= Table.read(f_name, format='hdf5', path='/wcs/cdmatrix') # ['CRVAL1','CRVAL2','CRPIX1','CRPIX2','CD1_1','CD1_2','CD2_1','CD2_2'] # logging.error(t_wcs) taos = Telescope(name='TAOS', geo_location_x=-2354953.99637757, geo_location_y=-4940160.3636381, geo_location_z=3270123.70695983) target = Target(name=str(t_header['FIELD'].data[0]), target_type=TargetType.FIELD, standard=None, redshift=None, keywords=None, moving=None) proposal = Proposal(id=COLLECTION, pi_name=None, project=COLLECTION, title=None) obs = SimpleObservation(collection=COLLECTION, observation_id=args.observation[1], sequence_number=None, intent=ObservationIntentType.SCIENCE, type='FIELD', proposal=proposal, telescope=taos, instrument=None, target=target, meta_release=release_date) provenance = Provenance(name=COLLECTION, version='{}.{}'.format( t_header['VERSION_MAJOR'].data[0], t_header['VERSION_MINOR'].data[0]), project=COLLECTION, producer=COLLECTION, run_id=t_header['RUN_ID'].data[0].decode(), reference='https://taos2.asiaa.sinica.edu.tw/', last_executed=release_date) plane = Plane(product_id=product_id, data_release=release_date, meta_release=release_date, provenance=provenance, data_product_type=DataProductType.IMAGE, calibration_level=CalibrationLevel.RAW_STANDARD) artifact = mc.get_artifact_metadata( f_name, ProductType.SCIENCE, ReleaseType.DATA, mc.build_uri(COLLECTION, os.path.basename(f_name))) # parts are always named '0' part = Part('0') # do each of the three telescopes for telescope in [0, 1, 2]: position = build_position(t_wcs, t_window, telescope) time = build_time(t_header['TIME_IN_SEC'].data[0], t_header['TIME_IN_MICROSEC'].data[0]) energy = build_energy() chunk = Chunk(naxis=4, position_axis_1=1, position_axis_2=2, energy_axis=3, time_axis=4, position=position, energy=energy, time=time) part.chunks.append(chunk) artifact.parts.add(part) plane.artifacts.add(artifact) obs.planes.add(plane) index += 1 return obs
def _build_obs(override, db_content, fqn, index, almaca_name, md_name): obs_date = db_content['Observation date'][index] if obs_date is None: raise mc.CadcException('No observation date for {}'.format(fqn)) else: obs_date = time.Time(obs_date).to_datetime() # of_site('alma') # 2225015.30883296, -5440016.41799762, -2481631.27428014 # size = db_content['Array'][index] telescope = Telescope(name="ALMA-{}".format(size), geo_location_x=2225142.18, geo_location_y=-5440307.37, geo_location_z=-2481029.852) instrument = Instrument(name=_get_band_name(override)) # HK - 14-08-19 # target: this should be the science target / science fieldname and # not the calibrator fieldname, as it is presently (i.e., should be # J1851+0035, not J1924-2914). Or, we may need to continue to leave # that field blank at this level. A single calibrated measurement set # may contain multiple science target names, which would not be # properly captured at this level. [For the raw data, the target # field is left blank] target = Target(name=override.get('field'), standard=False, moving=False, target_type=TargetType.OBJECT) # HK - 07-02-20 # Since we've changed what the base level observation is and can now list # a target name in the 'Derived Observation' base plane, I believe that # means we can also include that target's position under targetPosition. # You've already pulled this info out for the subsequent levels of the # hierarchy under 'position', so it's presumably fairly straightforward to # include the same info here. result_ra, result_dec = _get_ra_dec(md_name) point = Point(result_ra, result_dec) target_position = TargetPosition( coordinates=point, coordsys='ICRS', # from listobs output equinox=2000.0) # a guess by google # db_content as votable: # >>> t.colnames # ['Project_code', 'Source_name', 'RA', 'Dec', 'Galactic_longitude', # 'Galactic_latitude', 'Band', 'Spatial_resolution', # 'Frequency_resolution', 'Array', 'Mosaic', 'Integration', # 'Release_date', 'Frequency_support', 'Velocity_resolution', # 'Pol_products', 'Observation_date', 'PI_name', 'SB_name', # 'Proposal_authors', 'Line_sensitivity__10_km_s_', # 'Continuum_sensitivity', 'PWV', 'Group_ous_id', 'Member_ous_id', # 'Asdm_uid', 'Project_title', 'Project_type', 'Scan_intent', # 'Field_of_view', 'Largest_angular_scale', 'QA2_Status', 'COUNT', # 'Science_keyword', 'Scientific_category', 'ASA_PROJECT_CODE'] # # db_content.colnames as html: # # ['Project code', 'Source name', 'RA', 'Dec', 'Galactic longitude', # 'Galactic latitude', 'Band', 'Spatial resolution', # 'Frequency resolution', 'Array', 'Mosaic', 'Integration', # 'Release date', 'Frequency support', 'Velocity resolution', # 'Pol products', 'Observation date', 'PI name', 'SB name', # 'Proposal authors', 'Line sensitivity (10 km/s)', # 'Continuum sensitivity', 'PWV', 'Group ous id', 'Member ous id', # 'Asdm uid', 'Project title', 'Project type', 'Scan intent', # 'Field of view', 'Largest angular scale', 'QA2 Status', 'COUNT', # 'Science keyword', 'Scientific category', 'ASA_PROJECT_CODE'] # HK - 14-08-19 # can we include the project code, and not just the observation UID # somewhere in here? For the raw data, it looks like the project # code was included as 'proposal: ID', whereas for the calibrated # measurement set, proposal: ID is now set to the UID and the project # code (2016.1.00010.S) is not captured anywhere. Could the 'project' # field, currently set as 'null' be used for this? proposal = Proposal(id=db_content['Project code'][index], project=override.get('project'), pi_name=db_content['PI name'][index], title=db_content['Project title'][index]) keywords = db_content['Science keyword'][index] if keywords is not None: proposal.keywords = set(keywords.split()) environment = Environment() environment.tau = db_content['PWV'][index] / 0.935 + 0.35 environment.wavelength_tau = 350 * units.um.to(units.meter) intent = (ObservationIntentType.SCIENCE if almaca_name.intent is ProductType.SCIENCE else ObservationIntentType.CALIBRATION) algorithm = Algorithm(name='single band split') # # PD, SG 15-08-19 # make it a composite, algorithm name something like # 'target splitting' # observation = DerivedObservation(collection=ARCHIVE, observation_id=almaca_name.obs_id, sequence_number=None, intent=intent, type="OBJECT", proposal=proposal, telescope=telescope, instrument=instrument, target=target, meta_release=obs_date, algorithm=algorithm, environment=environment, target_position=target_position) observation.members.add( ObservationURI( mc.CaomName.make_obs_uri_from_obs_id('ALMA', 'A001_X88b_X23'))) return observation