""" This file contains all your file and directory definitions for elevation, meshes and outputs. """ import os from anuga.utilities.system_tools import get_user_name, get_host_name from time import localtime, strftime, gmtime from os.path import join, exists #------------------------------------------------------------------------------- # Directory setup #------------------------------------------------------------------------------- # this section needs to be updated to reflect the modelled community. # Note, the user needs to set up the directory system accordingly state = 'tasmania' scenario_name = 'hobart' scenario_folder = 'hobart_tsunami_scenario_2009' #------------------------------------------------------------------------------- # Initial Conditions #------------------------------------------------------------------------------- # Model specific parameters. # One or all can be changed each time the run_model script is executed tide = 0 # difference between MSL and HAT in metres # Highest Astronomical Tide = 0.8 m for Hobart zone = 55 # specify UTM zone of model event_number = 58260 # 58280, 64477 the event number - See event_chosen.xls # in anuga/boundaries for more details alpha = 0.1 # smoothing parameter for mesh friction=0.01 # manning's friction coefficient starttime=0 # start time for simulation finaltime=65000 # final time for simulation setup = 'final' # This can be one of three values # trial - coarsest mesh, fast # basic - coarse mesh # final - fine mesh, slowest #------------------------------------------------------------------------------- # Output filename # # Your output filename should be unique between different runs on different data. # The list of items below will be used to create a file in your output directory. # Your user name and time+date will be automatically added. For example, # [setup, tide, event_number] # will result in a filename like # 20090212_091046_run_final_0_27283_rwilson #------------------------------------------------------------------------------- output_comment = [setup, tide, event_number] #------------------------------------------------------------------------------- # Input Data #------------------------------------------------------------------------------- # ELEVATION DATA # Used in build_elevation.py ascii_grid_filenames = [] ## Add csv header list to all files in point_filenames ##headerlist = ['x', 'y', 'elevation'] point_filenames = [] # BOUNDING POLYGON - for data clipping and estimate of triangles in mesh # Used in build_elevation.py # Format for points easting,northing (no header) bounding_polygon_filename = 'bounding_polygon.csv' bounding_polygon_maxarea = 1000000 # INTERIOR REGIONS - for designing the mesh # Used in run_model.py # Format for points easting,northing (no header) interior_regions_data = [['aos1.csv', 1500], ['aos2.csv', 1500], ['sw.csv', 30000]] PriorityArea_filename = 'PriorityAreas.csv' # LAND - used to set the initial stage/water to be offcoast only # Used in run_model.py. Format for points easting,northing (no header) land_initial_conditions_filename = 'initial_conditions.csv' # FINAL BOUNDING POLYGON - used in build_boundary.py and run_model.py respectively # NOTE: when files are put together the points must be in sequence # For ease go clockwise! # Check the run_model.py for boundary_tags # Thinned ordering file from Hazard Map (geographic) # Format is index,latitude,longitude (with header) urs_order_filename = 'urs_order.csv' # Landward bounding points # Format easting,northing (no header) landward_boundary_filename = 'landward_boundary.csv' # GAUGES - for creating timeseries at a specific point # Used in get_timeseries.py. # Format easting,northing,name,elevation (with header) gauges_filename = 'time_of_arrival_all.csv' #'TideGaugesPoints.csv' #'tsunamipointsMGA.csv' #------------------------------------------------------------------------------- # Clipping regions for export to asc and regions for clipping data # Final inundation maps should only be created in regions of the finest mesh #------------------------------------------------------------------------------- # ASCII export grid for Hobart Communities xminHobart = 520000 xmaxHobart = 545000 yminHobart = 5230000 ymaxHobart = 5260000 # ASCII export grid for North West Communities xminNW = 548000 xmaxNW = 561000 yminNW = 5250000 ymaxNW = 5258000 # ASCII export grid for South Communities xminSouth = 523000 xmaxSouth = 533300 yminSouth = 5197000 ymaxSouth = 5214000 ################################################################################ ################################################################################ #### NOTE: NOTHING WOULD NORMALLY CHANGE BELOW THIS POINT. #### ################################################################################ ################################################################################ # Get system user and host names. # These values can be used to distinguish between two similar runs by two # different users or runs by the same user on two different machines. user = get_user_name() host = get_host_name() # Environment variable names. # The inundation directory, not the data directory. ENV_INUNDATIONHOME = 'ANUGADATA' #------------------------------------------------------------------------------- # Output Elevation Data #------------------------------------------------------------------------------- # Output filename for elevation # this is a combination of all the data generated in build_elevation.py combined_elevation_basename = scenario_name + '_combined_elevation' #------------------------------------------------------------------------------- # Directory Structure #------------------------------------------------------------------------------- # determines time for setting up output directories time = strftime('%Y%m%d_%H%M%S', localtime()) gtime = strftime('%Y%m%d_%H%M%S', gmtime()) build_time = time + '_build' run_time = time + '_run_' # create paths generated from environment variables. home = join(os.getenv(ENV_INUNDATIONHOME), 'data') # Absolute path for data folder # check various directories/files that must exist anuga_folder = join(home, state, scenario_folder, 'anuga') topographies_folder = join(anuga_folder, 'topographies') polygons_folder = join(anuga_folder, 'polygons') boundaries_folder = join(anuga_folder, 'boundaries') output_folder = join(anuga_folder, 'outputs') gauges_folder = join(anuga_folder, 'gauges') event_folder = join(boundaries_folder, str(event_number)) #------------------------------------------------------------------------------- # Location of input and output data #------------------------------------------------------------------------------- # Convert the user output_comment to a string for run_model.py output_comment = ('_'.join([str(x) for x in output_comment if x != user]) + '_' + user) # The absolute pathname of the all elevation, generated in build_elevation.py combined_elevation = join(topographies_folder, combined_elevation_basename) # The pathname for the urs order points, used within build_urs_boundary.py if urs_order_filename: urs_order = join(boundaries_folder, urs_order_filename) # The absolute pathname for the landward points of the bounding polygon, # Used within run_model.py) if landward_boundary_filename: landward_boundary = join(boundaries_folder, landward_boundary_filename) # The absolute pathname for the .sts file, generated in build_boundary.py event_sts = join(event_folder, scenario_name) # The absolute pathname for the output folder names # Used for build_elevation.py output_build = join(output_folder, build_time) + '_' + str(user) # Used for run_model.py output_run = join(output_folder, run_time) + output_comment # Used by post processing output_run_time = join(output_run, scenario_name) # The absolute pathname of the mesh, generated in run_model.py meshes = join(output_run, scenario_name) + '.msh' # The absolute pathname for the gauges file # Used for get_timeseries.py if gauges_filename: gauges = join(gauges_folder, gauges_filename) #Multiple polygons in one CSV file to make internal polygons PriorityAreas = join(polygons_folder, PriorityArea_filename)