Source code for mpas_analysis.ocean.climatology_map_antarctic_melt

# This software is open source software available under the BSD-3 license.
#
# Copyright (c) 2020 Triad National Security, LLC. All rights reserved.
# Copyright (c) 2020 Lawrence Livermore National Security, LLC. All rights
# reserved.
# Copyright (c) 2020 UT-Battelle, LLC. All rights reserved.
#
# Additional copyright and license information can be found in the LICENSE file
# distributed with this code, or at
# https://raw.githubusercontent.com/MPAS-Dev/MPAS-Analysis/master/LICENSE
from __future__ import absolute_import, division, print_function, \
    unicode_literals

import os
import csv
import xarray as xr
import dask
from multiprocessing.pool import ThreadPool
from pyremap import ProjectionGridDescriptor

from mpas_analysis.shared import AnalysisTask

from mpas_analysis.shared.io.utility import build_obs_path, get_region_mask, \
    decode_strings
from mpas_analysis.shared.io import write_netcdf

from mpas_analysis.shared.climatology import RemapMpasClimatologySubtask, \
    RemapObservedClimatologySubtask, get_antarctic_stereographic_projection
from mpas_analysis.shared.climatology.climatology import \
    get_masked_mpas_climatology_file_name

from mpas_analysis.ocean.plot_climatology_map_subtask import \
    PlotClimatologyMapSubtask

from mpas_analysis.shared.constants import constants

from mpas_analysis.shared.regions import get_feature_list


[docs]class ClimatologyMapAntarcticMelt(AnalysisTask): # {{{ """ An analysis task for comparison of Antarctic melt rates against observations """ # Authors # ------- # Xylar Asay-Davis
[docs] def __init__(self, config, mpasClimatologyTask, regionMasksTask, controlConfig): # {{{ """ Construct the analysis task. Parameters ---------- config : ``MpasAnalysisConfigParser`` Configuration options mpasClimatologyTask : ``MpasClimatologyTask`` The task that produced the climatology to be remapped and plotted regionMasksTask : ``ComputeRegionMasks`` A task for computing region masks controlConfig : ``MpasAnalysisConfigParser`` Configuration options for a control run """ # Authors # ------- # Xylar Asay-Davis fieldName = 'meltRate' # call the constructor from the base class (AnalysisTask) super(ClimatologyMapAntarcticMelt, self).__init__( config=config, taskName='climatologyMapAntarcticMelt', componentName='ocean', tags=['climatology', 'horizontalMap', fieldName, 'landIceCavities', 'antarctic']) sectionName = self.taskName mpasFieldName = 'timeMonthly_avg_landIceFreshwaterFlux' iselValues = None # read in what seasons we want to plot seasons = config.getExpression(sectionName, 'seasons') if len(seasons) == 0: raise ValueError('config section {} does not contain valid list ' 'of seasons'.format(sectionName)) comparisonGridNames = config.getExpression(sectionName, 'comparisonGrids') makeTables = config.getboolean(sectionName, 'makeTables') if makeTables: for season in seasons: tableSubtask = AntarcticMeltTableSubtask( parentTask=self, mpasClimatologyTask=mpasClimatologyTask, controlConfig=controlConfig, regionMasksTask=regionMasksTask, season=season) self.add_subtask(tableSubtask) if len(comparisonGridNames) == 0: raise ValueError('config section {} does not contain valid list ' 'of comparison grids'.format(sectionName)) # the variable 'timeMonthly_avg_landIceFreshwaterFlux' will be added to # mpasClimatologyTask along with the seasons. remapClimatologySubtask = RemapMpasAntarcticMeltClimatology( mpasClimatologyTask=mpasClimatologyTask, parentTask=self, climatologyName=fieldName, variableList=[mpasFieldName], comparisonGridNames=comparisonGridNames, seasons=seasons, iselValues=iselValues) if controlConfig is None: refTitleLabel = \ 'Observations (Rignot et al, 2013)' observationsDirectory = build_obs_path( config, 'ocean', 'meltSubdirectory') obsFileName = \ '{}/Rignot_2013_melt_rates_6000.0x6000.0km_10.0km_' \ 'Antarctic_stereo.nc'.format(observationsDirectory) refFieldName = 'meltRate' outFileLabel = 'meltRignot' galleryName = 'Observations: Rignot et al. (2013)' remapObservationsSubtask = RemapObservedAntarcticMeltClimatology( parentTask=self, seasons=seasons, fileName=obsFileName, outFilePrefix=refFieldName, comparisonGridNames=comparisonGridNames) self.add_subtask(remapObservationsSubtask) diffTitleLabel = 'Model - Observations' else: remapObservationsSubtask = None controlRunName = controlConfig.get('runs', 'mainRunName') galleryName = None refTitleLabel = 'Control: {}'.format(controlRunName) refFieldName = mpasFieldName outFileLabel = 'melt' diffTitleLabel = 'Main - Control' for comparisonGridName in comparisonGridNames: for season in seasons: # make a new subtask for this season and comparison grid subtask = PlotClimatologyMapSubtask( self, season, comparisonGridName, remapClimatologySubtask, remapObservationsSubtask, controlConfig=controlConfig) subtask.set_plot_info( outFileLabel=outFileLabel, fieldNameInTitle='Melt Rate', mpasFieldName=mpasFieldName, refFieldName=refFieldName, refTitleLabel=refTitleLabel, diffTitleLabel=diffTitleLabel, unitsLabel=r'm a$^{-1}$', imageCaption='Antarctic Melt Rate', galleryGroup='Melt Rate', groupSubtitle=None, groupLink='antarctic_melt', galleryName=galleryName) self.add_subtask(subtask)
# }}} def setup_and_check(self): # {{{ """ Perform steps to set up the analysis and check for errors in the setup. """ # Authors # ------- # Xylar Asay-Davis # first, call setup_and_check from the base class # (AnalysisTask), which will perform some common setup super(ClimatologyMapAntarcticMelt, self).setup_and_check() landIceFluxMode = self.namelist.get('config_land_ice_flux_mode') if landIceFluxMode not in ['standalone', 'coupled']: raise ValueError('*** climatologyMapMeltAntarctic requires ' 'config_land_ice_flux_mode \n' ' to be standalone or coupled. Otherwise, no ' 'melt rates are available \n' ' for plotting.')
# }}} # }}} class RemapMpasAntarcticMeltClimatology(RemapMpasClimatologySubtask): # {{{ """ A subtask for remapping climatologies of Antarctic melt rates and adding Attributes ---------- landIceMask : xarray.DataArray A mask indicating where there is land ice on the ocean grid (thus, where melt rates are valid) """ # Authors # ------- # Xylar Asay-Davis def run_task(self): # {{{ """ Compute climatologies of melt rates from E3SM/MPAS output This function has been overridden to load ``landIceMask`` from a restart file for later use in masking the melt rate. It then simply calls the run function from """ # Authors # ------- # Xylar Asay-Davis # first, load the land-ice mask from the restart file dsLandIceMask = xr.open_dataset(self.restartFileName) dsLandIceMask = dsLandIceMask[['landIceMask']] dsLandIceMask = dsLandIceMask.isel(Time=0) self.landIceMask = dsLandIceMask.landIceMask > 0. # then, call run from the base class (RemapMpasClimatologySubtask), # which will perform the main function of the task super(RemapMpasAntarcticMeltClimatology, self).run_task() # }}} def customize_masked_climatology(self, climatology, season): # {{{ """ Mask the melt rates using ``landIceMask`` and rescale it to m/yr Parameters ---------- climatology : ``xarray.Dataset`` object the climatology data set season : str The name of the season to be masked Returns ------- climatology : ``xarray.Dataset`` object the modified climatology data set """ # Authors # ------- # Xylar Asay-Davis fieldName = self.variableList[0] # scale the field to m/yr from kg/m^2/s and mask out non-land-ice areas climatology[fieldName] = \ constants.sec_per_year / constants.rho_fw * \ climatology[fieldName].where(self.landIceMask) return climatology # }}} # }}} class RemapObservedAntarcticMeltClimatology(RemapObservedClimatologySubtask): # {{{ """ A subtask for reading and remapping Antarctic melt-rate observations """ # Authors # ------- # Xylar Asay-Davis def get_observation_descriptor(self, fileName): # {{{ """ get a MeshDescriptor for the observation grid Parameters ---------- fileName : str observation file name describing the source grid Returns ------- obsDescriptor : ``MeshDescriptor`` The descriptor for the observation grid """ # Authors # ------- # Xylar Asay-Davis # create a descriptor of the observation grid using the x/y polar # stereographic coordinates projection = get_antarctic_stereographic_projection() obsDescriptor = ProjectionGridDescriptor.read( projection, fileName=fileName, xVarName='x', yVarName='y') return obsDescriptor # }}} def build_observational_dataset(self, fileName): # {{{ """ read in the data sets for observations, and possibly rename some variables and dimensions Parameters ---------- fileName : str observation file name Returns ------- dsObs : ``xarray.Dataset`` The observational dataset """ # Authors # ------- # Xylar Asay-Davis # Load MLD observational data dsObs = xr.open_dataset(fileName) return dsObs # }}} # }}} class AntarcticMeltTableSubtask(AnalysisTask): def __init__(self, parentTask, mpasClimatologyTask, controlConfig, regionMasksTask, season, subtaskName=None): # {{{ """ Construct the analysis task. Parameters ---------- parentTask : ``ClimatologyMapAntarcticMelt`` The parent task, used to get the ``taskName``, ``config`` and ``componentName`` mpasClimatologyTask : ``MpasClimatologyTask`` The task that produced the climatology to be remapped and plotted controlConfig : ``MpasAnalysisConfigParser`` Configuration options for a control run (if any) regionMasksTask : ``ComputeRegionMasks`` A task for computing region masks season : str One of the seasons in ``constants.monthDictionary`` subtaskName : str, optional The name of the subtask """ # Authors # ------- # Xylar Asay-Davis tags = ['climatology', 'table'] if subtaskName is None: subtaskName = 'table{}'.format(season) # call the constructor from the base class (AnalysisTask) super(AntarcticMeltTableSubtask, self).__init__( config=parentTask.config, taskName=parentTask.taskName, subtaskName=subtaskName, componentName=parentTask.componentName, tags=tags) config = parentTask.config self.season = season self.mpasClimatologyTask = mpasClimatologyTask self.controlConfig = controlConfig self.iceShelfMasksFile = get_region_mask(config, 'iceShelves20200621.geojson') self.masksSubtask = regionMasksTask.add_mask_subtask( self.iceShelfMasksFile, outFileSuffix='iceShelves20200621') self.run_after(self.masksSubtask) # }}} def run_task(self): # {{{ """ Computes and plots table of Antarctic sub-ice-shelf melt rates. """ # Authors # ------- # Xylar Asay-Davis self.logger.info("Computing Antarctic melt rate table...") config = self.config sectionName = self.taskName iceShelvesInTable = config.getExpression(sectionName, 'iceShelvesInTable') if 'all' in iceShelvesInTable: iceShelvesInTable = get_feature_list(self.iceShelfMasksFile) meltRateFileName = get_masked_mpas_climatology_file_name( config, self.season, self.componentName, climatologyName='antarcticMeltTable') if not os.path.exists(meltRateFileName): with dask.config.set(schedular='threads', pool=ThreadPool(1)): # Load data: inFileName = self.mpasClimatologyTask.get_file_name(self.season) mpasFieldName = 'timeMonthly_avg_landIceFreshwaterFlux' dsIn = xr.open_dataset(inFileName) freshwaterFlux = dsIn[mpasFieldName] if 'Time' in freshwaterFlux.dims: freshwaterFlux.isel(Time=0) regionMaskFileName = self.masksSubtask.maskFileName dsRegionMask = xr.open_dataset(regionMaskFileName) # figure out the indices of the regions to plot regionNames = decode_strings(dsRegionMask.regionNames) regionIndices = [] for iceShelf in iceShelvesInTable: for index, regionName in enumerate(regionNames): if iceShelf == regionName: regionIndices.append(index) break # select only those regions we want to plot dsRegionMask = dsRegionMask.isel(nRegions=regionIndices) cellMasks = dsRegionMask.regionCellMasks.chunk({'nRegions': 10}) restartFileName = \ self.runStreams.readpath('restart')[0] dsRestart = xr.open_dataset(restartFileName) areaCell = \ dsRestart.landIceFraction.isel(Time=0) * dsRestart.areaCell # convert from kg/s to kg/yr totalMeltFlux = constants.sec_per_year * \ (cellMasks * areaCell * freshwaterFlux).sum(dim='nCells') totalMeltFlux.compute() totalArea = (cellMasks * areaCell).sum(dim='nCells') # from kg/m^2/yr to m/yr meltRates = ((1. / constants.rho_fw) * (totalMeltFlux / totalArea)) meltRates.compute() # convert from kg/yr to GT/yr totalMeltFlux /= constants.kg_per_GT ds = xr.Dataset() ds['totalMeltFlux'] = totalMeltFlux ds.totalMeltFlux.attrs['units'] = 'GT a$^{-1}$' ds.totalMeltFlux.attrs['description'] = \ 'Total melt flux summed over each ice shelf or region' ds['meltRates'] = meltRates ds.meltRates.attrs['units'] = 'm a$^{-1}$' ds.meltRates.attrs['description'] = \ 'Melt rate averaged over each ice shelf or region' ds['area'] = 1e-6*totalArea ds.meltRates.attrs['units'] = 'km$^2$' ds.meltRates.attrs['description'] = \ 'Region or ice shelf area' ds['regionNames'] = dsRegionMask.regionNames write_netcdf(ds, meltRateFileName) else: ds = xr.open_dataset(meltRateFileName) mainRunName = config.get('runs', 'mainRunName') fieldNames = ['Region', 'Area', mainRunName] controlConfig = self.controlConfig if controlConfig is not None: controlFileName = get_masked_mpas_climatology_file_name( controlConfig, self.season, self.componentName, climatologyName='antarcticMeltTable') dsControl = xr.open_dataset(controlFileName) controlRunName = controlConfig.get('runs', 'mainRunName') fieldNames.append(controlRunName) else: dsControl = None controlRunName = None regionNames = decode_strings(ds.regionNames) tableFileName = get_masked_mpas_climatology_file_name( config, self.season, self.componentName, climatologyName='antarcticMeltRateTable') tableFileName = tableFileName.replace('.nc', '.csv') with open(tableFileName, 'w', newline='') as csvfile: writer = csv.DictWriter(csvfile, fieldnames=fieldNames) writer.writeheader() for index, regionName in enumerate(regionNames): row = {'Region': regionName, 'Area': '{}'.format(ds.area[index].values), mainRunName: '{}'.format(ds.meltRates[index].values)} if dsControl is not None: row[controlRunName] = \ '{}'.format(dsControl.meltRates[index].values) writer.writerow(row) tableFileName = get_masked_mpas_climatology_file_name( config, self.season, self.componentName, climatologyName='antarcticMeltFluxTable') tableFileName = tableFileName.replace('.nc', '.csv') with open(tableFileName, 'w', newline='') as csvfile: writer = csv.DictWriter(csvfile, fieldnames=fieldNames) writer.writeheader() for index, regionName in enumerate(regionNames): row = {'Region': regionName, 'Area': '{}'.format(ds.area[index].values), mainRunName: '{}'.format(ds.totalMeltFlux[index].values)} if dsControl is not None: row[controlRunName] = \ '{}'.format(dsControl.totalMeltFlux[index].values) writer.writerow(row) # }}} # }}} # vim: foldmethod=marker ai ts=4 sts=4 et sw=4 ft=python