예제 #1
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def _build_chunk_position(chunk, headers, obs_id):
    # DB 18-08-19
    # Ignoring rotation for now:  Use CRVAL1 = RA from header, CRVAL2 = DEC
    # from header.  NAXIS1/NAXIS2 values gives number of pixels along RA/DEC
    # axes (again, ignoring rotation) and assume CRPIX1 = NAXIS1/2.0 and
    # CRPIX2 = NAXIS2/2.0 (i.e. in centre of image).   XBINNING/YBINNING
    # give binning values along RA/DEC axes.   CDELT1 (scale in
    # degrees/pixel; it’s 3 arcsec/unbinned pixel)= 3.0*XBINNING/3600.0
    # CDELT2 = 3.0*YBINNING/3600.0.  Set CROTA2=0.0
    header = headers[0]
    ra = get_ra(header)
    dec = get_dec(header)
    if ra is None or dec is None:
        logging.warning(f'No position information for {obs_id}')
        chunk.naxis = None
    else:
        header['CTYPE1'] = 'RA---TAN'
        header['CTYPE2'] = 'DEC--TAN'
        header['CUNIT1'] = 'deg'
        header['CUNIT2'] = 'deg'
        header['CRVAL1'] = ra
        header['CRVAL2'] = dec
        header['CRPIX1'] = get_position_axis_function_naxis1(header)
        header['CRPIX2'] = get_position_axis_function_naxis2(header)

        wcs_parser = WcsParser(header, obs_id, 0)
        if chunk is None:
            chunk = Chunk()
        wcs_parser.augment_position(chunk)

        x_binning = header.get('XBINNING')
        if x_binning is None:
            x_binning = 1.0
        cdelt1 = 3.0 * x_binning / 3600.0
        y_binning = header.get('YBINNING')
        if y_binning is None:
            y_binning = 1.0
        cdelt2 = 3.0 * y_binning / 3600.0

        objct_rol = header.get('OBJCTROL')
        if objct_rol is None:
            objct_rol = 0.0

        crota2 = 90.0 - objct_rol
        crota2_rad = math.radians(crota2)
        cd11 = cdelt1 * math.cos(crota2_rad)
        cd12 = abs(cdelt2) * _sign(cdelt1) * math.sin(crota2_rad)
        cd21 = -abs(cdelt1) * _sign(cdelt2) * math.sin(crota2_rad)
        cd22 = cdelt2 * math.cos(crota2_rad)

        dimension = Dimension2D(header.get('NAXIS1'), header.get('NAXIS2'))
        x = RefCoord(get_position_axis_function_naxis1(header), get_ra(header))
        y = RefCoord(get_position_axis_function_naxis2(header),
                     get_dec(header))
        ref_coord = Coord2D(x, y)
        function = CoordFunction2D(dimension, ref_coord, cd11, cd12, cd21,
                                   cd22)
        chunk.position.axis.function = function
        chunk.position_axis_1 = 1
        chunk.position_axis_2 = 2
예제 #2
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def test_augment_artifact_position_from_blueprint():
    test_blueprint = ObsBlueprint(position_axes=(1, 2))
    test_blueprint.set('Chunk.positionAxis1', '1')
    test_blueprint.set('Chunk.positionAxis2', '2')
    test_blueprint.set('Chunk.position.axis.axis1.ctype', 'GLON-CAR')
    test_blueprint.set('Chunk.position.axis.axis1.cunit', 'deg')
    test_blueprint.set('Chunk.position.axis.axis2.ctype', 'GLAT-CAR')
    test_blueprint.set('Chunk.position.axis.axis2.cunit', 'deg')
    test_blueprint.set('Chunk.position.axis.function.cd11', '-0.004999999')
    test_blueprint.set('Chunk.position.axis.function.cd12', '0.0')
    test_blueprint.set('Chunk.position.axis.function.cd21', '0.0')
    test_blueprint.set('Chunk.position.axis.function.cd22', '0.004999999')
    test_blueprint.set('Chunk.position.axis.function.dimension.naxis1', '1')
    test_blueprint.set('Chunk.position.axis.function.dimension.naxis2', '1')
    test_blueprint.set('Chunk.position.axis.range.start.coord1.pix', '513.0')
    test_blueprint.set('Chunk.position.axis.range.start.coord1.val',
                       '128.7499990027')
    test_blueprint.set('Chunk.position.axis.range.start.coord2.pix', '513.0')
    test_blueprint.set('Chunk.position.axis.range.start.coord2.val',
                       '-0.9999999922536')
    test_fitsparser = FitsParser(sample_file_4axes,
                                 test_blueprint,
                                 uri='test_parser')
    test_chunk = Chunk()
    test_fitsparser._try_position_with_blueprint(test_chunk, 0)
    ex = _get_from_str_xml(EXPECTED_POSITION_XML,
                           ObservationReader()._get_spatial_wcs, 'position')
    result = get_differences(ex, test_chunk.position)
    assert result is None
예제 #3
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def copy_chunk(from_chunk, features=None):
    """Make a copy of a Chunk. This works around the CAOM2 constraint
    'org.postgresql.util.PSQLException: ERROR: duplicate key value violates
    unique constraint "chunk_pkey"', when trying to use the same chunk
    information in different parts (e.g. when referring to hdf5 files).

    :param from_chunk Chunk of which to make a copy
    :param features which version of CAOM to use
    :return a copy of the from_chunk
    """
    if features is not None and features.supports_latest_caom:
        copy = Chunk(
            product_type=from_chunk.product_type,
            naxis=from_chunk.naxis,
            position_axis_1=from_chunk.position_axis_1,
            position_axis_2=from_chunk.position_axis_2,
            position=from_chunk.position,
            energy_axis=from_chunk.energy_axis,
            energy=from_chunk.energy,
            time_axis=from_chunk.time_axis,
            time=from_chunk.time,
            custom_axis=from_chunk.custom_axis,
            custom=from_chunk.custom,
            polarization_axis=from_chunk.polarization_axis,
            polarization=from_chunk.polarization,
            observable_axis=from_chunk.observable_axis,
            observable=from_chunk.observable,
        )
        copy.meta_producer = from_chunk.meta_producer
    else:
        copy = Chunk(
            product_type=from_chunk.product_type,
            naxis=from_chunk.naxis,
            position_axis_1=from_chunk.position_axis_1,
            position_axis_2=from_chunk.position_axis_2,
            position=from_chunk.position,
            energy_axis=from_chunk.energy_axis,
            energy=from_chunk.energy,
            time_axis=from_chunk.time_axis,
            time=from_chunk.time,
            polarization_axis=from_chunk.polarization_axis,
            polarization=from_chunk.polarization,
            observable_axis=from_chunk.observable_axis,
            observable=from_chunk.observable,
        )
    return copy
예제 #4
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    def update(self, observation, omm_name, file_info):
        """Called to fill multiple CAOM model elements and/or attributes, must
        have this signature for import_module loading and execution.

        :param observation A CAOM Observation model instance.
        :param omm_name OmmName instance
        :param file_info cadcdata.FileInfo instance
        """
        self._logger.debug('Begin update.')
        self._update_telescope_location(observation)

        for plane in observation.planes.values():
            for artifact in plane.artifacts.values():
                if omm_name.product_id != plane.product_id:
                    continue
                fits2caom2.update_artifact_meta(artifact, file_info)
                for part in artifact.parts.values():
                    if len(part.chunks) == 0 and part.name == '0':
                        # always have a time axis, and usually an energy
                        # axis as well, so create a chunk for the zero-th part
                        part.chunks.append(Chunk())

                    for chunk in part.chunks:
                        chunk.product_type = self.get_product_type(0)
                        self._update_energy(chunk)
                        self._update_time(chunk, observation.observation_id)
                        self._update_position(plane, observation.intent, chunk)
                        if chunk.position is None:
                            # for WCS validation correctness
                            chunk.naxis = None
                            chunk.energy_axis = None
                            chunk.time_axis = None

                if omm_name.is_rejected():
                    self._update_requirements(observation)

            if OmmName.is_composite(plane.product_id):
                if OmmChooser.change_type(observation):
                    observation = cc.change_to_composite(observation)
                    self._logger.info(
                        f'Changing from Simple to Composite for '
                        f'{observation.observation_id}'
                    )
                self._update_provenance(observation)

        if (
            observation.instrument is None
            or observation.instrument.name is None
            or len(observation.instrument.name) == 0
        ):
            self._update_instrument_name(observation)

        self._logger.debug('Done update.')
        return observation
예제 #5
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def update(observation, **kwargs):
    """Called to fill multiple CAOM model elements and/or attributes, must
    have this signature for import_module loading and execution.

    :param observation A CAOM Observation model instance.
    :param **kwargs Everything else."""
    logging.debug('Begin update.')
    mc.check_param(observation, Observation)

    headers = None
    if 'headers' in kwargs:
        headers = kwargs['headers']
    fqn = None
    if 'fqn' in kwargs:
        fqn = kwargs['fqn']

    logging.error(type(headers))
    logging.error(type(headers[0]))

    _update_telescope_location(observation, headers)

    for plane in observation.planes:
        for artifact in observation.planes[plane].artifacts:
            parts = observation.planes[plane].artifacts[artifact].parts
            for part in parts:
                p = parts[part]
                if len(p.chunks) == 0 and part == '0':
                    # always have a time axis, and usually an energy
                    # axis as well, so create a chunk for the zero-th part
                    p.chunks.append(Chunk())

                for chunk in p.chunks:
                    chunk.naxis = 4
                    chunk.product_type = get_product_type(headers[0])
                    _update_energy(chunk, headers)
                    _update_time(chunk, headers)
                    _update_position(chunk, headers)

    if observation.observation_id.endswith('_REJECT'):
        _update_requirements(observation)

    if (observation.instrument is None or observation.instrument.name is None
            or len(observation.instrument.name) == 0):
        _update_instrument_name(observation)

    if OmmName.is_composite(observation.observation_id):
        if OmmChooser().needs_delete(observation):
            observation = _update_observation_type(observation)
        _update_provenance(observation, headers)
        # _update_time_bounds(observation, fqn)

    logging.debug('Done update.')
    return True
예제 #6
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def test_augment_artifact_polarization_from_blueprint():
    test_blueprint = ObsBlueprint(polarization_axis=1)
    test_blueprint.set('Chunk.polarizationAxis', '1')
    test_blueprint.set('Chunk.polarization.axis.axis.ctype', 'STOKES')
    test_blueprint.set('Chunk.polarization.axis.function.refCoord.pix', '1.0')
    test_blueprint.set('Chunk.polarization.axis.function.refCoord.val', '1.0')
    test_blueprint.set('Chunk.polarization.axis.function.delta', '1.0')
    test_blueprint.set('Chunk.polarization.axis.function.naxis', '1')
    test_fitsparser = FitsParser(sample_file_4axes,
                                 test_blueprint,
                                 uri='test_parser')
    test_chunk = Chunk()
    test_fitsparser._try_polarization_with_blueprint(test_chunk, 0)
    ex = _get_from_str_xml(EXPECTED_POLARIZATION_XML,
                           ObservationReader()._get_polarization_wcs,
                           'polarization')
    result = get_differences(ex, test_chunk.polarization)
    assert result is None
예제 #7
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def test_augment_artifact_energy_from_blueprint():
    test_blueprint = ObsBlueprint(energy_axis=1)
    test_blueprint.set('Chunk.energyAxis', 1)
    test_blueprint.set('Chunk.energy.specsys', 'LSRK')
    test_blueprint.set('Chunk.energy.axis.axis.ctype', 'VRAD')
    test_blueprint.set('Chunk.energy.axis.axis.cunit', 'm / s')
    test_blueprint.set('Chunk.energy.axis.function.refCoord.pix', '145.0')
    test_blueprint.set('Chunk.energy.axis.function.refCoord.val', '-60000.0')
    test_blueprint.set('Chunk.energy.axis.function.delta', '-824.46002')
    test_blueprint.set('Chunk.energy.axis.function.naxis', '1')
    test_fitsparser = FitsParser(sample_file_4axes,
                                 test_blueprint,
                                 uri='ad:TEST/test_blueprint')
    test_chunk = Chunk()
    test_fitsparser._try_energy_with_blueprint(test_chunk, 0)
    ex = _get_from_str_xml(EXPECTED_ENERGY_XML,
                           ObservationReader()._get_spectral_wcs, 'energy')
    result = get_differences(ex, test_chunk.energy)
    assert result is None
예제 #8
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def test_augment_artifact_time_from_blueprint():
    test_blueprint = ObsBlueprint(time_axis=1)
    test_blueprint.set('Chunk.timeAxis', '1')
    test_blueprint.set('Chunk.time.exposure', '0.02')
    test_blueprint.set('Chunk.time.resolution', '0.02')
    test_blueprint.set('Chunk.time.timesys', 'UTC')
    test_blueprint.set('Chunk.time.axis.axis.ctype', 'TIME')
    test_blueprint.set('Chunk.time.axis.axis.cunit', 'd')
    test_blueprint.set('Chunk.time.axis.error.syser', '1e-07')
    test_blueprint.set('Chunk.time.axis.error.rnder', '1e-07')
    test_blueprint.set('Chunk.time.axis.function.refCoord.pix', '0.5')
    test_blueprint.set('Chunk.time.axis.function.refCoord.val',
                       '56789.4298069')
    test_blueprint.set('Chunk.time.axis.function.delta', '2.31481e-07')
    test_blueprint.set('Chunk.time.axis.function.naxis', '1')
    test_fitsparser = FitsParser(sample_file_4axes,
                                 test_blueprint,
                                 uri='ad:TEST/test_blueprint')
    test_chunk = Chunk()
    test_fitsparser._try_time_with_blueprint(test_chunk, 0)
    ex = _get_from_str_xml(EXPECTED_CFHT_WIRCAM_RAW_GUIDE_CUBE_TIME,
                           ObservationReader()._get_temporal_wcs, 'time')
    result = get_differences(ex, test_chunk.time)
    assert result is None
예제 #9
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def test_augment_artifact_bounds_range_from_blueprint():
    test_blueprint = ObsBlueprint(energy_axis=1,
                                  time_axis=2,
                                  polarization_axis=3,
                                  position_axes=(4, 5))
    test_blueprint.set('Chunk.energy.axis.range.start.pix', '145.0')
    test_blueprint.set('Chunk.energy.axis.range.start.val', '-60000.0')
    test_blueprint.set('Chunk.energy.axis.range.end.pix', '-824.46002')
    test_blueprint.set('Chunk.energy.axis.range.end.val', '1')
    test_blueprint.set('Chunk.time.axis.range.start.pix', '145.0')
    test_blueprint.set('Chunk.time.axis.range.start.val', '-60000.0')
    test_blueprint.set('Chunk.time.axis.range.end.pix', '-824.46002')
    test_blueprint.set('Chunk.time.axis.range.end.val', '1')
    test_blueprint.set('Chunk.polarization.axis.range.start.pix', '145.0')
    test_blueprint.set('Chunk.polarization.axis.range.start.val', '-60000.0')
    test_blueprint.set('Chunk.polarization.axis.range.end.pix', '-824.46002')
    test_blueprint.set('Chunk.polarization.axis.range.end.val', '1')
    test_blueprint.set('Chunk.position.axis.range.start.coord1.pix', '145.0')
    test_blueprint.set('Chunk.position.axis.range.start.coord1.val',
                       '-60000.0')
    test_blueprint.set('Chunk.position.axis.range.end.coord1.pix',
                       '-824.46002')
    test_blueprint.set('Chunk.position.axis.range.end.coord1.val', '1')
    test_blueprint.set('Chunk.position.axis.range.start.coord2.pix', '145.0')
    test_blueprint.set('Chunk.position.axis.range.start.coord2.val',
                       '-60000.0')
    test_blueprint.set('Chunk.position.axis.range.end.coord2.pix',
                       '-824.46002')
    test_blueprint.set('Chunk.position.axis.range.end.coord2.val', '1')
    test_fitsparser = FitsParser(sample_file_4axes,
                                 test_blueprint,
                                 uri='ad:TEST/test_blueprint')
    test_chunk = Chunk()
    test_chunk.energy = SpectralWCS(CoordAxis1D(Axis('WAVE', 'm')), 'TOPOCENT')
    test_chunk.time = TemporalWCS(CoordAxis1D(Axis('TIME', 'd')))
    test_chunk.polarization = PolarizationWCS(CoordAxis1D(Axis('STOKES')))
    test_chunk.position = SpatialWCS(
        CoordAxis2D(Axis('RA', 'deg'), Axis('DEC', 'deg')))
    test_fitsparser._try_range_with_blueprint(test_chunk, 0)

    assert test_chunk.energy.axis.range is not None, \
        'chunk.energy.axis.range should be declared'
    assert test_chunk.time.axis.range is not None, \
        'chunk.time.axis.range should be declared'
    assert test_chunk.polarization.axis.range is not None, \
        'chunk.polarization.axis.range should be declared'
    assert test_chunk.position.axis.range is not None, \
        'chunk.position.axis.range should be declared'
    ex = _get_from_str_xml(EXPECTED_ENERGY_RANGE_BOUNDS_XML,
                           ObservationReader()._get_spectral_wcs, 'energy')
    assert ex is not None, \
        'energy string from expected output should be declared'
    result = get_differences(ex, test_chunk.energy)
    assert result is None

    ex = _get_from_str_xml(EXPECTED_TIME_RANGE_BOUNDS_XML,
                           ObservationReader()._get_temporal_wcs, 'time')
    assert ex is not None, \
        'time string from expected output should be declared'
    result = get_differences(ex, test_chunk.time)
    assert result is None

    ex = _get_from_str_xml(EXPECTED_POL_RANGE_BOUNDS_XML,
                           ObservationReader()._get_polarization_wcs,
                           'polarization')
    assert ex is not None, \
        'polarization string from expected output should be declared'
    result = get_differences(ex, test_chunk.polarization)
    assert result is None

    ex = _get_from_str_xml(EXPECTED_POS_RANGE_BOUNDS_XML,
                           ObservationReader()._get_spatial_wcs, 'position')
    assert ex is not None, \
        'position string from expected output should be declared'
    result = get_differences(ex, test_chunk.position)
    assert result is None
예제 #10
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 def test_compute(self):
     # _choose_product returns Artifact.product (SCIENCE),
     # user_chunk = False
     test_chunk = Chunk()
     test_chunk.product_type = chunk.ProductType.CALIBRATION
     test_chunk.custom = CustomTestUtil.good_wcs()
     test_chunks = TypedList(Chunk, test_chunk)
     part_name = "test_part"
     part_product_type = chunk.ProductType.CALIBRATION
     part = Part(part_name, part_product_type, test_chunks)
     uri = 'mast:HST/product/test_file.jpg'
     artifact_product_type = chunk.ProductType.SCIENCE
     release_type = ReleaseType.DATA
     artifact = Artifact(uri, artifact_product_type, release_type)
     artifact.parts = TypedOrderedDict((Part), (part_name, part))
     artifacts = TypedList(Artifact, artifact)
     actual_axis = wcs_util.CustomAxisUtil.compute(artifacts)
     expected_axis = None
     self.assertEqual(expected_axis, actual_axis)
     # _choose_product returns Artifact.product (CALIBRATION),
     # user_chunk = False
     test_chunk = Chunk()
     test_chunk.product_type = chunk.ProductType.SCIENCE
     test_chunk.custom = CustomTestUtil.good_wcs()
     test_chunks = TypedList(Chunk, test_chunk)
     part_name = "test_part"
     part_product_type = chunk.ProductType.SCIENCE
     part = Part(part_name, part_product_type, test_chunks)
     uri = 'mast:HST/product/test_file.jpg'
     artifact_product_type = chunk.ProductType.CALIBRATION
     release_type = ReleaseType.DATA
     artifact = Artifact(uri, artifact_product_type, release_type)
     artifact.parts = TypedOrderedDict((Part), (part_name, part))
     artifacts = TypedList(Artifact, artifact)
     actual_axis = wcs_util.CustomAxisUtil.compute(artifacts)
     expected_axis = None
     self.assertEqual(expected_axis, actual_axis)
     # _choose_product returns Part.product (SCIENCE),
     # user_chunk = False
     test_chunk = Chunk()
     test_chunk.product_type = chunk.ProductType.SCIENCE
     test_chunk.custom = CustomTestUtil.good_wcs()
     test_chunks = TypedList(Chunk, test_chunk)
     part_name = "test_part"
     part_product_type = chunk.ProductType.SCIENCE
     part = Part(part_name, part_product_type, test_chunks)
     uri = 'mast:HST/product/test_file.jpg'
     artifact_product_type = chunk.ProductType.PREVIEW
     release_type = ReleaseType.DATA
     artifact = Artifact(uri, artifact_product_type, release_type)
     artifact.parts = TypedOrderedDict((Part), (part_name, part))
     artifacts = TypedList(Artifact, artifact)
     actual_axis = wcs_util.CustomAxisUtil.compute(artifacts)
     expected_axis = None
     self.assertEqual(expected_axis, actual_axis)
     # _choose_product returns Part.product (CALIBRATION),
     # user_chunk = False
     test_chunk = Chunk()
     test_chunk.product_type = chunk.ProductType.SCIENCE
     test_chunk.custom = CustomTestUtil.good_wcs()
     test_chunks = TypedList(Chunk, test_chunk)
     part_name = "test_part"
     part_product_type = chunk.ProductType.CALIBRATION
     part = Part(part_name, part_product_type, test_chunks)
     uri = 'mast:HST/product/test_file.jpg'
     artifact_product_type = chunk.ProductType.PREVIEW
     release_type = ReleaseType.DATA
     artifact = Artifact(uri, artifact_product_type, release_type)
     artifact.parts = TypedOrderedDict((Part), (part_name, part))
     artifacts = TypedList(Artifact, artifact)
     actual_axis = wcs_util.CustomAxisUtil.compute(artifacts)
     expected_axis = None
     self.assertEqual(expected_axis, actual_axis)
     # _choose_product returns Chunk.product (SCIENCE), user_chunk = False
     test_chunk = Chunk()
     test_chunk.product_type = chunk.ProductType.SCIENCE
     test_chunk.custom = CustomTestUtil.good_wcs()
     test_chunks = TypedList(Chunk, test_chunk)
     part_name = "test_part"
     part_product_type = chunk.ProductType.PREVIEW
     part = Part(part_name, part_product_type, test_chunks)
     uri = 'mast:HST/product/test_file.jpg'
     artifact_product_type = chunk.ProductType.PREVIEW
     release_type = ReleaseType.DATA
     artifact = Artifact(uri, artifact_product_type, release_type)
     artifact.parts = TypedOrderedDict((Part), (part_name, part))
     artifacts = TypedList(Artifact, artifact)
     actual_axis = wcs_util.CustomAxisUtil.compute(artifacts)
     expected_axis = None
     self.assertEqual(expected_axis, actual_axis)
     # _choose_product returns Chunk.product (CALIBRATION),
     # user_chunk = False
     test_chunk = Chunk()
     test_chunk.product_type = chunk.ProductType.CALIBRATION
     test_chunk.custom = CustomTestUtil.good_wcs()
     test_chunks = TypedList(Chunk, test_chunk)
     part_name = "test_part"
     part_product_type = chunk.ProductType.PREVIEW
     part = Part(part_name, part_product_type, test_chunks)
     uri = 'mast:HST/product/test_file.jpg'
     artifact_product_type = chunk.ProductType.PREVIEW
     release_type = ReleaseType.DATA
     artifact = Artifact(uri, artifact_product_type, release_type)
     artifact.parts = TypedOrderedDict((Part), (part_name, part))
     artifacts = TypedList(Artifact, artifact)
     actual_axis = wcs_util.CustomAxisUtil.compute(artifacts)
     expected_axis = None
     self.assertEqual(expected_axis, actual_axis)
     # _choose_product returns None, user_chunk = False
     test_chunk = Chunk()
     test_chunk.product_type = chunk.ProductType.PREVIEW
     test_chunk.custom = CustomTestUtil.good_wcs()
     test_chunks = TypedList(Chunk, test_chunk)
     part_name = "test_part"
     part_product_type = chunk.ProductType.PREVIEW
     part = Part(part_name, part_product_type, test_chunks)
     uri = 'mast:HST/product/test_file.jpg'
     artifact_product_type = chunk.ProductType.PREVIEW
     release_type = ReleaseType.DATA
     artifact = Artifact(uri, artifact_product_type, release_type)
     artifact.parts = TypedOrderedDict((Part), (part_name, part))
     artifacts = TypedList(Artifact, artifact)
     actual_axis = wcs_util.CustomAxisUtil.compute(artifacts)
     expected_axis = None
     self.assertEqual(expected_axis, actual_axis)
     # _choose_product returns Artifact.product (SCIENCE),
     # user_chunk = True, Chunk.custom is None
     test_chunk = Chunk()
     test_chunk.product_type = chunk.ProductType.SCIENCE
     test_chunk.custom = None
     test_chunks = TypedList(Chunk, test_chunk)
     part_name = "test_part"
     part_product_type = chunk.ProductType.SCIENCE
     part = Part(part_name, part_product_type, test_chunks)
     uri = 'mast:HST/product/test_file.jpg'
     artifact_product_type = chunk.ProductType.SCIENCE
     release_type = ReleaseType.DATA
     artifact = Artifact(uri, artifact_product_type, release_type)
     artifact.parts = TypedOrderedDict((Part), (part_name, part))
     artifacts = TypedList(Artifact, artifact)
     expected_axis = None
     actual_axis = wcs_util.CustomAxisUtil.compute(artifacts)
     self.assertEqual(expected_axis, actual_axis)
     # _choose_product returns Artifact.product (SCIENCE),
     # user_chunk = True, Chunk.custom is not None
     # bad Chunk.custom.axis.axis.ctype
     test_chunk = Chunk()
     test_chunk.product_type = chunk.ProductType.SCIENCE
     test_chunk.custom = CustomTestUtil.bad_ctype_wcs()
     test_chunks = TypedList(Chunk, test_chunk)
     part_name = "test_part"
     part_product_type = chunk.ProductType.SCIENCE
     part = Part(part_name, part_product_type, test_chunks)
     uri = 'mast:HST/product/test_file.jpg'
     artifact_product_type = chunk.ProductType.SCIENCE
     release_type = ReleaseType.DATA
     artifact = Artifact(uri, artifact_product_type, release_type)
     artifact.parts = TypedOrderedDict((Part), (part_name, part))
     artifacts = TypedList(Artifact, artifact)
     with pytest.raises(ValueError) as ex:
         actual_axis = wcs_util.CustomAxisUtil.compute(artifacts)
     assert ('Unsupported CTYPE:' in str(ex.value))
     # _choose_product returns Artifact.product (SCIENCE),
     # user_chunk = True, Chunk.custom is not None
     # first_ctype == Chunk.custom.axis.axis.ctype
     test_chunk = Chunk()
     test_chunk.product_type = chunk.ProductType.SCIENCE
     test_chunk.custom = CustomTestUtil.good_wcs_with_function()
     test_chunks = TypedList(Chunk, test_chunk)
     part_name = "test_part"
     part_product_type = chunk.ProductType.SCIENCE
     part = Part(part_name, part_product_type, test_chunks)
     uri = 'mast:HST/product/test_file.jpg'
     artifact_product_type = chunk.ProductType.SCIENCE
     release_type = ReleaseType.DATA
     artifact = Artifact(uri, artifact_product_type, release_type)
     artifact.parts = TypedOrderedDict((Part), (part_name, part))
     artifacts = TypedList(Artifact, artifact)
     expected_ctype = "RM"
     expected_sample = Interval(-49.5, 19950.5)
     expected_samples = [expected_sample]
     expected_bounds = Interval(-49.5, 19950.5, expected_samples)
     expected_dimension = 200
     expected_axis = plane.CustomAxis(expected_ctype, expected_bounds,
                                      expected_dimension)
     actual_axis = wcs_util.CustomAxisUtil.compute(artifacts)
     self.assertEqual(expected_axis.ctype, actual_axis.ctype)
     self.assertEqual(expected_axis.bounds.lower, actual_axis.bounds.lower)
     self.assertEqual(expected_axis.bounds.upper, actual_axis.bounds.upper)
     self.assertEqual(expected_axis.bounds.samples[0].lower,
                      actual_axis.bounds.samples[0].lower)
     self.assertEqual(expected_axis.bounds.samples[0].upper,
                      actual_axis.bounds.samples[0].upper)
     self.assertEqual(expected_axis.dimension, actual_axis.dimension)
     # _choose_product returns Artifact.product (SCIENCE),
     # user_chunk = True, Chunk.custom is not None
     # first_ctype == Chunk.custom.axis.axis.ctype
     test_chunk_1 = Chunk()
     test_chunk_1.product_type = chunk.ProductType.SCIENCE
     test_chunk_1.custom = CustomTestUtil.good_wcs_with_function()
     test_chunk_2 = Chunk()
     test_chunk_2.product_type = chunk.ProductType.SCIENCE
     test_chunk_2.custom = CustomTestUtil.good_wcs_with_function()
     test_chunk_2.custom.axis.axis.ctype = "FARADAY"
     test_chunks = TypedList(Chunk, test_chunk_1, test_chunk_2)
     part_name = "test_part"
     part_product_type = chunk.ProductType.SCIENCE
     part = Part(part_name, part_product_type, test_chunks)
     uri = 'mast:HST/product/test_file.jpg'
     artifact_product_type = chunk.ProductType.SCIENCE
     release_type = ReleaseType.DATA
     artifact = Artifact(uri, artifact_product_type, release_type)
     artifact.parts = TypedOrderedDict((Part), (part_name, part))
     artifacts = TypedList(Artifact, artifact)
     expected_ctype = "RM"
     expected_sample = Interval(-49.5, 19950.5)
     expected_samples = [expected_sample]
     expected_bounds = Interval(-49.5, 19950.5, expected_samples)
     expected_dimension = 200
     expected_axis = plane.CustomAxis(expected_ctype, expected_bounds,
                                      expected_dimension)
     with pytest.raises(ValueError) as ex:
         actual_axis = wcs_util.CustomAxisUtil.compute(artifacts)
     assert ('CTYPE must be the same across all Artifacts' in str(ex.value))
예제 #11
0
 def test_compute_bounds(self):
     # user_chunk = False
     test_chunk = Chunk()
     test_chunk.product_type = chunk.ProductType.SCIENCE
     test_chunk.custom = CustomTestUtil.good_wcs()
     test_chunks = TypedList(Chunk, test_chunk)
     part_name = "test_part"
     part_product_type = chunk.ProductType.SCIENCE
     part = Part(part_name, part_product_type, test_chunks)
     uri = 'mast:HST/product/test_file.jpg'
     artifact_product_type = chunk.ProductType.SCIENCE
     release_type = ReleaseType.DATA
     artifact = Artifact(uri, artifact_product_type, release_type)
     artifact.parts = TypedOrderedDict((Part), (part_name, part))
     artifacts = TypedList(Artifact, artifact)
     product_type = None
     expected_ctype = "RM"
     actual_bounds = wcs_util.CustomAxisUtil.compute_bounds(
         artifacts, product_type, expected_ctype)
     expected_bounds = None
     self.assertEqual(expected_bounds, actual_bounds)
     # user_chunk = True, current_type != expected_ctype
     test_chunk = Chunk()
     test_chunk.product_type = chunk.ProductType.CALIBRATION
     test_chunk.custom = CustomTestUtil.good_wcs_with_function()
     test_chunks = TypedList(Chunk, test_chunk)
     part_name = "test_part"
     part_product_type = chunk.ProductType.CALIBRATION
     part = Part(part_name, part_product_type, test_chunks)
     uri = 'mast:HST/product/test_file.jpg'
     artifact_product_type = chunk.ProductType.CALIBRATION
     release_type = ReleaseType.DATA
     artifact = Artifact(uri, artifact_product_type, release_type)
     artifact.parts = TypedOrderedDict((Part), (part_name, part))
     artifacts = TypedList(Artifact, artifact)
     product_type = chunk.ProductType.CALIBRATION
     expected_ctype = "FARADAY"
     with pytest.raises(ValueError) as ex:
         wcs_util.CustomAxisUtil.compute_bounds(artifacts, product_type,
                                                expected_ctype)
     assert ('CTYPE must be the same across all Artifacts' in str(ex.value))
     # user_chunk = True, range is not None
     test_chunk = Chunk()
     test_chunk.product_type = chunk.ProductType.CALIBRATION
     test_chunk.custom = CustomTestUtil.good_wcs_with_range()
     test_chunks = TypedList(Chunk, test_chunk)
     part_name = "test_part"
     part_product_type = chunk.ProductType.CALIBRATION
     part = Part(part_name, part_product_type, test_chunks)
     uri = 'mast:HST/product/test_file.jpg'
     artifact_product_type = chunk.ProductType.CALIBRATION
     release_type = ReleaseType.DATA
     artifact = Artifact(uri, artifact_product_type, release_type)
     artifact.parts = TypedOrderedDict((Part), (part_name, part))
     artifacts = TypedList(Artifact, artifact)
     product_type = chunk.ProductType.CALIBRATION
     expected_ctype = "RM"
     actual_interval = wcs_util.CustomAxisUtil.compute_bounds(
         artifacts, product_type, expected_ctype)
     expected_interval = Interval(1.1, 11.1)
     self.assertEqual(expected_interval.lower, actual_interval.lower)
     self.assertEqual(expected_interval.upper, actual_interval.upper)
     # user_chunk = True, get_num_pixels: bounds with 3 samples that
     # traverses _merge_into_list completely
     test_chunk = Chunk()
     test_chunk.product_type = chunk.ProductType.CALIBRATION
     test_chunk.custom = CustomTestUtil.good_wcs_with_bounds_3_samples()
     test_chunks = TypedList(Chunk, test_chunk)
     part_name = "test_part"
     part_product_type = chunk.ProductType.CALIBRATION
     part = Part(part_name, part_product_type, test_chunks)
     uri = 'mast:HST/product/test_file.jpg'
     artifact_product_type = chunk.ProductType.CALIBRATION
     release_type = ReleaseType.DATA
     artifact = Artifact(uri, artifact_product_type, release_type)
     artifact.parts = TypedOrderedDict((Part), (part_name, part))
     artifacts = TypedList(Artifact, artifact)
     product_type = chunk.ProductType.CALIBRATION
     expected_ctype = "RM"
     actual_interval = wcs_util.CustomAxisUtil.compute_bounds(
         artifacts, product_type, expected_ctype)
     expected_interval = Interval(-1.2, 11.2)
     self.assertEqual(expected_interval.lower, actual_interval.lower)
     self.assertEqual(expected_interval.upper, actual_interval.upper)
     # user_chunk = True, function is not None
     test_chunk = Chunk()
     test_chunk.product_type = chunk.ProductType.CALIBRATION
     test_chunk.custom = CustomTestUtil.good_wcs_with_function()
     test_chunks = TypedList(Chunk, test_chunk)
     part_name = "test_part"
     part_product_type = chunk.ProductType.CALIBRATION
     part = Part(part_name, part_product_type, test_chunks)
     uri = 'mast:HST/product/test_file.jpg'
     artifact_product_type = chunk.ProductType.CALIBRATION
     release_type = ReleaseType.DATA
     artifact = Artifact(uri, artifact_product_type, release_type)
     artifact.parts = TypedOrderedDict((Part), (part_name, part))
     artifacts = TypedList(Artifact, artifact)
     product_type = chunk.ProductType.CALIBRATION
     expected_ctype = "RM"
     actual_interval = wcs_util.CustomAxisUtil.compute_bounds(
         artifacts, product_type, expected_ctype)
     expected_interval = Interval(-49.5, 19950.5)
     self.assertEqual(expected_interval.lower, actual_interval.lower)
     self.assertEqual(expected_interval.upper, actual_interval.upper)
예제 #12
0
 def test_compute_dimension_from_wcs(self):
     # bounds is None
     bounds = None
     artifacts = None
     product_type = None
     expected_ctype = None
     actual_dimension = wcs_util.CustomAxisUtil.compute_dimension_from_wcs(
         bounds, artifacts, product_type, expected_ctype)
     expected_dimension = None
     self.assertEqual(expected_dimension, actual_dimension)
     # bounds is not None, user_chunk = True, current_type != expected_ctype
     bounds = Interval(1.1, 11.1)
     test_chunk = Chunk()
     test_chunk.product_type = chunk.ProductType.CALIBRATION
     test_chunk.custom = CustomTestUtil.good_wcs_with_function()
     test_chunks = TypedList(Chunk, test_chunk)
     part_name = "test_part"
     part_product_type = chunk.ProductType.CALIBRATION
     part = Part(part_name, part_product_type, test_chunks)
     uri = 'mast:HST/product/test_file.jpg'
     artifact_product_type = chunk.ProductType.CALIBRATION
     release_type = ReleaseType.DATA
     artifact = Artifact(uri, artifact_product_type, release_type)
     artifact.parts = TypedOrderedDict((Part), (part_name, part))
     artifacts = TypedList(Artifact, artifact)
     product_type = chunk.ProductType.CALIBRATION
     expected_ctype = "FARADAY"
     with pytest.raises(ValueError) as ex:
         wcs_util.CustomAxisUtil.compute_dimension_from_wcs(
             bounds, artifacts, product_type, expected_ctype)
     assert ('CTYPE must be the same across all Artifacts' in str(ex.value))
     # bounds is not None, user_chunk = True, current_type is not None and
     # current_type == expected_ctype, ss >= scale, num = 1
     bounds = Interval(1.1, 11.1)
     test_chunk = Chunk()
     test_chunk.product_type = chunk.ProductType.CALIBRATION
     test_chunk.custom = CustomTestUtil.good_wcs_with_negative_delta()
     test_chunks = TypedList(Chunk, test_chunk)
     part_name = "test_part"
     part_product_type = chunk.ProductType.CALIBRATION
     part = Part(part_name, part_product_type, test_chunks)
     uri = 'mast:HST/product/test_file.jpg'
     artifact_product_type = chunk.ProductType.CALIBRATION
     release_type = ReleaseType.DATA
     artifact = Artifact(uri, artifact_product_type, release_type)
     artifact.parts = TypedOrderedDict((Part), (part_name, part))
     artifacts = TypedList(Artifact, artifact)
     product_type = chunk.ProductType.CALIBRATION
     expected_ctype = "RM"
     actual_dimension = wcs_util.CustomAxisUtil.compute_dimension_from_wcs(
         bounds, artifacts, product_type, expected_ctype)
     expected_dimension = 200
     self.assertEqual(expected_dimension, actual_dimension)
     # bounds is not None, user_chunk = False, sw = None
     test_chunk = Chunk()
     test_chunk.product_type = chunk.ProductType.SCIENCE
     test_chunk.custom = CustomTestUtil.good_wcs()
     test_chunks = TypedList(Chunk, test_chunk)
     part_name = "test_part"
     part_product_type = chunk.ProductType.SCIENCE
     part = Part(part_name, part_product_type, test_chunks)
     uri = 'mast:HST/product/test_file.jpg'
     artifact_product_type = chunk.ProductType.SCIENCE
     release_type = ReleaseType.DATA
     artifact = Artifact(uri, artifact_product_type, release_type)
     artifact.parts = TypedOrderedDict((Part), (part_name, part))
     artifacts = TypedList(Artifact, artifact)
     product_type = None
     expected_ctype = "RM"
     actual_dimension = wcs_util.CustomAxisUtil.compute_dimension_from_wcs(
         bounds, artifacts, product_type, expected_ctype)
     expected_dimension = None
     self.assertEqual(expected_dimension, actual_dimension)
     # bounds is not None, user_chunk = True, current_type is not None and
     # current_type == expected_ctype, ss >= scale, num = 2
     bounds = Interval(1.1, 11.1)
     test_chunk1 = Chunk()
     test_chunk1.product_type = chunk.ProductType.CALIBRATION
     test_chunk1.custom = CustomTestUtil.good_wcs_with_negative_delta()
     test_chunk2 = Chunk()
     test_chunk2.product_type = chunk.ProductType.CALIBRATION
     test_chunk2.custom = CustomTestUtil.good_wcs()
     test_chunks = TypedList(Chunk, test_chunk1, test_chunk2)
     part_name = "test_part"
     part_product_type = chunk.ProductType.CALIBRATION
     part = Part(part_name, part_product_type, test_chunks)
     uri = 'mast:HST/product/test_file.jpg'
     artifact_product_type = chunk.ProductType.CALIBRATION
     release_type = ReleaseType.DATA
     artifact = Artifact(uri, artifact_product_type, release_type)
     artifact.parts = TypedOrderedDict((Part), (part_name, part))
     artifacts = TypedList(Artifact, artifact)
     product_type = chunk.ProductType.CALIBRATION
     expected_ctype = "RM"
     actual_dimension = wcs_util.CustomAxisUtil.compute_dimension_from_wcs(
         bounds, artifacts, product_type, expected_ctype)
     expected_dimension = 500
     self.assertEqual(expected_dimension, actual_dimension)
예제 #13
0
 def test_compute_dimension_from_range_bounds(self):
     # user_chunk = False, matches is None
     test_chunk = Chunk()
     test_chunk.product_type = chunk.ProductType.SCIENCE
     test_chunk.custom = CustomTestUtil.good_wcs()
     test_chunks = TypedList(Chunk, test_chunk)
     part_name = "test_part"
     part_product_type = chunk.ProductType.SCIENCE
     part = Part(part_name, part_product_type, test_chunks)
     uri = 'mast:HST/product/test_file.jpg'
     artifact_product_type = chunk.ProductType.SCIENCE
     release_type = ReleaseType.DATA
     artifact = Artifact(uri, artifact_product_type, release_type)
     artifact.parts = TypedOrderedDict((Part), (part_name, part))
     artifacts = TypedList(Artifact, artifact)
     product_type = None
     expected_ctype = "RM"
     actual_num_pixels = \
         wcs_util.CustomAxisUtil.compute_dimension_from_range_bounds(
             artifacts, product_type, expected_ctype)
     expected_num_pixels = None
     self.assertEqual(expected_num_pixels, actual_num_pixels)
     # user_chunk = False, ctype not match
     test_chunk = Chunk()
     test_chunk.product_type = chunk.ProductType.SCIENCE
     test_chunk.custom = CustomTestUtil.good_wcs()
     test_chunks = TypedList(Chunk, test_chunk)
     part_name = "test_part"
     part_product_type = chunk.ProductType.SCIENCE
     part = Part(part_name, part_product_type, test_chunks)
     uri = 'mast:HST/product/test_file.jpg'
     artifact_product_type = chunk.ProductType.SCIENCE
     release_type = ReleaseType.DATA
     artifact = Artifact(uri, artifact_product_type, release_type)
     artifact.parts = TypedOrderedDict((Part), (part_name, part))
     artifacts = TypedList(Artifact, artifact)
     product_type = chunk.ProductType.CALIBRATION
     expected_ctype = "RM"
     actual_num_pixels = \
         wcs_util.CustomAxisUtil.compute_dimension_from_range_bounds(
             artifacts, product_type, expected_ctype)
     expected_num_pixels = None
     self.assertEqual(expected_num_pixels, actual_num_pixels)
     # user_chunk = False, ptype not match
     test_chunk = Chunk()
     test_chunk.product_type = chunk.ProductType.CALIBRATION
     test_chunk.custom = CustomTestUtil.good_wcs()
     test_chunks = TypedList(Chunk, test_chunk)
     part_name = "test_part"
     part_product_type = chunk.ProductType.SCIENCE
     part = Part(part_name, part_product_type, test_chunks)
     uri = 'mast:HST/product/test_file.jpg'
     artifact_product_type = chunk.ProductType.SCIENCE
     release_type = ReleaseType.DATA
     artifact = Artifact(uri, artifact_product_type, release_type)
     artifact.parts = TypedOrderedDict((Part), (part_name, part))
     artifacts = TypedList(Artifact, artifact)
     product_type = chunk.ProductType.CALIBRATION
     expected_ctype = "RM"
     actual_num_pixels = \
         wcs_util.CustomAxisUtil.compute_dimension_from_range_bounds(
             artifacts, product_type, expected_ctype)
     expected_num_pixels = None
     self.assertEqual(expected_num_pixels, actual_num_pixels)
     # user_chunk = False, atype not match
     test_chunk = Chunk()
     test_chunk.product_type = chunk.ProductType.CALIBRATION
     test_chunk.custom = CustomTestUtil.good_wcs()
     test_chunks = TypedList(Chunk, test_chunk)
     part_name = "test_part"
     part_product_type = chunk.ProductType.CALIBRATION
     part = Part(part_name, part_product_type, test_chunks)
     uri = 'mast:HST/product/test_file.jpg'
     artifact_product_type = chunk.ProductType.SCIENCE
     release_type = ReleaseType.DATA
     artifact = Artifact(uri, artifact_product_type, release_type)
     artifact.parts = TypedOrderedDict((Part), (part_name, part))
     artifacts = TypedList(Artifact, artifact)
     product_type = chunk.ProductType.CALIBRATION
     expected_ctype = "RM"
     actual_num_pixels = \
         wcs_util.CustomAxisUtil.compute_dimension_from_range_bounds(
             artifacts, product_type, expected_ctype)
     expected_num_pixels = None
     self.assertEqual(expected_num_pixels, actual_num_pixels)
     # user_chunk = True, current_type != expected_ctype
     test_chunk = Chunk()
     test_chunk.product_type = chunk.ProductType.CALIBRATION
     test_chunk.custom = CustomTestUtil.good_wcs_with_function()
     test_chunks = TypedList(Chunk, test_chunk)
     part_name = "test_part"
     part_product_type = chunk.ProductType.CALIBRATION
     part = Part(part_name, part_product_type, test_chunks)
     uri = 'mast:HST/product/test_file.jpg'
     artifact_product_type = chunk.ProductType.CALIBRATION
     release_type = ReleaseType.DATA
     artifact = Artifact(uri, artifact_product_type, release_type)
     artifact.parts = TypedOrderedDict((Part), (part_name, part))
     artifacts = TypedList(Artifact, artifact)
     product_type = chunk.ProductType.CALIBRATION
     expected_ctype = "FARADAY"
     with pytest.raises(ValueError) as ex:
         wcs_util.CustomAxisUtil.compute_dimension_from_range_bounds(
             artifacts, product_type, expected_ctype)
     assert ('CTYPE must be the same across all Artifacts' in str(ex.value))
     # user_chunk = True, get_num_pixels: range is not None
     test_chunk = Chunk()
     test_chunk.product_type = chunk.ProductType.CALIBRATION
     test_chunk.custom = CustomTestUtil.good_wcs_with_range()
     test_chunks = TypedList(Chunk, test_chunk)
     part_name = "test_part"
     part_product_type = chunk.ProductType.CALIBRATION
     part = Part(part_name, part_product_type, test_chunks)
     uri = 'mast:HST/product/test_file.jpg'
     artifact_product_type = chunk.ProductType.CALIBRATION
     release_type = ReleaseType.DATA
     artifact = Artifact(uri, artifact_product_type, release_type)
     artifact.parts = TypedOrderedDict((Part), (part_name, part))
     artifacts = TypedList(Artifact, artifact)
     product_type = chunk.ProductType.CALIBRATION
     expected_ctype = "RM"
     actual_num_pixels = \
         wcs_util.CustomAxisUtil.compute_dimension_from_range_bounds(
             artifacts, product_type, expected_ctype)
     expected_num_pixels = 10
     self.assertEqual(expected_num_pixels, actual_num_pixels)
     # user_chunk = True, get_num_pixels: bounds with 3 samples that
     # traverses _merge_into_list completely
     test_chunk = Chunk()
     test_chunk.product_type = chunk.ProductType.CALIBRATION
     test_chunk.custom = CustomTestUtil.good_wcs_with_bounds_3_samples()
     test_chunks = TypedList(Chunk, test_chunk)
     part_name = "test_part"
     part_product_type = chunk.ProductType.CALIBRATION
     part = Part(part_name, part_product_type, test_chunks)
     uri = 'mast:HST/product/test_file.jpg'
     artifact_product_type = chunk.ProductType.CALIBRATION
     release_type = ReleaseType.DATA
     artifact = Artifact(uri, artifact_product_type, release_type)
     artifact.parts = TypedOrderedDict((Part), (part_name, part))
     artifacts = TypedList(Artifact, artifact)
     product_type = chunk.ProductType.CALIBRATION
     expected_ctype = "RM"
     actual_num_pixels = \
         wcs_util.CustomAxisUtil.compute_dimension_from_range_bounds(
             artifacts, product_type, expected_ctype)
     expected_num_pixels = 11
     self.assertEqual(expected_num_pixels, actual_num_pixels)
     # user_chunk = True, range = None, bounds = None, use_func and
     # function = None
     test_chunk = Chunk()
     test_chunk.product_type = chunk.ProductType.CALIBRATION
     test_chunk.custom = CustomTestUtil.good_wcs()
     test_chunks = TypedList(Chunk, test_chunk)
     part_name = "test_part"
     part_product_type = chunk.ProductType.CALIBRATION
     part = Part(part_name, part_product_type, test_chunks)
     uri = 'mast:HST/product/test_file.jpg'
     artifact_product_type = chunk.ProductType.CALIBRATION
     release_type = ReleaseType.DATA
     artifact = Artifact(uri, artifact_product_type, release_type)
     artifact.parts = TypedOrderedDict((Part), (part_name, part))
     artifacts = TypedList(Artifact, artifact)
     product_type = chunk.ProductType.CALIBRATION
     expected_ctype = "RM"
     actual_num_pixels = \
         wcs_util.CustomAxisUtil.compute_dimension_from_range_bounds(
             artifacts, product_type, expected_ctype)
     expected_num_pixels = None
     self.assertEqual(expected_num_pixels, actual_num_pixels)
예제 #14
0
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