Ejemplo n.º 1
0
def init_glacier_directories(rgidf=None, *, reset=False, force=False,
                             from_prepro_level=None, prepro_border=None,
                             prepro_rgi_version=None, prepro_base_url=None,
                             from_tar=False, delete_tar=False,
                             use_demo_glaciers=None):
    """Initializes the list of Glacier Directories for this run.

    This is the very first task to do (always). If the directories are already
    available in the working directory, use them. If not, create new ones.

    Parameters
    ----------
    rgidf : GeoDataFrame or list of ids, optional for pre-computed runs
        the RGI glacier outlines. If unavailable, OGGM will parse the
        information from the glacier directories found in the working
        directory. It is required for new runs.
    reset : bool
        delete the existing glacier directories if found.
    force : bool
        setting `reset=True` will trigger a yes/no question to the user. Set
        `force=True` to avoid this.
    from_prepro_level : int
        get the gdir data from the official pre-processed pool. See the
        documentation for more information
    prepro_border : int
        for `from_prepro_level` only: if you want to override the default
        behavior which is to use `cfg.PARAMS['border']`
    prepro_rgi_version : str
        for `from_prepro_level` only: if you want to override the default
        behavior which is to use `cfg.PARAMS['rgi_version']`
    prepro_base_url : str
        for `from_prepro_level` only: if you want to override the default
        URL from which to download the gdirs. Default currently is
        https://cluster.klima.uni-bremen.de/~fmaussion/gdirs/oggm_v1.1/
    use_demo_glaciers : bool
        whether to check the demo glaciers for download (faster than the
        standard prepro downloads). The default is to decide whether or
        not to check based on simple criteria such as glacier list size.
    from_tar : bool, default=False
        extract the gdir data from a tar file. If set to `True`,
        will check for a tar file at the expected location in `base_dir`.
    delete_tar : bool, default=False
        delete the original tar file after extraction.

    Returns
    -------
    gdirs : list of :py:class:`oggm.GlacierDirectory` objects
        the initialised glacier directories

    Notes
    -----
    This task is very similar to init_glacier_regions, with one main
    difference: it does not process the DEMs for this glacier.
    Eventually, init_glacier_regions will be deprecated and removed from the
    codebase.
    """

    _check_duplicates(rgidf)

    if reset and not force:
        reset = utils.query_yes_no('Delete all glacier directories?')

    if from_prepro_level:
        url = utils.get_prepro_base_url(base_url=prepro_base_url,
                                        border=prepro_border,
                                        prepro_level=from_prepro_level,
                                        rgi_version=prepro_rgi_version)
        if cfg.PARAMS['has_internet'] and not utils.url_exists(url):
            raise InvalidParamsError("base url seems unreachable with these "
                                     "parameters: {}".format(url))

    # if reset delete also the log directory
    if reset:
        fpath = os.path.join(cfg.PATHS['working_dir'], 'log')
        if os.path.exists(fpath):
            rmtree(fpath)

    if rgidf is None:
        # Infer the glacier directories from folders available in working dir
        if reset:
            raise ValueError('Cannot use reset without setting rgidf')
        log.workflow('init_glacier_directories by parsing all available '
                     'folders (this takes time: if possible, provide rgidf '
                     'instead).')
        # The dirs should be there already
        gl_dir = os.path.join(cfg.PATHS['working_dir'], 'per_glacier')
        gdirs = []
        for root, _, files in os.walk(gl_dir):
            if files and ('outlines.shp' in files or
                          'outlines.tar.gz' in files):
                gdirs.append(oggm.GlacierDirectory(os.path.basename(root)))
    else:
        # Create glacier directories from input
        # Check if dataframe or list of str
        try:
            entities = []
            for _, entity in rgidf.iterrows():
                entities.append(entity)
        except AttributeError:
            entities = utils.tolist(rgidf)

        # Check demo
        if use_demo_glaciers is None:
            use_demo_glaciers = len(entities) < 100

        if from_prepro_level is not None:
            log.workflow('init_glacier_directories from prepro level {} on '
                         '{} glaciers.'.format(from_prepro_level,
                                               len(entities)))
            # Read the hash dictionary before we use multiproc
            if cfg.PARAMS['dl_verify']:
                utils.get_dl_verify_data('cluster.klima.uni-bremen.de')
            gdirs = execute_entity_task(gdir_from_prepro, entities,
                                        from_prepro_level=from_prepro_level,
                                        prepro_border=prepro_border,
                                        prepro_rgi_version=prepro_rgi_version,
                                        check_demo_glacier=use_demo_glaciers,
                                        base_url=prepro_base_url)
        else:
            # We can set the intersects file automatically here
            if (cfg.PARAMS['use_intersects'] and
                    len(cfg.PARAMS['intersects_gdf']) == 0):
                try:
                    rgi_ids = np.unique(np.sort([entity.RGIId for entity in
                                                 entities]))
                    rgi_version = rgi_ids[0].split('-')[0][-2:]
                    fp = utils.get_rgi_intersects_entities(rgi_ids,
                                                           version=rgi_version)
                    cfg.set_intersects_db(fp)
                except AttributeError:
                    # List of str
                    pass

            gdirs = execute_entity_task(utils.GlacierDirectory, entities,
                                        reset=reset,
                                        from_tar=from_tar,
                                        delete_tar=delete_tar)

    return gdirs
Ejemplo n.º 2
0
def run_prepro_levels(rgi_version=None,
                      rgi_reg=None,
                      border=None,
                      output_folder='',
                      working_dir='',
                      dem_source='',
                      is_test=False,
                      test_ids=None,
                      demo=False,
                      test_rgidf=None,
                      test_intersects_file=None,
                      test_topofile=None,
                      disable_mp=False,
                      params_file=None,
                      elev_bands=False,
                      match_regional_geodetic_mb=False,
                      match_geodetic_mb_per_glacier=False,
                      evolution_model='fl_sia',
                      centerlines_only=False,
                      override_params=None,
                      add_consensus=False,
                      start_level=None,
                      start_base_url=None,
                      max_level=5,
                      ref_tstars_base_url='',
                      logging_level='WORKFLOW',
                      disable_dl_verify=False,
                      dynamic_spinup=False,
                      dynamic_spinup_start_year=1979,
                      continue_on_error=True):
    """Generate the preprocessed OGGM glacier directories for this OGGM version

    Parameters
    ----------
    rgi_version : str
        the RGI version to use (defaults to cfg.PARAMS)
    rgi_reg : str
        the RGI region to process
    border : int
        the number of pixels at the maps border
    output_folder : str
        path to the output folder (where to put the preprocessed tar files)
    dem_source : str
        which DEM source to use: default, SOURCE_NAME or ALL
    working_dir : str
        path to the OGGM working directory
    ref_tstars_base_url : str
        url where to find the pre-calibrated reference tstar list.
        Required as of v1.4.
    params_file : str
        path to the OGGM parameter file (to override defaults)
    is_test : bool
        to test on a couple of glaciers only!
    test_ids : list
        if is_test: list of ids to process
    demo : bool
        to run the prepro for the list of demo glaciers
    test_rgidf : shapefile
        for testing purposes only
    test_intersects_file : shapefile
        for testing purposes only
    test_topofile : str
        for testing purposes only
    test_crudir : str
        for testing purposes only
    disable_mp : bool
        disable multiprocessing
    elev_bands : bool
        compute all flowlines based on the Huss&Hock 2015 method instead
        of the OGGM default, which is a mix of elev_bands and centerlines.
    centerlines_only : bool
        compute all flowlines based on the OGGM centerline(s) method instead
        of the OGGM default, which is a mix of elev_bands and centerlines.
    match_regional_geodetic_mb : str
        match the regional mass balance estimates at the regional level
        ('hugonnet': Hugonnet et al., 2020 or 'zemp': Zemp et al., 2019).
    match_geodetic_mb_per_glacier : str
        match the mass balance estimates at the glacier level
        (currently only 'hugonnet': Hugonnet et al., 2020).
    evolution_model : str
        which geometry evolution model to use: `fl_sia` (default),
        or `massredis` (mass redistribution curve).
    add_consensus : bool
        adds (reprojects) the consensus estimates thickness to the glacier
        directories. With elev_bands=True, the data will also be binned.
    start_level : int
        the pre-processed level to start from (default is to start from
        scratch). If set, you'll need to indicate start_base_url as well.
    start_base_url : str
        the pre-processed base-url to fetch the data from.
    max_level : int
        the maximum pre-processing level before stopping
    logging_level : str
        the logging level to use (DEBUG, INFO, WARNING, WORKFLOW)
    override_params : dict
        a dict of parameters to override.
    disable_dl_verify : bool
        disable the hash verification of OGGM downloads
    dynamic_spinup: str
        include a dynamic spinup matching 'area' OR 'volume' at the RGI-date
    dynamic_spinup_start_year : int
        if dynamic_spinup is set, define the starting year for the simulation.
        The default is 1979, unless the climate data starts later.
    """

    # Input check
    if max_level not in [1, 2, 3, 4, 5]:
        raise InvalidParamsError('max_level should be one of [1, 2, 3, 4, 5]')

    if start_level is not None:
        if start_level not in [0, 1, 2, 3, 4]:
            raise InvalidParamsError(
                'start_level should be one of [0, 1, 2, 3, 4]')
        if start_level > 0 and start_base_url is None:
            raise InvalidParamsError('With start_level, please also indicate '
                                     'start_base_url')
    else:
        start_level = 0

    if match_regional_geodetic_mb and match_geodetic_mb_per_glacier:
        raise InvalidParamsError(
            'match_regional_geodetic_mb incompatible with '
            'match_geodetic_mb_per_glacier!')

    if match_geodetic_mb_per_glacier and match_geodetic_mb_per_glacier != 'hugonnet':
        raise InvalidParamsError('Currently only `hugonnet` is available for '
                                 'match_geodetic_mb_per_glacier.')

    if evolution_model not in ['fl_sia', 'massredis']:
        raise InvalidParamsError('evolution_model should be one of '
                                 "['fl_sia', 'massredis'].")

    if dynamic_spinup and dynamic_spinup not in ['area', 'volume']:
        raise InvalidParamsError(f"Dynamic spinup option '{dynamic_spinup}' "
                                 "not supported")

    if dynamic_spinup and evolution_model == 'massredis':
        raise InvalidParamsError("Dynamic spinup is not working/tested"
                                 "with massredis!")

    # Time
    start = time.time()

    def _time_log():
        # Log util
        m, s = divmod(time.time() - start, 60)
        h, m = divmod(m, 60)
        log.workflow('OGGM prepro_levels is done! Time needed: '
                     '{:02d}:{:02d}:{:02d}'.format(int(h), int(m), int(s)))

    # Local paths
    if override_params is None:
        override_params = {}

    utils.mkdir(working_dir)
    override_params['working_dir'] = working_dir

    # Initialize OGGM and set up the run parameters
    cfg.initialize(file=params_file,
                   params=override_params,
                   logging_level=logging_level,
                   future=True)

    if match_geodetic_mb_per_glacier and (cfg.PARAMS['hydro_month_nh'] != 1 or
                                          cfg.PARAMS['hydro_month_sh'] != 1):
        raise InvalidParamsError('We recommend to set hydro_month_nh and sh '
                                 'to 1 for the geodetic MB calibration per '
                                 'glacier.')

    # Use multiprocessing?
    cfg.PARAMS['use_multiprocessing'] = not disable_mp

    # How many grid points around the glacier?
    # Make it large if you expect your glaciers to grow large
    cfg.PARAMS['border'] = border

    # Set to True for operational runs
    cfg.PARAMS['continue_on_error'] = continue_on_error

    # Check for the integrity of the files OGGM downloads at run time
    # For large files (e.g. using a 1 tif DEM like ALASKA) calculating the hash
    # takes a long time, so deactivating this can make sense
    cfg.PARAMS['dl_verify'] = not disable_dl_verify

    # Other things that make sense
    cfg.PARAMS['store_model_geometry'] = True

    # Log the parameters
    msg = '# OGGM Run parameters:'
    for k, v in cfg.PARAMS.items():
        if type(v) in [pd.DataFrame, dict]:
            continue
        msg += '\n    {}: {}'.format(k, v)
    log.workflow(msg)

    if rgi_version is None:
        rgi_version = cfg.PARAMS['rgi_version']
    output_base_dir = os.path.join(output_folder, 'RGI{}'.format(rgi_version),
                                   'b_{:03d}'.format(border))

    # Add a package version file
    utils.mkdir(output_base_dir)
    opath = os.path.join(output_base_dir, 'package_versions.txt')
    with open(opath, 'w') as vfile:
        vfile.write(utils.show_versions(logger=log))

    if demo:
        rgidf = utils.get_rgi_glacier_entities(cfg.DATA['demo_glaciers'].index)
    elif test_rgidf is None:
        # Get the RGI file
        rgidf = gpd.read_file(
            utils.get_rgi_region_file(rgi_reg, version=rgi_version))
        # We use intersects
        rgif = utils.get_rgi_intersects_region_file(rgi_reg,
                                                    version=rgi_version)
        cfg.set_intersects_db(rgif)

        # Some RGI input quality checks - this is based on visual checks
        # of large glaciers in the RGI
        ids_to_ice_cap = [
            'RGI60-05.10315',  # huge Greenland ice cap
            'RGI60-03.01466',  # strange thing next to Devon
            'RGI60-09.00918',  # Academy of sciences Ice cap
            'RGI60-09.00969',
            'RGI60-09.00958',
            'RGI60-09.00957',
        ]
        rgidf.loc[rgidf.RGIId.isin(ids_to_ice_cap), 'Form'] = '1'

        # In AA almost all large ice bodies are actually ice caps
        if rgi_reg == '19':
            rgidf.loc[rgidf.Area > 100, 'Form'] = '1'

        # For greenland we omit connectivity level 2
        if rgi_reg == '05':
            rgidf = rgidf.loc[rgidf['Connect'] != 2]
    else:
        rgidf = test_rgidf
        cfg.set_intersects_db(test_intersects_file)

    if is_test:
        if test_ids is not None:
            rgidf = rgidf.loc[rgidf.RGIId.isin(test_ids)]
        else:
            rgidf = rgidf.sample(4)

        if max_level > 2:
            # Also use ref tstars
            utils.apply_test_ref_tstars()

    if max_level > 2 and ref_tstars_base_url:
        workflow.download_ref_tstars(base_url=ref_tstars_base_url)

    log.workflow('Starting prepro run for RGI reg: {} '
                 'and border: {}'.format(rgi_reg, border))
    log.workflow('Number of glaciers: {}'.format(len(rgidf)))

    # L0 - go
    if start_level == 0:
        gdirs = workflow.init_glacier_directories(rgidf,
                                                  reset=True,
                                                  force=True)

        # Glacier stats
        sum_dir = os.path.join(output_base_dir, 'L0', 'summary')
        utils.mkdir(sum_dir)
        opath = os.path.join(sum_dir,
                             'glacier_statistics_{}.csv'.format(rgi_reg))
        utils.compile_glacier_statistics(gdirs, path=opath)

        # L0 OK - compress all in output directory
        log.workflow('L0 done. Writing to tar...')
        level_base_dir = os.path.join(output_base_dir, 'L0')
        workflow.execute_entity_task(utils.gdir_to_tar,
                                     gdirs,
                                     delete=False,
                                     base_dir=level_base_dir)
        utils.base_dir_to_tar(level_base_dir)
        if max_level == 0:
            _time_log()
            return
    else:
        gdirs = workflow.init_glacier_directories(
            rgidf,
            reset=True,
            force=True,
            from_prepro_level=start_level,
            prepro_border=border,
            prepro_rgi_version=rgi_version,
            prepro_base_url=start_base_url)

    # L1 - Add dem files
    if start_level == 0:
        if test_topofile:
            cfg.PATHS['dem_file'] = test_topofile

        # Which DEM source?
        if dem_source.upper() == 'ALL':
            # This is the complex one, just do the job and leave
            log.workflow('Running prepro on ALL sources')
            for i, s in enumerate(utils.DEM_SOURCES):
                rs = i == 0
                log.workflow('Running prepro on sources: {}'.format(s))
                gdirs = workflow.init_glacier_directories(rgidf,
                                                          reset=rs,
                                                          force=rs)
                workflow.execute_entity_task(tasks.define_glacier_region,
                                             gdirs,
                                             source=s)
                workflow.execute_entity_task(_rename_dem_folder,
                                             gdirs,
                                             source=s)

            # make a GeoTiff mask of the glacier, choose any source
            workflow.execute_entity_task(gis.rasterio_glacier_mask,
                                         gdirs,
                                         source='ALL')

            # Compress all in output directory
            level_base_dir = os.path.join(output_base_dir, 'L1')
            workflow.execute_entity_task(utils.gdir_to_tar,
                                         gdirs,
                                         delete=False,
                                         base_dir=level_base_dir)
            utils.base_dir_to_tar(level_base_dir)

            _time_log()
            return

        # Force a given source
        source = dem_source.upper() if dem_source else None

        # L1 - go
        workflow.execute_entity_task(tasks.define_glacier_region,
                                     gdirs,
                                     source=source)

        # Glacier stats
        sum_dir = os.path.join(output_base_dir, 'L1', 'summary')
        utils.mkdir(sum_dir)
        opath = os.path.join(sum_dir,
                             'glacier_statistics_{}.csv'.format(rgi_reg))
        utils.compile_glacier_statistics(gdirs, path=opath)

        # L1 OK - compress all in output directory
        log.workflow('L1 done. Writing to tar...')
        level_base_dir = os.path.join(output_base_dir, 'L1')
        workflow.execute_entity_task(utils.gdir_to_tar,
                                     gdirs,
                                     delete=False,
                                     base_dir=level_base_dir)
        utils.base_dir_to_tar(level_base_dir)
        if max_level == 1:
            _time_log()
            return

    # L2 - Tasks
    if start_level <= 1:
        # Check which glaciers will be processed as what
        if elev_bands:
            gdirs_band = gdirs
            gdirs_cent = []
        elif centerlines_only:
            gdirs_band = []
            gdirs_cent = gdirs
        else:
            # Default is to centerlines_only, but it used to be a mix
            # (e.g. bands for ice caps, etc)
            # I still keep this logic here in case we want to mix again
            gdirs_band = []
            gdirs_cent = gdirs

        log.workflow('Start flowline processing with: '
                     'N centerline type: {}, '
                     'N elev bands type: {}.'
                     ''.format(len(gdirs_cent), len(gdirs_band)))

        # HH2015 method
        workflow.execute_entity_task(tasks.simple_glacier_masks, gdirs_band)

        # Centerlines OGGM
        workflow.execute_entity_task(tasks.glacier_masks, gdirs_cent)

        if add_consensus:
            from oggm.shop.bedtopo import add_consensus_thickness
            workflow.execute_entity_task(add_consensus_thickness, gdirs_band)
            workflow.execute_entity_task(add_consensus_thickness, gdirs_cent)

            # Elev bands with var data
            vn = 'consensus_ice_thickness'
            workflow.execute_entity_task(tasks.elevation_band_flowline,
                                         gdirs_band,
                                         bin_variables=vn)
            workflow.execute_entity_task(
                tasks.fixed_dx_elevation_band_flowline,
                gdirs_band,
                bin_variables=vn)
        else:
            # HH2015 method without it
            task_list = [
                tasks.elevation_band_flowline,
                tasks.fixed_dx_elevation_band_flowline,
            ]
            for task in task_list:
                workflow.execute_entity_task(task, gdirs_band)

        # Centerlines OGGM
        task_list = [
            tasks.compute_centerlines,
            tasks.initialize_flowlines,
            tasks.catchment_area,
            tasks.catchment_intersections,
            tasks.catchment_width_geom,
            tasks.catchment_width_correction,
        ]
        for task in task_list:
            workflow.execute_entity_task(task, gdirs_cent)

        # Same for all glaciers
        if border >= 20:
            task_list = [
                tasks.compute_downstream_line,
                tasks.compute_downstream_bedshape,
            ]
            for task in task_list:
                workflow.execute_entity_task(task, gdirs)
        else:
            log.workflow('L2: for map border values < 20, wont compute '
                         'downstream lines.')

        # Glacier stats
        sum_dir = os.path.join(output_base_dir, 'L2', 'summary')
        utils.mkdir(sum_dir)
        opath = os.path.join(sum_dir,
                             'glacier_statistics_{}.csv'.format(rgi_reg))
        utils.compile_glacier_statistics(gdirs, path=opath)

        # And for level 2: shapes
        if len(gdirs_cent) > 0:
            opath = os.path.join(sum_dir, 'centerlines_{}.shp'.format(rgi_reg))
            utils.write_centerlines_to_shape(gdirs_cent,
                                             to_tar=True,
                                             path=opath)

        # L2 OK - compress all in output directory
        log.workflow('L2 done. Writing to tar...')
        level_base_dir = os.path.join(output_base_dir, 'L2')
        workflow.execute_entity_task(utils.gdir_to_tar,
                                     gdirs,
                                     delete=False,
                                     base_dir=level_base_dir)
        utils.base_dir_to_tar(level_base_dir)
        if max_level == 2:
            _time_log()
            return

    # L3 - Tasks
    if start_level <= 2:
        sum_dir = os.path.join(output_base_dir, 'L3', 'summary')
        utils.mkdir(sum_dir)

        # Climate
        workflow.execute_entity_task(tasks.process_climate_data, gdirs)

        if cfg.PARAMS['climate_qc_months'] > 0:
            workflow.execute_entity_task(tasks.historical_climate_qc, gdirs)

        if match_geodetic_mb_per_glacier:
            utils.get_geodetic_mb_dataframe(
            )  # Small optim to avoid concurrency
            workflow.execute_entity_task(
                tasks.mu_star_calibration_from_geodetic_mb, gdirs)
            workflow.execute_entity_task(tasks.apparent_mb_from_any_mb, gdirs)
        else:
            workflow.execute_entity_task(tasks.local_t_star, gdirs)
            workflow.execute_entity_task(tasks.mu_star_calibration, gdirs)

        # Inversion: we match the consensus
        filter = border >= 20
        workflow.calibrate_inversion_from_consensus(
            gdirs,
            apply_fs_on_mismatch=True,
            error_on_mismatch=False,
            filter_inversion_output=filter)

        # Do we want to match geodetic estimates?
        # This affects only the bias so we can actually do this *after*
        # the inversion, but we really want to take calving into account here
        if match_regional_geodetic_mb:
            opath = os.path.join(
                sum_dir, 'fixed_geometry_mass_balance_'
                'before_match_{}.csv'.format(rgi_reg))
            utils.compile_fixed_geometry_mass_balance(gdirs, path=opath)
            workflow.match_regional_geodetic_mb(
                gdirs, rgi_reg=rgi_reg, dataset=match_regional_geodetic_mb)

        # We get ready for modelling
        if border >= 20:
            workflow.execute_entity_task(tasks.init_present_time_glacier,
                                         gdirs)
        else:
            log.workflow(
                'L3: for map border values < 20, wont initialize glaciers '
                'for the run.')
        # Glacier stats
        opath = os.path.join(sum_dir,
                             'glacier_statistics_{}.csv'.format(rgi_reg))
        utils.compile_glacier_statistics(gdirs, path=opath)
        opath = os.path.join(sum_dir,
                             'climate_statistics_{}.csv'.format(rgi_reg))
        utils.compile_climate_statistics(gdirs, path=opath)
        opath = os.path.join(
            sum_dir, 'fixed_geometry_mass_balance_{}.csv'.format(rgi_reg))
        utils.compile_fixed_geometry_mass_balance(gdirs, path=opath)

        # L3 OK - compress all in output directory
        log.workflow('L3 done. Writing to tar...')
        level_base_dir = os.path.join(output_base_dir, 'L3')
        workflow.execute_entity_task(utils.gdir_to_tar,
                                     gdirs,
                                     delete=False,
                                     base_dir=level_base_dir)
        utils.base_dir_to_tar(level_base_dir)
        if max_level == 3:
            _time_log()
            return
        if border < 20:
            log.workflow(
                'L3: for map border values < 20, wont compute L4 and L5.')
            _time_log()
            return

        # is needed to copy some files for L4 and L5
        sum_dir_L3 = sum_dir

    # L4 - No tasks: add some stats for consistency and make the dirs small
    if start_level <= 3:
        sum_dir = os.path.join(output_base_dir, 'L4', 'summary')
        utils.mkdir(sum_dir)

        # Copy L3 files for consistency
        for bn in [
                'glacier_statistics', 'climate_statistics',
                'fixed_geometry_mass_balance'
        ]:
            if start_level < 3:
                ipath = os.path.join(sum_dir_L3,
                                     bn + '_{}.csv'.format(rgi_reg))
            else:
                ipath = file_downloader(
                    os.path.join(
                        get_prepro_base_url(base_url=start_base_url,
                                            rgi_version=rgi_version,
                                            border=border,
                                            prepro_level=start_level),
                        'summary', bn + '_{}.csv'.format(rgi_reg)))

            opath = os.path.join(sum_dir, bn + '_{}.csv'.format(rgi_reg))
            shutil.copyfile(ipath, opath)

        # Copy mini data to new dir
        mini_base_dir = os.path.join(working_dir, 'mini_perglacier',
                                     'RGI{}'.format(rgi_version),
                                     'b_{:03d}'.format(border))
        mini_gdirs = workflow.execute_entity_task(tasks.copy_to_basedir,
                                                  gdirs,
                                                  base_dir=mini_base_dir)

        # L4 OK - compress all in output directory
        log.workflow('L4 done. Writing to tar...')
        level_base_dir = os.path.join(output_base_dir, 'L4')
        workflow.execute_entity_task(utils.gdir_to_tar,
                                     mini_gdirs,
                                     delete=False,
                                     base_dir=level_base_dir)
        utils.base_dir_to_tar(level_base_dir)
        if max_level == 4:
            _time_log()
            return

        # use mini_gdirs for L5
        gdirs = mini_gdirs

    # L5 - spinup run in mini gdirs
    # Get end date. The first gdir might have blown up, try some others
    i = 0
    while True:
        if i >= len(gdirs):
            raise RuntimeError('Found no valid glaciers!')
        try:
            y0 = gdirs[i].get_climate_info()['baseline_hydro_yr_0']
            # One adds 1 because the run ends at the end of the year
            ye = gdirs[i].get_climate_info()['baseline_hydro_yr_1'] + 1
            break
        except BaseException:
            i += 1

    # Which model?
    if evolution_model == 'massredis':
        from oggm.core.flowline import MassRedistributionCurveModel
        evolution_model = MassRedistributionCurveModel
    else:
        from oggm.core.flowline import FluxBasedModel
        evolution_model = FluxBasedModel

    # OK - run
    if dynamic_spinup:
        if y0 > dynamic_spinup_start_year:
            dynamic_spinup_start_year = y0
        workflow.execute_entity_task(
            tasks.run_dynamic_spinup,
            gdirs,
            evolution_model=evolution_model,
            minimise_for=dynamic_spinup,
            spinup_start_yr=dynamic_spinup_start_year,
            output_filesuffix='_dynamic_spinup',
        )
        workflow.execute_entity_task(tasks.run_from_climate_data,
                                     gdirs,
                                     min_ys=y0,
                                     ye=ye,
                                     evolution_model=evolution_model,
                                     init_model_filesuffix='_dynamic_spinup',
                                     output_filesuffix='_hist_spin')
        workflow.execute_entity_task(tasks.merge_consecutive_run_outputs,
                                     gdirs,
                                     input_filesuffix_1='_dynamic_spinup',
                                     input_filesuffix_2='_hist_spin',
                                     output_filesuffix='_historical_spinup',
                                     delete_input=True)

    workflow.execute_entity_task(tasks.run_from_climate_data,
                                 gdirs,
                                 min_ys=y0,
                                 ye=ye,
                                 evolution_model=evolution_model,
                                 output_filesuffix='_historical')

    # Now compile the output
    sum_dir = os.path.join(output_base_dir, 'L5', 'summary')
    utils.mkdir(sum_dir)
    opath = os.path.join(sum_dir, f'historical_run_output_{rgi_reg}.nc')
    utils.compile_run_output(gdirs, path=opath, input_filesuffix='_historical')

    if dynamic_spinup:
        opath = os.path.join(sum_dir,
                             f'historical_spinup_run_output_{rgi_reg}.nc')
        utils.compile_run_output(gdirs,
                                 path=opath,
                                 input_filesuffix='_historical_spinup')

    # Glacier statistics we recompute here for error analysis
    opath = os.path.join(sum_dir, 'glacier_statistics_{}.csv'.format(rgi_reg))
    utils.compile_glacier_statistics(gdirs, path=opath)

    # Other stats for consistency
    for bn in ['climate_statistics', 'fixed_geometry_mass_balance']:
        if start_level < 3:
            ipath = os.path.join(sum_dir_L3, bn + '_{}.csv'.format(rgi_reg))
        else:
            ipath = file_downloader(
                os.path.join(
                    get_prepro_base_url(base_url=start_base_url,
                                        rgi_version=rgi_version,
                                        border=border,
                                        prepro_level=start_level), 'summary',
                    bn + '_{}.csv'.format(rgi_reg)))
        opath = os.path.join(sum_dir, bn + '_{}.csv'.format(rgi_reg))
        shutil.copyfile(ipath, opath)

    # Add the extended files
    pf = os.path.join(sum_dir, 'historical_run_output_{}.nc'.format(rgi_reg))
    mf = os.path.join(sum_dir,
                      'fixed_geometry_mass_balance_{}.csv'.format(rgi_reg))
    # This is crucial - extending calving only possible with L3 data!!!
    if start_level < 3:
        sf = os.path.join(sum_dir_L3,
                          'glacier_statistics_{}.csv'.format(rgi_reg))
    else:
        sf = file_downloader(
            os.path.join(
                get_prepro_base_url(base_url=start_base_url,
                                    rgi_version=rgi_version,
                                    border=border,
                                    prepro_level=start_level), 'summary',
                'glacier_statistics_{}.csv'.format(rgi_reg)))
    opath = os.path.join(
        sum_dir, 'historical_run_output_extended_{}.nc'.format(rgi_reg))
    utils.extend_past_climate_run(past_run_file=pf,
                                  fixed_geometry_mb_file=mf,
                                  glacier_statistics_file=sf,
                                  path=opath)

    # L5 OK - compress all in output directory
    log.workflow('L5 done. Writing to tar...')
    level_base_dir = os.path.join(output_base_dir, 'L5')
    workflow.execute_entity_task(utils.gdir_to_tar,
                                 gdirs,
                                 delete=False,
                                 base_dir=level_base_dir)
    utils.base_dir_to_tar(level_base_dir)

    _time_log()