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genForcing.py
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genForcing.py
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import argparse
import os
from core import config
from core import err_handler
from core import forcingInputMod
from core import forecastMod
from core import geoMod
from core import ioMod
from core import parallel
from core import suppPrecipMod
def main():
""" Main program to process LDASIN forcing files for WRF-Hydro.
The main execution of the program requires the user to compose
a forcing configuration file that is parsed by this workflow.
Please see documentation for further instructions.
Logan Karsten - National Center for Atmospheric Research
303-497-2693
"""
# Parse out the path to the configuration file.
parser = argparse.ArgumentParser(description='Main calling program to generate WRF-Hydro Forcing')
parser.add_argument('config_file', metavar='config_file', type=str,
help='Configuration file for the forcing engine')
parser.add_argument('nwm_version', metavar='nwm_version', type=str, nargs='?',
help='National Water Model Version Number Specification')
parser.add_argument('nwm_config', metavar='nwm_config', type=str, nargs='?',
help='National Water Model Configuration')
# Process the input arguments into the program.
args = parser.parse_args()
if not os.path.isfile(args.config_file):
err_handler.err_out_screen('Specified configuration file: ' + args.config_file + ' not found.')
# Initialize the configuration object that will contain all
# user-specified options.
job_meta = config.ConfigOptions(args.config_file)
# Place NWM version number (if provided by the user). This will be placed into the final
# output files as a global attribute.
if args.nwm_version is not None:
job_meta.nwmVersion = args.nwm_version
# Place NWM configuration (if provided by the user). This will be placed into the final
# output files as a global attribute.
if args.nwm_config is not None:
job_meta.nwmConfig = args.nwm_config
# Parse the configuration options
try:
job_meta.read_config()
except KeyboardInterrupt:
err_handler.err_out_screen('User keyboard interrupt')
except ImportError:
err_handler.err_out_screen('Missing Python packages')
except InterruptedError:
err_handler.err_out_screen('External kill signal detected')
# Initialize our MPI communication
mpi_meta = parallel.MpiConfig()
try:
mpi_meta.initialize_comm(job_meta)
except:
err_handler.err_out_screen(job_meta.errMsg)
# Initialize our WRF-Hydro geospatial object, which contains
# information about the modeling domain, local processor
# grid boundaries, and ESMF grid objects/fields to be used
# in regridding.
WrfHydroGeoMeta = geoMod.GeoMetaWrfHydro()
try:
WrfHydroGeoMeta.initialize_destination_geo(job_meta, mpi_meta)
except Exception:
err_handler.err_out_screen_para(job_meta.errMsg, mpi_meta)
if job_meta.spatial_meta is not None:
try:
WrfHydroGeoMeta.initialize_geospatial_metadata(job_meta, mpi_meta)
except Exception:
err_handler.err_out_screen_para(job_meta.errMsg, mpi_meta)
err_handler.check_program_status(job_meta, mpi_meta)
# Check to make sure we have enough dimensionality to run regridding. ESMF requires both grids
# to have a size of at least 2.
if WrfHydroGeoMeta.nx_local < 2 or WrfHydroGeoMeta.ny_local < 2:
job_meta.errMsg = "You have specified too many cores for your WRF-Hydro grid. " \
"Local grid Must have x/y dimension size of 2."
err_handler.err_out_screen_para(job_meta.errMsg, mpi_meta)
err_handler.check_program_status(job_meta, mpi_meta)
# Initialize our output object, which includes local slabs from the output grid.
try:
OutputObj = ioMod.OutputObj(job_meta, WrfHydroGeoMeta)
except Exception:
err_handler.err_out_screen_para(job_meta, mpi_meta)
err_handler.check_program_status(job_meta, mpi_meta)
# Next, initialize our input forcing classes. These objects will contain
# information about our source products (I.E. data type, grid sizes, etc).
# Information will be mapped via the options specified by the user.
# In addition, input ESMF grid objects will be created to hold data for
# downscaling and regridding purposes.
try:
inputForcingMod = forcingInputMod.initDict(job_meta,WrfHydroGeoMeta)
except Exception:
err_handler.err_out_screen_para(job_meta, mpi_meta)
err_handler.check_program_status(job_meta, mpi_meta)
# If we have specified supplemental precipitation products, initialize
# the supp class.
if job_meta.number_supp_pcp > 0:
suppPcpMod = suppPrecipMod.initDict(job_meta,WrfHydroGeoMeta)
else:
suppPcpMod = None
err_handler.check_program_status(job_meta, mpi_meta)
# There are three run modes (retrospective/realtime/reforecast). We are breaking the main
# workflow into either retrospective or forecasts (realtime/reforecasts)
#if jobMeta.retro_flag:
# # Place code into here for calling the retro run mod.
#if job_meta.refcst_flag or job_meta.realtime_flag:
# Place code in here for calling the forecasting module.
forecastMod.process_forecasts(job_meta, WrfHydroGeoMeta,inputForcingMod,suppPcpMod,mpi_meta,OutputObj)
#try:
# forecastMod.process_forecasts(jobMeta,WrfHydroGeoMeta,
# inputForcingMod,suppPcpMod,mpiMeta,OutputObj)
#except Exception:
# errMod.log_critical(jobMeta, mpiMeta)
err_handler.check_program_status(job_meta, mpi_meta)
if __name__ == "__main__":
main()